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Farnell PDF
Type: ECQE(F) - Panasonic - Farnell Element 14
Type: ECQE(F) - Panasonic - Farnell Element 14
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Farnell Element 14 :
See the trailer for the next exciting episode of The Ben Heck show. Check back on Friday to be among the first to see the exclusive full show on element…
Connect your Raspberry Pi to a breadboard, download some code and create a push-button audio play project.
Puce électronique / Microchip :
Sans fil - Wireless :
Texas instrument :
Ordinateurs :
Logiciels :
Tutoriels :
Autres documentations :
Analog-Devices-ADC-S..> 09-Sep-2014 08:21 2.4M
Analog-Devices-ADMC2..> 09-Sep-2014 08:21 2.4M
Analog-Devices-ADMC4..> 09-Sep-2014 08:23 2.3M
Analog-Devices-AN300..> 08-Sep-2014 17:42 2.0M
Analog-Devices-ANF32..> 09-Sep-2014 08:18 2.6M
Analog-Devices-Basic..> 08-Sep-2014 17:49 1.9M
Analog-Devices-Compl..> 08-Sep-2014 17:38 2.0M
Analog-Devices-Convo..> 09-Sep-2014 08:26 2.1M
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Analog-Devices-Convo..> 09-Sep-2014 08:25 2.2M
Analog-Devices-Digit..> 08-Sep-2014 18:02 2.1M
Analog-Devices-Digit..> 08-Sep-2014 18:03 2.0M
Analog-Devices-Gloss..> 08-Sep-2014 17:36 2.0M
Analog-Devices-Intro..> 08-Sep-2014 17:39 1.9M
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Farnell-ELMA-PDF.htm 29-Mar-2014 11:13 3.3M
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Farnell-EPCOS-Sample..> 11-Mar-2014 07:53 2.2M
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Farnell-HIP4081A-Int..> 07-Jul-2014 19:47 1.0M
Farnell-HUNTSMAN-Adv..> 10-Mar-2014 16:17 1.7M
Farnell-Haute-vitess..> 11-Mar-2014 08:17 2.4M
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Farnell-OMRON-Master..> 10-Mar-2014 16:26 1.8M
Farnell-OPA627-Texas..> 09-Sep-2014 08:08 2.8M
Farnell-OSLON-SSL-Ce..> 19-Mar-2014 18:03 2.1M
Farnell-OXPCIE958-FB..> 13-Jun-2014 18:40 1.8M
Farnell-Octal-Genera..> 28-Jul-2014 17:42 2.8M
Farnell-PADO-semi-au..> 04-Jul-2014 10:41 3.7M
Farnell-PBSS5160T-60..> 19-Mar-2014 18:03 2.1M
Farnell-PCF8574-PCF8..> 16-Jul-2014 09:03 1.7M
Farnell-PDTA143X-ser..> 20-Mar-2014 08:12 2.6M
Farnell-PDTB123TT-NX..> 13-Jun-2014 18:43 1.5M
Farnell-PESD5V0F1BL-..> 13-Jun-2014 18:43 1.5M
Farnell-PESD9X5.0L-P..> 13-Jun-2014 18:43 1.6M
Farnell-PIC12F609-61..> 04-Jul-2014 10:41 3.7M
Farnell-PIC18F2420-2..> 18-Jul-2014 16:57 2.5M
Farnell-PIC18F2455-2..> 23-Jun-2014 10:27 3.1M
Farnell-PIC24FJ256GB..> 14-Jun-2014 09:51 2.4M
Farnell-PMBT3906-PNP..> 13-Jun-2014 18:44 1.5M
Farnell-PMBT4403-PNP..> 23-Jun-2014 10:27 3.1M
Farnell-PMEG4002EL-N..> 14-Jun-2014 18:18 3.4M
Farnell-PMEG4010CEH-..> 13-Jun-2014 18:43 1.6M
Farnell-PN512-Full-N..> 16-Jul-2014 09:03 1.4M
Farnell-Panasonic-15..> 23-Jun-2014 10:29 2.1M
Farnell-Panasonic-EC..> 20-Mar-2014 17:36 2.6M
Farnell-Panasonic-EZ..> 20-Mar-2014 08:10 2.6M
Farnell-Panasonic-Id..> 20-Mar-2014 17:35 2.6M
Farnell-Panasonic-Ne..> 20-Mar-2014 17:36 2.6M
Farnell-Panasonic-Ra..> 20-Mar-2014 17:37 2.6M
Farnell-Panasonic-TS..> 20-Mar-2014 08:12 2.6M
Farnell-Panasonic-Y3..> 20-Mar-2014 08:11 2.6M
Farnell-PiFace-Digit..> 25-Jul-2014 12:25 3.0M
Farnell-Pico-Spox-Wi..> 10-Mar-2014 16:16 1.7M
Farnell-PicoScope-42..> 25-Jul-2014 12:23 3.0M
Farnell-PicoScope-se..> 25-Jul-2014 12:24 3.0M
Farnell-Pompes-Charg..> 24-Apr-2014 20:23 3.3M
Farnell-Ponts-RLC-po..> 14-Jun-2014 18:23 3.3M
Farnell-Portable-Ana..> 29-Mar-2014 11:16 2.8M
Farnell-Power-suppli..> 25-Jul-2014 12:29 7.0M
Farnell-Premier-Farn..> 21-Mar-2014 08:11 3.8M
Farnell-Produit-3430..> 14-Jun-2014 09:48 2.5M
Farnell-Proskit-SS-3..> 10-Mar-2014 16:26 1.8M
Farnell-Puissance-ut..> 11-Mar-2014 07:49 2.4M
Farnell-Q48-PDF.htm 23-Jun-2014 10:29 2.1M
Farnell-QRE1113-Fair..> 06-Jul-2014 10:03 879K
Farnell-Quadruple-2-..> 08-Sep-2014 07:29 1.5M
Farnell-Quick-Start-..> 25-Jul-2014 12:25 3.0M
Farnell-RASPBERRY-PI..> 22-Jul-2014 12:35 5.9M
Farnell-RDS-80-PDF.htm 18-Jul-2014 16:57 1.3M
Farnell-REF19x-Serie..> 09-Sep-2014 08:08 2.8M
Farnell-REF102-10V-P..> 28-Jul-2014 17:09 2.4M
Farnell-RF-short-tra..> 28-Jul-2014 17:16 6.3M
Farnell-Radial-Lead-..> 20-Mar-2014 08:12 2.6M
Farnell-RaspiCam-Doc..> 22-Jul-2014 12:32 1.6M
Farnell-Realiser-un-..> 11-Mar-2014 07:51 2.3M
Farnell-Reglement-RE..> 21-Mar-2014 08:08 3.9M
Farnell-Repartiteurs..> 14-Jun-2014 18:26 2.5M
Farnell-S-TRI-SWT860..> 21-Mar-2014 08:11 3.8M
Farnell-S1A-Fairchil..> 06-Jul-2014 10:03 896K
Farnell-SB175-Connec..> 11-Mar-2014 08:14 2.8M
Farnell-SB520-SB5100..> 22-Jul-2014 12:32 1.6M
Farnell-SERIAL-TFT-M..> 15-Jul-2014 17:05 1.0M
Farnell-SICK-OPTIC-E..> 18-Jul-2014 16:58 1.5M
Farnell-SL3ICS1002-1..> 16-Jul-2014 09:05 2.5M
Farnell-SL3S1203_121..> 16-Jul-2014 09:04 1.1M
Farnell-SL3S4011_402..> 16-Jul-2014 09:03 1.1M
Farnell-SL59830-Inte..> 06-Jul-2014 10:11 1.0M
Farnell-SMBJ-Transil..> 29-Mar-2014 11:12 3.3M
Farnell-SMU-Instrume..> 08-Jul-2014 18:51 2.3M
Farnell-SN54HC164-SN..> 08-Sep-2014 07:25 2.0M
Farnell-SN54HC244-SN..> 08-Jul-2014 18:52 2.3M
Farnell-SN54LV4053A-..> 28-Jul-2014 17:20 5.9M
Farnell-SO967460-PDF..> 11-Oct-2014 12:05 2.9M
Farnell-SOT-23-Multi..> 11-Mar-2014 07:51 2.3M
Farnell-SOURIAU-Cont..> 08-Jul-2014 19:04 3.0M
Farnell-SPLC780A1-16..> 14-Jun-2014 18:25 2.5M
Farnell-SSC7102-Micr..> 23-Jun-2014 10:25 3.2M
Farnell-STM32F103x8-..> 22-Jul-2014 12:33 1.6M
Farnell-STM32F405xxS..> 27-Aug-2014 18:27 1.8M
Farnell-SVPE-series-..> 14-Jun-2014 18:15 2.0M
Farnell-Schroff-A108..> 25-Jul-2014 12:27 2.8M
Farnell-Schroff-Main..> 25-Jul-2014 12:26 2.9M
Farnell-Schroff-mult..> 25-Jul-2014 12:26 2.9M
Farnell-Sensorless-C..> 04-Jul-2014 10:42 3.3M
Farnell-Septembre-20..> 20-Mar-2014 17:46 3.7M
Farnell-Serial-File-..> 06-Jul-2014 10:02 941K
Farnell-Serie-PicoSc..> 19-Mar-2014 18:01 2.5M
Farnell-Serie-Standa..> 14-Jun-2014 18:23 3.3M
Farnell-Series-2600B..> 20-Mar-2014 17:30 3.0M
Farnell-Series-TDS10..> 04-Jul-2014 10:39 4.0M
Farnell-Signal-PCB-R..> 14-Jun-2014 18:11 2.1M
Farnell-Silica-Gel-M..> 07-Jul-2014 19:46 1.2M
Farnell-Single-Chip-..> 08-Sep-2014 07:30 1.5M
Farnell-SmartRF06-Ev..> 07-Jul-2014 19:43 1.6M
Farnell-Strangkuhlko..> 21-Mar-2014 08:09 3.9M
Farnell-Supercapacit..> 26-Mar-2014 17:57 2.7M
Farnell-Synchronous-..> 08-Jul-2014 18:54 2.1M
Farnell-T672-3000-Se..> 08-Jul-2014 18:59 2.0M
Farnell-TAS1020B-USB..> 28-Jul-2014 17:19 6.2M
Farnell-TCL-DC-traco..> 15-Jul-2014 16:46 858K
Farnell-TDK-Lambda-H..> 14-Jun-2014 18:21 3.3M
Farnell-TEKTRONIX-DP..> 10-Mar-2014 17:20 2.0M
Farnell-TEL-5-Series..> 15-Jul-2014 16:47 814K
Farnell-TEN-8-WI-Ser..> 15-Jul-2014 16:46 939K
Farnell-TEP-150WI-Se..> 15-Jul-2014 16:47 837K
Farnell-TEXAS-INSTRU..> 22-Jul-2014 12:29 4.8M
Farnell-TEXAS-INSTRU..> 22-Jul-2014 12:31 2.4M
Farnell-TEXAS-INSTRU..> 22-Jul-2014 12:30 4.6M
Farnell-TIS-Instruct..> 15-Jul-2014 16:47 845K
Farnell-TIS-series-t..> 15-Jul-2014 16:46 875K
Farnell-TKC2-Dusters..> 07-Jul-2014 19:46 1.2M
Farnell-TL082-Wide-B..> 28-Jul-2014 17:16 6.3M
Farnell-TLV320AIC23B..> 08-Sep-2014 07:18 2.4M
Farnell-TLV320AIC325..> 28-Jul-2014 17:45 2.9M
Farnell-TMLM-Series-..> 15-Jul-2014 16:47 810K
Farnell-TMP006EVM-Us..> 29-Jul-2014 10:30 1.3M
Farnell-TMR-2-Series..> 15-Jul-2014 16:46 897K
Farnell-TMR-2-series..> 15-Jul-2014 16:48 787K
Farnell-TMR-3-WI-Ser..> 15-Jul-2014 16:46 939K
Farnell-TMS320F28055..> 28-Jul-2014 17:09 2.7M
Farnell-TOS-tracopow..> 15-Jul-2014 16:47 852K
Farnell-TPS40060-Wid..> 28-Jul-2014 17:19 6.3M
Farnell-TSV6390-TSV6..> 28-Jul-2014 17:14 6.4M
Farnell-TXL-series-t..> 15-Jul-2014 16:47 829K
Farnell-TYCO-ELECTRO..> 25-Jul-2014 12:30 6.9M
Farnell-Tektronix-AC..> 13-Jun-2014 18:44 1.5M
Farnell-Telemetres-l..> 20-Mar-2014 17:46 3.7M
Farnell-Termometros-..> 14-Jun-2014 18:14 2.0M
Farnell-The-Discrete..> 08-Sep-2014 17:44 1.8M
Farnell-The-essentia..> 10-Mar-2014 16:27 1.7M
Farnell-Thermometre-..> 29-Jul-2014 10:30 1.4M
Farnell-Tiva-C-Serie..> 08-Jul-2014 18:49 2.6M
Farnell-Trust-Digita..> 25-Jul-2014 12:24 3.0M
Farnell-U2270B-PDF.htm 14-Jun-2014 18:15 3.4M
Farnell-ULINKpro-Deb..> 25-Jul-2014 12:35 5.9M
Farnell-ULN2803A-Rev..> 09-Sep-2014 19:26 2.9M
Farnell-USB-Buccanee..> 14-Jun-2014 09:48 2.5M
Farnell-USB-to-Seria..> 08-Sep-2014 07:27 2.0M
Farnell-USB1T11A-PDF..> 19-Mar-2014 18:03 2.1M
Farnell-UTO-Souriau-..> 08-Jul-2014 18:48 2.8M
Farnell-UTS-Series-S..> 08-Jul-2014 18:49 2.8M
Farnell-UTS-Series-S..> 08-Jul-2014 18:49 2.5M
Farnell-User-Guide-M..> 07-Jul-2014 19:41 2.0M
Farnell-V4N-PDF.htm 14-Jun-2014 18:11 2.1M
Farnell-Videk-PDF.htm 06-Jul-2014 10:01 948K
Farnell-WIRE-WRAP-50..> 25-Jul-2014 12:34 5.9M
Farnell-WetTantalum-..> 11-Mar-2014 08:14 2.8M
Farnell-XPS-AC-Octop..> 14-Jun-2014 18:11 2.1M
Farnell-XPS-MC16-XPS..> 11-Mar-2014 08:15 2.8M
Farnell-XPSAF5130-PD..> 18-Jul-2014 16:56 1.4M
Farnell-YAGEO-DATA-S..> 11-Mar-2014 08:13 2.8M
Farnell-ZigBee-ou-le..> 11-Mar-2014 07:50 2.4M
Farnell-celpac-SUL84..> 21-Mar-2014 08:11 3.8M
Farnell-china_rohs_o..> 21-Mar-2014 10:04 3.9M
Farnell-cree-Xlamp-X..> 20-Mar-2014 17:34 2.8M
Farnell-cree-Xlamp-X..> 20-Mar-2014 17:35 2.7M
Farnell-cree-Xlamp-X..> 20-Mar-2014 17:31 2.9M
Farnell-cree-Xlamp-m..> 20-Mar-2014 17:32 2.9M
Farnell-cree-Xlamp-m..> 20-Mar-2014 17:32 2.9M
Farnell-ev-relays-ae..> 06-Jul-2014 10:02 926K
Farnell-fiche-de-don..> 07-Jul-2014 19:44 1.4M
Farnell-fx-3650P-fx-..> 29-Jul-2014 10:42 1.5M
Farnell-iServer-Micr..> 22-Jul-2014 12:32 1.6M
Farnell-ir1150s_fr.p..> 29-Mar-2014 11:11 3.3M
Farnell-manual-bus-p..> 10-Mar-2014 16:29 1.9M
Farnell-maxim-integr..> 28-Jul-2014 17:14 6.4M
Farnell-pmbta13_pmbt..> 15-Jul-2014 17:06 959K
Farnell-propose-plus..> 11-Mar-2014 08:19 2.8M
Farnell-safety-data-..> 07-Jul-2014 19:44 1.4M
Farnell-techfirst_se..> 21-Mar-2014 08:08 3.9M
Farnell-tesa®pack63..> 08-Jul-2014 18:56 2.0M
Farnell-testo-205-20..> 20-Mar-2014 17:37 3.0M
Farnell-testo-470-Fo..> 20-Mar-2014 17:38 3.0M
Farnell-uC-OS-III-Br..> 10-Mar-2014 17:20 2.0M
Farnell-user-manuel-..> 29-Jul-2014 10:29 1.5M
Sefram-7866HD.pdf-PD..> 29-Mar-2014 11:46 472K
Sefram-CAT_ENREGISTR..> 29-Mar-2014 11:46 461K
Sefram-CAT_MESUREURS..> 29-Mar-2014 11:46 435K
Sefram-GUIDE_SIMPLIF..> 29-Mar-2014 11:46 481K
Sefram-GUIDE_SIMPLIF..> 29-Mar-2014 11:46 442K
Sefram-GUIDE_SIMPLIF..> 29-Mar-2014 11:46 422K
Sefram-SP270.pdf-PDF..> 29-Mar-2014 11:46 464K
Farnell-AN2794-Appli..> 13-Oct-2014 10:02 1.0M
Farnell-Data-Sheet-S..> 13-Oct-2014 10:09 1.2M
Farnell-ESM6045DV-ST..> 13-Oct-2014 10:07 850K
Farnell-L78-Positive..> 13-Oct-2014 10:05 1.8M
Farnell-L78S-STMicro..> 13-Oct-2014 10:09 1.6M
Farnell-L4978-STMicr..> 13-Oct-2014 10:08 783K
Farnell-L6384E-STMic..> 13-Oct-2014 10:03 1.9M
Farnell-L6562-STMicr..> 13-Oct-2014 10:08 754K
Farnell-LM139-LM239-..> 13-Oct-2014 10:08 771K
Farnell-LM217-LM317-..> 13-Oct-2014 10:05 1.7M
Farnell-LM350-STMicr..> 13-Oct-2014 10:04 1.8M
Farnell-LM2904-LM290..> 13-Oct-2014 10:05 1.7M
Farnell-MC34063ABD-T..> 13-Oct-2014 10:07 844K
Farnell-SG2525A-SG35..> 13-Oct-2014 10:02 1.0M
Farnell-SMAJ-STMicro..> 13-Oct-2014 10:08 734K
Farnell-ST1S10PHR-ST..> 13-Oct-2014 10:08 820K
Farnell-ST3232B-ST32..> 13-Oct-2014 10:07 867K
Farnell-STEVAL-TDR02..> 13-Oct-2014 10:02 960K
Farnell-STM32F030x4-..> 13-Oct-2014 10:07 1.1M
Farnell-STM32F103x8-..> 13-Oct-2014 10:07 1.0M
Farnell-STM32F205xx-..> 13-Oct-2014 10:06 1.7M
Farnell-STM32F405xx-..> 13-Oct-2014 10:06 1.4M
Farnell-STP16NF06L-n..> 13-Oct-2014 10:06 1.7M
Farnell-STP80NF55L-0..> 13-Oct-2014 10:06 1.7M
Farnell-Smart-street..> 13-Oct-2014 10:04 1.8M
Farnell-TIP41C-TIP42..> 13-Oct-2014 10:08 829K
Farnell-TIP102-TIP10..> 13-Oct-2014 10:07 853K
Farnell-TSV6390-TSV6..> 13-Oct-2014 10:10 6.4M
Farnell-ULN2001-ULN2..> 13-Oct-2014 10:03 1.9M
Farnell-ULQ2001-ULQ2..> 13-Oct-2014 10:03 1.9M
Farnell-VND920P-E-ST..> 13-Oct-2014 10:04 1.8M
Design, Specifications are subject to change without notice. Ask factory for technical specifications before purchase and/or use.
Whenever a doubt about safety arises from this product, please inform us immediately for technical consultation without fail.
- FC32 -
Plastic Film Capacitors
Metallized Polyester Film Capacitor
Type:ECQE(F)
Non-inductive construction using metallized Polyester
film with flame retardant epoxy resin coating
■Features
•Self-healing property
•Excellent electrical characteristics
•Flame retardant epoxy resin coating
•RoHS directive compliant
■Recommended Applications
•General purpose usage
❈Please contact us when applications are CD , ignitor etc.
■Explanation of Part Numbers
1 2 3 4 5 6 7 8 9 10 11 12
E C Q E
Product code Dielectric &
construction
Rated volt. Capacitance
F
Cap. Tol. Suffix Suffix
1
2
4
6
100 VDC
250 VDC
400 VDC
630 VDC
10
12
1A
2A
1000 VDC
1250 VDC
125 VAC
250 VAC
J
K
±5 %
±10 %
E C Q E
Product code Dielectric &
construction
Rated volt. Capacitance
R F
Suffix Cap. Tol. Suffix
■Specifications
●Explanation of Part Number for Odd Size Taping
Category temp. range
(Including temperature-rise on unit surface)
Rated voltage
Capacitance range
Capacitance tolerance
Dissipation factor (tan )
Withstand voltage
Insulation resistance (IR)
100 VDC, 250 VDC,400 VDC, 630 VDC, 1000 VDC, 1250 VDC,
125 VAC, 250 VAC
–40 ˚C to +105 ˚C
–40 ˚C to +105 ˚C
100 VDC, 250 VDC, 400 VDC, 630 VDC, 1000 VDC, 1250 VDC,
(Derating of rated voltage by 1.25 %/˚C at more than 85 ˚C)
125 VAC, 250 VAC
0.0010 µF to 10 µF (E12)
±5 %(J), ±10 %(K)
tan <=1.0 % (20 ˚C, 1 kHz)
•Rated volt. 100 V to 630 VDC
Between terminals : Rated volt.(VDC)✕150 % 60 s
•Rated volt. 1000 VDC, 1250 VDC
Between terminals : Rated volt. (VDC)✕175 % 2 s to 5 s or 1000 VAC 60 s
Between terminals to enclosure : 1500 VAC 60 s
•Rated volt. 125 VAC, 250 VAC
Between terminals : Rated volt.(VAC)✕230 % 60 s
Between terminals to enclosure : 1500 VAC 60 s
100 V to 630 VDC: C <= 0.33 µF : IR>=9000 MΩ (20 ˚C, 100 VDC, 60 s)
C > 0.33 µF : IR>=3000 MΩ . µF
1000 VDC, 1250 VDC: IR>=10000 MΩ (20 ˚C, 100 VDC, 60 s)
IR>=2000 MΩ (20 ˚C, 500 VDC, 60 s)
125 VAC, 250 VAC: C <= 0.47 µF : IR>=2000 MΩ (20 ˚C, 500 VDC, 60 s)
C > 0.47 µF : IR>=3000 MΩ . µF (20 ˚C, 100 VDC, 60 s)
❈ In case of applying voltage in alternating current (50 Hz or 60 Hz sine wave) to a capacitor with DC rated voltage, please
refer to the page of “Permissible voltage (R.M.S) in alternating current corresponding to DC rated voltage”.
❈ Voltage to be applied to ECQE1A (F) & ECQE2A (F) is only sine wave (50 Hz or 60 Hz).
Suffix
Blank
B
Z
3
6
Lead Form
Straight
Crimped lead
Cut lead
Crimped taping (Ammo)
Crimped taping (Ammo)
p Œ ¯ ¶ ‚ /P33-52 12.11.14 19:29 y [ W 32
Design, Specifications are subject to change without notice. Ask factory for technical specifications before purchase and/or use.
Whenever a doubt about safety arises from this product, please inform us immediately for technical consultation without fail.
- FC33 -
Plastic Film Capacitors
■Dimensions in mm (not to scale)
Cut lead
■Packaging Specifications for Bulk Package
Packing quantity:100 pcs./bag
■Taping Specifications for Automatic Insertion
●Taping style
❈Refer to the page of taping specifications.
100 VDC
250 VDC
400 VDC
630 VDC
1000 VDC
1250 VDC
125 VAC
250 VAC
ECQE (F)
AD AS AB BCD E
0.56 to 0.68 ○ Ammo ( ) F3
0.82 to 1.0 ○ Ammo ( ) F3
1.2 to 3.3 ○ Ammo ( ) F3
1.2 to 3.3 ○ Ammo R( ) F
0.010 to 0.27 ○ Ammo ( ) F3
0.33 ○ Ammo ( ) F3
0.39 to 1.5 ○ Ammo ( ) F3
0.010 to 0.33 ○ Ammo R( ) F
0.39 to 1.5 ○ Ammo R( ) F
0.010 to 0.10 ○ Ammo ( ) F3
0.12 to 0.47 ○ Ammo ( ) F3
0.010 to 0.10 ○ Ammo R( ) F
0.12 to 0.47 ○ Ammo R( ) F
0.0010 to 0.033 ○ Ammo ( ) F3
0.039 to 0.047 ○ Ammo ( ) F3
0.056 to 0.22 ○ Ammo ( ) F3
0.0010 to 0.047 ○ Ammo R( ) F
0.056 to 0.22 ○ Ammo R( ) F
0.010 to 0.10 ○ Ammo R( ) F
0.0010 to 0.022 ○ Ammo R( ) F
0.010 to 0.068 ○ Ammo ( ) F6
0.010 to 0.068 ○ Ammo R( ) F
0.010 to 0.033 ○ Ammo ( ) F6
0.010 to 0.047 ○ Ammo R( ) F
0.056 to 0.22 ○ Ammo R( ) F
●Packaging Specifications
Cap. range
(µF)
Taping style Type Rated volt. Packing suffix Style
AD
AB
B
C
D
E
Lead Spacing
5.0 mm
5.0 mm
5.0 mm
5.0 mm
7.5 mm
7.5 mm
❈See the column
“Rating, Dimensions
& Quantity Box” for
packing quantity.
●Lead Spacing
Metallized Film
p Œ ¯ ¶ ‚ /P33-52 12.11.14 19:29 y [ W 33
Design, Specifications are subject to change without notice. Ask factory for technical specifications before purchase and/or use.
Whenever a doubt about safety arises from this product, please inform us immediately for technical consultation without fail.
- FC34 -
Plastic Film Capacitors
■Rating, Dimensions & Quantity/Ammo Box
●Rated voltage : 250 VDC, Capacitance tolerance : ±5 %(J), ±10 %(K)
Style D: 0.010 µF to 0.33 µF
Style B: 0.39 µF to 10.0 µF Suffix for lead crimped or taped type
Cap. tol. code
▲ ▲
Suffix for lead crimped or taped type
Cap. tol. code
▲ ▲
■Rating, Dimensions & Quantity/Ammo Box
●Rated voltage : 100 VDC, Capacitance tolerance : ± 5 %(J), ±10 %(K)
0.56 12.0 5.5 10.9 15.9 10.0 10.0 1.0 0.60
0.68 12.0 6.0 11.9 16.9 10.0 10.0 1.0 0.60
0.82 12.0 6.0 13.5 18.5 10.0 10.0 1.0 0.60
1.0 12.0 6.7 14.0 19.0 10.0 10.0 1.0 0.60
1.2 18.5 5.5 12.8 17.8 15.0 10.0 1.0 0.60
1.5 18.5 6.0 13.4 18.4 15.0 10.0 1.0 0.80
1.8 18.5 6.5 14.4 19.4 15.0 10.0 1.0 0.80
2.2 18.5 7.0 15.0 20.0 15.0 10.0 1.0 0.80
2.7 18.5 8.0 15.8 20.8 15.0 10.0 1.0 0.80
3.3 18.5 8.5 16.5 21.5 15.0 10.0 1.0 0.80
3.9 26.0 7.0 16.4 21.4 22.5 15.0 1.0 0.80
4.7 26.0 7.5 17.0 22.0 22.5 15.0 1.0 0.80
5.6 26.0 8.3 17.5 22.5 22.5 15.0 1.0 0.80
6.8 26.0 9.0 18.5 23.5 22.5 15.0 1.0 0.80
8.2 26.0 10.0 20.0 25.0 22.5 15.0 1.5 0.80
10.0 26.0 11.5 21.0 26.0 22.5 15.0 1.5 0.80
Part No. Cap.
(µF)
Min. order Q'ty
Taping
500 -
- -
-
Dimensions (mm)
L max. T max. Standard
5 mm Odd size
5 mm Odd size
7.5 mm
ø d
ECQE1564□F( )
ECQE1684□F( )
ECQE1824□F( )
ECQE1105□F( )
ECQE1125□F( )
ECQE1155□F( )
ECQE1185□F( )
ECQE1225□F( )
ECQE1275□F( )
ECQE1335□F( )
ECQE1395□F( )
ECQE1475□F( )
ECQE1565□F( )
ECQE1685□F( )
ECQE1825□F( )
ECQE1106□F( )
500
1,000
400 400
500
600
-
H max.
Straight Crimped lead Straight
F
Crimped lead
S
Straight
G max.
Bulk
500
style D: 0.056 µF to 1.0 µF
style B: 1.2 µF to 10.0 µF
Part No. Cap.
(µF)
Dimensions (mm)
L max. T max. ø d
ECQE2103□F( ) 0.010 10.3 4.3 7.4 12.4 7.5 7.5 1.0 0.60
ECQE2123□F( ) 0.012 10.3 4.4 7.5 12.5 7.5 7.5 1.0 0.60
ECQE2153□F( ) 0.015 10.3 4.4 7.5 12.5 7.5 7.5 1.0 0.60
ECQE2183□F( ) 0.018 10.3 4.4 7.5 12.5 7.5 7.5 1.0 0.60
ECQE2223□F( ) 0.022 10.3 4.4 7.5 12.5 7.5 7.5 1.0 0.60
ECQE2273□F( ) 0.027 10.3 4.4 7.5 12.5 7.5 7.5 1.0 0.60
ECQE2333□F( ) 0.033 10.3 4.5 7.5 12.5 7.5 7.5 1.0 0.60
ECQE2393□F( ) 0.039 10.3 4.5 7.5 12.5 7.5 7.5 1.0 0.60
ECQE2473□F( ) 0.047 10.3 4.5 7.5 12.5 7.5 7.5 1.0 0.60
ECQE2563□F( ) 0.056 10.3 4.8 7.9 12.9 7.5 7.5 1.0 0.60
ECQE2683□F( ) 0.068 10.3 4.5 7.5 12.5 7.5 7.5 1.0 0.60
ECQE2823□F( ) 0.082 10.3 4.9 8.0 13.0 7.5 7.5 1.0 0.60
ECQE2104□F( ) 0.10 10.3 5.8 8.4 13.4 7.5 7.5 1.0 0.60
ECQE2124□F( ) 0.12 10.3 6.0 9.0 14.0 7.5 7.5 1.0 0.60
ECQE2154□F( ) 0.15 10.3 6.0 10.8 15.8 7.5 7.5 1.0 0.60
ECQE2184□F( ) 0.18 12.0 5.0 10.3 15.3 10.0 10.0 1.0 0.60
ECQE2224□F( ) 0.22 12.0 5.5 10.5 15.5 10.0 10.0 1.0 0.60
ECQE2274□F( ) 0.27 12.0 6.0 11.5 16.5 10.0 10.0 1.0 0.60
ECQE2334□F( ) 0.33 12.0 6.5 12.0 17.0 10.0 10.0 1.0 0.60
ECQE2394□F( ) 0.39 18.5 4.9 12.0 17.0 15.0 10.0 1.0 0.60
ECQE2474□F( ) 0.47 18.5 5.3 12.5 17.5 15.0 10.0 1.0 0.60
ECQE2564□F( ) 0.56 18.5 5.5 13.0 18.0 15.0 10.0 1.0 0.60
ECQE2684□F( ) 0.68 18.5 6.0 13.5 18.5 15.0 10.0 1.0 0.80
ECQE2824□F( ) 0.82 18.5 6.5 14.5 19.5 15.0 10.0 1.0 0.80
ECQE2105□F( ) 1.0 18.5 7.4 15.0 20.0 15.0 10.0 1.0 0.80
ECQE2125□F( ) 1.2 18.5 8.0 15.9 20.9 15.0 10.0 1.0 0.80
ECQE2155□F( ) 1.5 18.5 9.0 16.8 21.8 15.0 10.0 1.0 0.80
ECQE2185□F( ) 1.8 26.0 7.5 15.5 20.5 22.5 15.0 1.0 0.80
ECQE2225□F( ) 2.2 26.0 8.5 16.3 21.3 22.5 15.0 1.0 0.80
ECQE2275□F( ) 2.7 26.0 9.4 17.0 22.0 22.5 15.0 1.0 0.80
ECQE2335□F( ) 3.3 26.0 10.3 18.0 23.0 22.5 15.0 1.5 0.80
ECQE2395□F( ) 3.9 26.0 11.0 20.5 25.5 22.5 15.0 1.5 0.80
ECQE2475□F( ) 4.7 26.0 12.0 21.5 26.5 22.5 15.0 1.5 0.80
ECQE2565□F( ) 5.6 31.0 11.8 21.0 26.0 27.5 22.5 1.5 0.80
ECQE2685□F( ) 6.8 31.0 13.0 22.4 27.4 27.5 22.5 1.5 0.80
ECQE2825□F( ) 8.2 31.0 14.3 23.5 28.5 27.5 22.5 1.5 0.80
ECQE2106□F( )10.0 31.0 15.9 25.8 30.8 27.5 22.5 1.5 0.80
1000
-
- 1000
500
500
1000
400
500
400
300
- -
H max.
Straight Crimped lead Straight
F
Crimped lead
S
Straight
G max.
500
Min. order Q'ty
Taping Standard
5 mm Odd size
5 mm Odd size
7.5 mm
Bulk
p Œ ¯ ¶ ‚ /P33-52 12.11.14 19:29 y [ W 34
Design, Specifications are subject to change without notice. Ask factory for technical specifications before purchase and/or use.
Whenever a doubt about safety arises from this product, please inform us immediately for technical consultation without fail.
- FC35 -
Plastic Film Capacitors
■Rating, Dimensions & Quantity/Ammo Box
●Rated voltage : 400 VDC, Capacitance tolerance : ±5 %(J), ±10 %(K)
style D:0.010 µF to 0.10 µF
style B:0.12 µF to 2.2 µF
Suffix for lead crimped or taped type
Cap. tol. code
▲ ▲
Part No.
0.010 10.3 4.3 7.4 12.4 7.5 7.5 1.0 0.60
0.012 10.3 4.4 7.5 12.5 7.5 7.5 1.0 0.60
0.015 10.3 4.4 7.5 12.5 7.5 7.5 1.0 0.60
0.018 10.3 4.4 7.5 12.5 7.5 7.5 1.0 0.60
0.022 10.3 4.8 7.9 12.9 7.5 7.5 1.0 0.60
0.027 10.3 5.5 8.0 13.0 7.5 7.5 1.0 0.60
0.033 10.3 6.0 9.0 14.0 7.5 7.5 1.0 0.60
0.039 12.0 4.9 8.0 13.0 10.0 10.0 1.0 0.60
0.047 12.0 5.0 8.3 13.3 10.0 10.0 1.0 0.60
0.056 12.0 5.0 10.0 15.0 10.0 10.0 1.0 0.60
0.068 12.0 5.4 10.5 15.5 10.0 10.0 1.0 0.60
0.082 12.0 5.8 11.0 16.0 10.0 10.0 1.0 0.60
0.10 12.0 6.3 12.0 17.0 10.0 10.0 1.0 0.60
0.12 18.5 5.0 10.0 15.0 15.0 10.0 1.0 0.60
0.15 18.5 5.0 12.4 17.4 15.0 10.0 1.0 0.60
0.18 18.5 5.4 12.5 17.5 15.0 10.0 1.0 0.60
0.22 18.5 5.9 13.0 18.0 15.0 10.0 1.0 0.60
0.27 18.5 6.5 14.3 19.3 15.0 10.0 1.0 0.80
0.33 18.5 7.0 14.9 19.9 15.0 10.0 1.0 0.80
0.39 18.5 7.5 15.4 20.4 15.0 10.0 1.0 0.80
0.47 18.5 7.8 17.0 22.0 15.0 10.0 1.0 0.80
0.56 26.0 6.5 16.0 21.0 22.5 15.0 1.0 0.80
0.68 26.0 7.0 16.5 21.5 22.5 15.0 1.0 0.80
0.82 26.0 7.9 17.3 22.3 22.5 15.0 1.0 0.80
1.0 26.0 8.5 18.0 23.0 22.5 15.0 1.0 0.80
1.2 26.0 9.5 18.9 23.9 22.5 15.0 1.0 0.80
1.5 31.0 9.5 19.0 24.0 27.5 22.5 1.0 0.80
1.8 31.0 11.0 20.5 25.5 27.5 22.5 1.5 0.80
2.2 31.0 11.0 22.0 27.0 27.5 22.5 1.5 0.80
ECQE4103□F( )
ECQE4123□F( )
ECQE4153□F( )
ECQE4183□F( )
ECQE4223□F( )
ECQE4273□F( )
ECQE4333□F( )
ECQE4393□F( )
ECQE4473□F( )
ECQE4563□F( )
ECQE4683□F( )
ECQE4823□F( )
ECQE4104□F( )
ECQE4124□F( )
ECQE4154□F( )
ECQE4184□F( )
ECQE4224□F( )
ECQE4274□F( )
ECQE4334□F( )
ECQE4394□F( )
ECQE4474□F( )
ECQE4564□F( )
ECQE4684□F( )
ECQE4824□F( )
ECQE4105□F( )
ECQE4125□F( )
ECQE4155□F( )
ECQE4185□F( )
ECQE4225□F( )
Cap.
(µF)
1000
500
-
-
500
500
400
- -
1000
Dimensions (mm)
L max. T max. φd H max.
Straight Crimped lead Straight
F
Crimped lead
S
Straight
G max.
500
Min. order Q'ty
Taping Standard
5 mm Odd size
5 mm Odd size
7.5 mm
Bulk
Metallized Film
p Œ ¯ ¶ ‚ /P33-52 12.11.14 19:29 y [ W 35
Design, Specifications are subject to change without notice. Ask factory for technical specifications before purchase and/or use.
Whenever a doubt about safety arises from this product, please inform us immediately for technical consultation without fail.
- FC36 -
Plastic Film Capacitors
●Rated voltage : 630 VDC, Capacitance tolerance : ±5 %(J), ±10 %(K)
Suffix for lead crimped or taped type.
Cap. tol. code
▲ ▲
style D:0.010 µF to 0.047 µF
style B:0.0010 µF to 0.0082 µF, 0.056 µF to 2.2 µF
Part No.
0.0010 10.0 4.5 9.5 14.5 7.5 5.0 1.0 0.60
0.0012 10.0 4.5 10.0 15.0 7.5 5.0 1.0 0.60
0.0015 10.0 4.5 10.0 15.0 7.5 5.0 1.0 0.60
0.0018 10.0 4.5 10.0 15.0 7.5 5.0 1.0 0.60
0.0022 10.0 4.5 10.0 15.0 7.5 5.0 1.0 0.60
0.0027 10.0 4.5 10.0 15.0 7.5 5.0 1.0 0.60
0.0033 10.0 4.5 10.0 15.0 7.5 5.0 1.0 0.60
0.0039 10.0 4.5 10.0 15.0 7.5 5.0 1.0 0.60
0.0047 12.0 4.5 10.0 15.0 10.0 7.5 1.0 0.60
0.0056 12.0 4.5 10.0 15.0 10.0 7.5 1.0 0.60
0.0068 12.0 4.9 10.0 15.0 10.0 7.5 1.0 0.60
0.0082 12.0 4.5 10.0 15.0 10.0 7.5 1.0 0.60
0.010 12.0 4.5 7.5 12.5 10.0 10.0 1.0 0.60
0.012 12.0 4.5 7.8 12.8 10.0 10.0 1.0 0.60
0.015 12.0 5.0 8.2 13.2 10.0 10.0 1.0 0.60
0.018 12.0 4.9 10.0 15.0 10.0 10.0 1.0 0.60
0.022 12.0 5.3 10.5 15.5 10.0 10.0 1.0 0.60
0.027 12.0 5.5 10.9 15.9 10.0 10.0 1.0 0.60
0.033 12.0 6.0 11.9 16.9 10.0 10.0 1.0 0.60
0.039 12.0 6.0 13.4 18.4 10.0 10.0 1.0 0.60
0.047 12.0 6.5 13.5 18.5 10.0 10.0 1.0 0.60
0.056 18.5 5.4 10.5 15.5 15.0 10.0 1.0 0.60
0.068 18.5 5.8 11.0 16.0 15.0 10.0 1.0 0.60
0.082 18.5 6.5 12.0 17.0 15.0 10.0 1.0 0.60
0.10 18.5 6.3 14.0 19.0 15.0 10.0 1.0 0.60
0.12 18.5 6.3 14.5 19.5 15.0 10.0 1.0 0.80
0.15 18.5 7.5 15.4 20.4 15.0 10.0 1.0 0.80
0.18 18.5 8.0 16.0 21.0 15.0 10.0 1.0 0.80
0.22 18.5 9.0 16.5 21.5 15.0 10.0 1.0 0.80
0.27 26.0 7.0 16.5 21.5 22.5 15.0 1.0 0.80
0.33 26.0 7.8 17.0 22.0 22.5 15.0 1.0 0.80
0.39 26.0 8.5 17.9 22.9 22.5 15.0 1.0 0.80
0.47 26.0 9.3 18.5 23.5 22.5 15.0 1.0 0.80
0.56 26.0 10.0 20.0 25.0 22.5 15.0 1.5 0.80
0.68 26.0 11.5 21.0 26.0 22.5 15.0 1.5 0.80
0.82 31.0 11.3 20.5 25.5 27.5 22.5 1.5 0.80
1.0 31.0 12.5 21.9 26.9 27.5 22.5 1.5 0.80
1.2 31.0 13.5 23.0 28.0 27.5 22.5 1.5 0.80
1.5 31.0 15.3 24.7 29.7 27.5 22.5 1.5 0.80
1.8 31.0 16.8 27.0 32.0 27.5 22.5 1.5 0.80
2.2 31.0 19.5 29.0 34.0 27.5 22.5 1.5 0.80
ECQE6102□F( )
ECQE6122□F( )
ECQE6152□F( )
ECQE6182□F( )
ECQE6222□F( )
ECQE6272□F( )
ECQE6332□F( )
ECQE6392□F( )
ECQE6472□F( )
ECQE6562□F( )
ECQE6682□F( )
ECQE6822□F( )
ECQE6103□F( )
ECQE6123□F( )
ECQE6153□F( )
ECQE6183□F( )
ECQE6223□F( )
ECQE6273□F( )
ECQE6333□F( )
ECQE6393□F( )
ECQE6473□F( )
ECQE6563□F( )
ECQE6683□F( )
ECQE6823□F( )
ECQE6104□F( )
ECQE6124□F( )
ECQE6154□F( )
ECQE6184□F( )
ECQE6224□F( )
ECQE6274□F( )
ECQE6334□F( )
ECQE6394□F( )
ECQE6474□F( )
ECQE6564□F( )
ECQE6684□F( )
ECQE6824□F( )
ECQE6105□F( )
ECQE6125□F( )
ECQE6155□F( )
ECQE6185□F( )
ECQE6225□F( )
Cap.
(µF)
1000 -
1000
500
400
300
1000
500
400
- -
500
-
Dimensions (mm)
L max. T max. φd H max.
Straight Crimped lead Straight
F
Crimped lead
S
Straight
G max.
500
Min. order Q'ty
Taping Standard
5 mm Odd size
5 mm Odd size
7.5 mm
Bulk
p Œ ¯ ¶ ‚ /P33-52 12.11.14 19:29 y [ W 36
Design, Specifications are subject to change without notice. Ask factory for technical specifications before purchase and/or use.
Whenever a doubt about safety arises from this product, please inform us immediately for technical consultation without fail.
- FC37 -
Plastic Film Capacitors
■Rating, Dimensions & Quantity/Ammo Box
●Rated voltage : 1000 VDC, Note) 125 VAC, Capacitance tolerance : ±5 %(J), ±10 %(K)
Note) This type has two rated voltage, one is DC rated voltage another is AC rated voltage..
DC rated voltage is 1000 V, AC rated voltage is 125 V.
Making for rated voltage is「1000 V, 125 V 」
When capacitors use in secondary side of power source, and in case of applying voltage in altering current (50 Hz or 60 Hz sine wave)
to a capacitor, please refer to the page of ''Permissible voltage (R.M.S) in altering current corresponding to DC rated voltage''.
When capacitors use in primary side of power source, the rated voltage is shown 125 VAC. Voltage to be applied to capacitors in only
sine wave (50 Hz or 60 Hz).
AC rated capacitors complying with clause 1 of ''Electrical Appliance and Material Safety Law''. And not complying with clause 2 of
''Electrical Appliance and Material Safety Law'', in this case please use ECQUL type or ECQUG type
Part No.
0.010 15.5 6.0 11.0 16.0 12.5 12.5 1.0 0.60
0.012 15.5 6.0 12.0 17.0 12.5 12.5 1.0 0.60
0.015 15.5 7.0 12.5 17.5 12.5 12.5 1.0 0.60
0.018 15.5 7.5 13.0 20.0 12.5 12.5 1.0 0.80
0.022 15.5 7.5 15.5 22.5 12.5 12.5 1.0 0.80
0.027 21.0 6.0 13.0 18.0 17.5 12.5 1.0 0.80
0.033 21.0 6.5 14.0 19.0 17.5 12.5 1.0 0.80
0.039 21.0 7.0 14.5 19.5 17.5 12.5 1.0 0.80
0.047 21.0 7.5 15.5 20.5 17.5 12.5 1.0 0.80
0.056 21.0 7.5 17.0 22.0 17.5 12.5 1.0 0.80
0.068 21.0 8.5 18.0 23.0 17.5 12.5 1.0 0.80
0.082 21.0 9.0 18.5 23.5 17.5 12.5 1.0 0.80
0.10 21.0 10.0 20.0 25.0 17.5 12.5 1.0 0.80
0.12 26.0 9.0 18.5 23.5 22.5 17.5 1.0 0.80
0.15 26.0 10.0 20.0 25.0 22.5 17.5 1.5 0.80
0.18 26.0 10.5 22.0 27.0 22.5 17.5 1.5 0.80
0.22 26.0 12.0 23.0 28.0 22.5 17.5 1.5 0.80
ECQE10103□F( )
ECQE10123□F( )
ECQE10153□F( )
ECQE10183□F( )
ECQE10223□F( )
ECQE10273□F( )
ECQE10333□F( )
ECQE10393□F( )
ECQE10473□F( )
ECQE10563□F( )
ECQE10683□F( )
ECQE10823□F( )
ECQE10104□F( )
ECQE10124□F( )
ECQE10154□F( )
ECQE10184□F( )
ECQE10224□F( )
Cap.
(µF)
Min. order Q'ty
500
400
500
400
300
-
Dimensions (mm)
L max. T max. ø d 7.5 mm
H max.
Straight Crimped lead Straight
F
Crimped lead
S
Straight
G max.
500
Bulk Taping
Style D: 0.010 µF to 0.022 µF
Style B: 0.027 µF to 0.22 µF
Suffix for lead crimped or taped type.
Cap. tol. code
▲ ▲
Metallized Film
p Œ ¯ ¶ ‚ /P33-52 12.11.14 19:29 y [ W 37
Design, Specifications are subject to change without notice. Ask factory for technical specifications before purchase and/or use.
Whenever a doubt about safety arises from this product, please inform us immediately for technical consultation without fail.
- FC38 -
Plastic Film Capacitors
■Rating, Dimensions & Quantity/Ammo Box
●Rated voltage : 1250 VDC, Note) 125 VAC, Capacitance tolerance : ±5 %(J), ±10 %(K)
Note) This type has two rated voltage, one is DC rated voltage another is AC rated voltage..
DC rated voltage is 1250 V, AC rated voltage is 125 V.
Making for rated voltage is「1250 V, 125 V 」
When capacitors use in secondary side of power source, and in case of applying voltage in altering current (50 Hz or 60 Hz sine wave)
to a capacitor, please refer to the page of ''Permissible voltage (R.M.S) in altering current corresponding to DC rated voltage''.
When capacitors use in primary side of power source, the rated voltage is shown 125 VAC. Voltage to be applied to capacitors in only
sine wave (50 Hz or 60 Hz).
AC rated capacitors complying with clause 1 of ''Electrical Appliance and Material Safety Law''. And not complying with clause 2 of
''Electrical Appliance and Material Safety Law'', in this case please use ECQUL type or ECQUG type
Style D: 0.0010 µF to 0.0068 µF
Style B: 0.0082 µF to 0.22 µF
Part No.
0.0010 15.5 6.0 11.0 16.0 12.5 10.0 1.0 0.60
0.0012 15.5 6.0 11.0 16.0 12.5 10.0 1.0 0.60
0.0015 15.5 6.0 11.0 16.0 12.5 10.0 1.0 0.60
0.0018 15.5 6.0 11.0 16.0 12.5 10.0 1.0 0.60
0.0022 15.5 6.0 11.5 16.5 12.5 10.0 1.0 0.60
0.0027 15.5 6.5 12.0 17.0 12.5 10.0 1.0 0.60
0.0033 15.5 6.0 11.5 16.5 12.5 10.0 1.0 0.60
0.0039 15.5 6.5 12.0 17.0 12.5 10.0 1.0 0.60
0.0047 15.5 7.0 12.5 17.5 12.5 10.0 1.0 0.60
0.0056 15.5 7.5 13.0 18.0 12.5 10.0 1.0 0.60
0.0068 15.5 7.5 15.0 20.0 12.5 10.0 1.0 0.60
0.0082 21.0 5.0 12.0 17.0 17.5 12.5 1.0 0.60
0.010 21.0 5.0 12.5 17.5 17.5 12.5 1.0 0.60
0.012 21.0 5.5 13.0 18.0 17.5 12.5 1.0 0.60
0.015 21.0 6.0 13.5 18.5 17.5 12.5 1.0 0.60
0.018 21.0 6.5 14.5 19.5 17.5 12.5 1.0 0.80
0.022 21.0 7.0 15.0 20.0 17.5 12.5 1.0 0.80
0.027 26.0 6.0 15.5 20.5 22.5 17.5 1.0 0.80
0.033 26.0 6.5 16.0 21.0 22.5 17.5 1.0 0.80
0.039 26.0 7.0 16.5 21.5 22.5 17.5 1.0 0.80
0.047 26.0 8.0 17.0 22.0 22.5 17.5 1.0 0.80
0.056 31.0 7.5 17.0 22.0 27.5 22.5 1.0 0.80
0.068 31.0 8.0 17.5 22.5 27.5 22.5 1.0 0.80
0.082 31.0 9.0 18.5 23.5 27.5 22.5 1.0 0.80
0.10 31.0 10.0 19.5 24.5 27.5 22.5 1.0 0.80
0.12 31.0 11.5 20.5 25.5 27.5 22.5 1.5 0.80
0.15 31.0 12.0 23.0 28.0 27.5 22.5 1.5 0.80
0.18 31.0 13.0 24.5 29.5 27.5 22.5 1.5 0.80
0.22 31.0 14.5 26.5 31.5 27.5 22.5 1.5 0.80
ECQE12102□F( )
ECQE12122□F( )
ECQE12152□F( )
ECQE12182□F( )
ECQE12222□F( )
ECQE12272□F( )
ECQE12332□F( )
ECQE12392□F( )
ECQE12472□F( )
ECQE12562□F( )
ECQE12682□F( )
ECQE12822□F( )
ECQE12103□F( )
ECQE12123□F( )
ECQE12153□F( )
ECQE12183□F( )
ECQE12223□F( )
ECQE12273□F( )
ECQE12333□F( )
ECQE12393□F( )
ECQE12473□F( )
ECQE12563□F( )
ECQE12683□F( )
ECQE12823□F( )
ECQE12104□F( )
ECQE12124□F( )
ECQE12154□F( )
ECQE12184□F( )
ECQE12224□F( )
Cap.
(µF)
Min. order Q'ty
500
400
500
Dimensions (mm)
L max. T max. ø d 7.5 mm
H max.
Straight Crimped lead Straight
F
Crimped lead
S
Straight
G max.
Bulk Taping
500
Suffix for lead crimped or taped type.
Cap. tol. code
▲ ▲
p Œ ¯ ¶ ‚ /P33-52 12.11.14 19:29 y [ W 38
Design, Specifications are subject to change without notice. Ask factory for technical specifications before purchase and/or use.
Whenever a doubt about safety arises from this product, please inform us immediately for technical consultation without fail.
- FC39 -
Plastic Film Capacitors
■Rating, Dimensions & Quantity/Ammo Box
●Rated voltage : 125 VAC, Capacitance tolerance : ±5 %(J), ±10 %(K)
●Noise suppression Capacitors (Across-the-line)
style D:0.010 µF to 0.068 µF
Suffix for lead crimped or taped type.
Cap. tol. code
MF( )
Table 1
Notice for AC rated
AC rated capacitors complying with clause 1 of ''Electrical Appliance and Material Safety Law''.
As for clause 2 of ''Electrical Appliance and Material Safety Law'', please use ECQUL type or ECQUG type.
When using these capacitors as a across-the-line capacitor, it shall be required to follow either item 1. or item 2. condition.
1. Capacitor shall be connected in parallel with varistor (Specified varistor voltage in table 1.)
2. Voltage applied for capacitor shall not exceed other than specified in table 1, when using these capacitors.
Cap. Rated Voltage
125 VAC
Varistor voltage
250 V
Pulse voltage
250 V0–P
Part No.
0.010 10.5 4.5 7.5 12.5 7.5 7.5 1.0 0.60
0.012 10.5 4.4 7.5 12.5 7.5 7.5 1.0 0.60
0.015 10.5 4.4 7.5 12.5 7.5 7.5 1.0 0.60
0.018 10.5 4.4 7.5 12.5 7.5 7.5 1.0 0.60
0.022 10.5 4.4 7.5 12.5 7.5 7.5 1.0 0.60
0.027 10.5 4.4 7.5 12.5 7.5 7.5 1.0 0.60
0.033 10.5 4.5 7.8 12.8 7.5 7.5 1.0 0.60
0.039 10.5 4.5 7.8 12.8 7.5 7.5 1.0 0.60
0.047 10.5 5.5 8.0 13.0 7.5 7.5 1.0 0.60
0.056 10.5 5.9 8.5 13.5 7.5 7.5 1.0 0.60
0.068 10.5 6.3 9.4 14.4 7.5 7.5 1.0 0.60
ECQE1A103□F( )
ECQE1A123□F( )
ECQE1A153□F( )
ECQE1A183□F( )
ECQE1A223□F( )
ECQE1A273□F( )
ECQE1A333□F( )
ECQE1A393□F( )
ECQE1A473□F( )
ECQE1A563□F( )
ECQE1A683□F( )
Cap.
(µF)
1000
-
1000
500
Dimensions (mm)
L max. T max. φd H max.
Straight Crimped lead Straight
F
Crimped lead
S
Straight
G max.
500
Min. order Q'ty
Taping Standard
5 mm Odd size
5 mm Odd size
7.5 mm
Bulk
Metallized Film
p Œ ¯ ¶ ‚ /P33-52 12.11.14 19:29 y [ W 39
Design, Specifications are subject to change without notice. Ask factory for technical specifications before purchase and/or use.
Whenever a doubt about safety arises from this product, please inform us immediately for technical consultation without fail.
- FC40 -
Plastic Film Capacitors
●Rated voltage : 250 VAC, Capacitance tolerance : ±5 %(J), ±10 %(K)
Noise suppression Capacitors (Across-the-line)
Style D:0.010 µF to 0.047 µF
Style B:0.056 µF to 0.47 µF
Table 1
❈Please consult us about Crimed lead type of 0.56 µF to 2.2 µF.
Notice for AC rated
AC rated capacitors complying with clause 1 of ''Electrical Appliance and Material Safety Law''.
As for clause 2 of ''Electrical Appliance and Material Safety Law'', please use ECQUL type or ECQUG type.
When using these capacitors as a across-the-line capacitor, it shall be required to follow either item 1. or item 2. condition.
1. Capacitor shall be connected in parallel with varistor (Specified varistor voltage in table 1.)
2. Voltage applied for capacitor shall not exceed other than specified in table 1, when using these capacitors.
Cap. Rated Voltage
250 VAC
Varistor voltage
470 V
Pulse voltage
630 V0–P
Suffix for lead crimped or taped type.
Cap. tol. code
MF( )
Part No.
0.010 12.5 5.5 10.8 15.8 10.0 10.0 1.0 0.60
0.012 12.5 6.0 11.5 16.5 10.0 10.0 1.0 0.60
0.015 12.5 6.3 9.9 14.9 10.0 10.0 1.0 0.60
0.018 12.5 6.0 11.9 16.9 10.0 10.0 1.0 0.60
0.022 12.5 6.0 11.5 16.5 10.0 10.0 1.0 0.60
0.027 12.5 5.5 10.9 15.9 10.0 10.0 1.0 0.60
0.033 12.5 6.0 11.9 16.9 10.0 10.0 1.0 0.60
0.039 12.5 6.0 13.4 18.4 10.0 10.0 1.0 0.60
0.047 12.5 6.5 14.4 19.4 10.0 10.0 1.0 0.60
0.056 18.5 5.4 10.5 15.5 15.0 10.0 1.0 0.60
0.068 18.5 5.8 11.0 16.0 15.0 10.0 1.0 0.60
0.082 18.5 6.3 12.0 17.0 15.0 10.0 1.0 0.60
0.10 18.5 6.3 14.0 19.0 15.0 10.0 1.0 0.60
0.12 18.5 6.8 14.5 19.5 15.0 10.0 1.0 0.80
0.15 18.5 7.5 15.4 20.4 15.0 10.0 1.0 0.80
0.18 18.5 8.0 16.0 21.0 15.0 10.0 1.0 0.80
0.22 18.5 9.0 16.9 21.9 15.0 10.0 1.0 0.80
0.27 26.0 7.0 16.5 21.5 22.5 15.0 1.0 0.80
0.33 26.0 7.8 17.0 22.0 22.5 15.0 1.0 0.80
0.39 26.0 8.5 17.9 22.9 22.5 15.0 1.0 0.80
0.47 26.0 9.3 18.5 23.5 22.5 15.0 1.0 0.80
0.56 26.0 10.0 20.0 ─ 22.5 ─ 1.0 0.80
0.68 26.0 11.5 21.0 ─ 22.5 ─ 1.0 0.80
0.82 26.0 13.0 22.5 ─ 22.5 ─ 1.0 0.80
1.0 31.0 12.5 21.9 ─ 27.5 ─ 1.5 0.80
1.2 31.0 13.5 23.0 ─ 27.5 ─ 1.5 0.80
1.5 31.0 15.3 24.7 ─ 27.5 ─ 1.5 0.80
1.8 31.0 16.8 27.0 ─ 27.5 ─ 1.5 0.80
2.2 31.0 19.5 29.0 ─ 27.5 ─ 1.5 0.80
ECQE2A103□F( )
ECQE2A123□F( )
ECQE2A153□F( )
ECQE2A183□F( )
ECQE2A223□F( )
ECQE2A273□F( )
ECQE2A333□F( )
ECQE2A393□F( )
ECQE2A473□F( )
ECQE2A563□F( )
ECQE2A683□F( )
ECQE2A823□F( )
ECQE2A104□F( )
ECQE2A124□F( )
ECQE2A154□F( )
ECQE2A184□F( )
ECQE2A224□F( )
ECQE2A274□F( )
ECQE2A334□F( )
ECQE2A394□F( )
ECQE2A474□F( )
ECQE2A564P( )( )
ECQE2A684P( )( )
ECQE2A824P( )( )
ECQE2A105P( )( )
ECQE2A125P( )( )
ECQE2A155P( )( )
ECQE2A185P( )( )
ECQE2A225P( )( )
Cap.
(µF)
500
1000
500
400
300
-
-
Dimensions (mm)
L max. T max. φd H max.
Straight Crimped lead Straight
F
Crimped lead
S
Straight
G max.
500
Min. order Q'ty
Taping Standard
5 mm Odd size
7.5 mm
Bulk
p Œ ¯ ¶ ‚ /P33-52 12.11.14 19:29 y [ W 40
Temperature Characteristics Frequency Characteristics
0.01
0.1
1
10
100
1000
10000
1 10 100 1000 10000
0
2
4
6
8
10
1 10 100 1000 10000
-10
-5
0
5
10
1 10 100 1000 10000
1.E+06
1.E+07
1.E+08
1.E+09
1.E+10
1.E+11
1.E+12
-60 -40 -20 0 20 40 60 80 100
0
2
4
6
8
10
-60 -40 -20 0 20 40 60 80 100
-10
-5
0
5
10
-60 -40 -20 0 20 40 60 80 100
ECQE(F) Type 100VDC Series (Metallized Polyester Film)
Erectrical Characteristics
at 1kHz
Temperature (Degree C)
Capacitance change (%) Dissipation factor (%)
Temperature (Degree C)
at 1kHz
at DC100V
Temperature (Degree C)
Insuration resistance (ohm)
Capacitance change (%)
Frequency (kHz)
Frequency (kHz)
Dissipation factor (%)
Frequency (kHz)
Impedance (ohm)
10uF
4.7uF
1.0uF
10uF
4.7uF
1.0uF
10uF
4.7uF
1.0uF
10uF
4.7uF
1.0uF
1.0uF
4.7uF
10uF
1.0uF
4.7uF
10uF
Rating
Voltage
Capacitance
Value(uF) Code dV/dt(V/us) Current(o-p)
(A)
0.56 564 12.32
0.68 684 15.0
0.82 824 18.0
1.00 105 22.0
1.20 125 13.2
1.50 155 17.1
1.80 185 19.8
2.20 225 24.2
2.70 275 29.7
3.30 335 36.3
3.90 395 23.4
4.70 475 28.2
5.60 565 33.6
6.80 685 40.8
8.20 825 49.2
10.00 106 60.0
Pulse Handling Capability (dV/dt)
(Max 10000cycles)
Voltage Derating by Temperature
Permissible Current Permissible Voltage
6
22
100VDC
11
0
20
40
60
80
100
120
-60 -40 -20 0 20 40 60 80 100 120
0.1
1
10
100
10 100 1000
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
10 100 1000
* Please consult Panasonic if your condition exceeds the above spec.
ECQE(F) Type 100VDC Series (Metallized Polyester Film)
Applicable Specifications
Frequency (kHz)
Permissible Current (Arms)
Permissible Voltage (Vrms)
(at sinewave)
Frequency (kHz)
Rated Voltage (VDC)
Surface Temperature of Capacitor(Degree C)
1.0uF
2.2uF
4.7uF
10uF
1.0uF
2.2uF
4.7uF
10uF
From 0.56uF to 10uF
Temperature Characteristics Frequency Characteristics
0.01
0.1
1
10
100
1000
10000
1 10 100 1000 10000 100000
0
2
4
6
8
10
1 10 100 1000 10000
-10
-5
0
5
10
1 10 100 1000 10000
1.E+06
1.E+07
1.E+08
1.E+09
1.E+10
1.E+11
1.E+12
-60 -40 -20 0 20 40 60 80 100
0
2
4
6
8
10
-60 -40 -20 0 20 40 60 80 100
-10
-5
0
5
10
-60 -40 -20 0 20 40 60 80 100
ECQE(F) Type 250VDC Series (Metallized Polyester Film)
Erectrical Characteristics
at 1kHz
Temperature (Degree C)
Capacitance change (%) Dissipation factor (%)
Temperature (Degree C)
at 1kHz
at DC100V
Temperature (Degree C)
Insuration resistance (ohm)
Capacitance change (%)
Frequency (kHz)
Frequency (kHz)
Dissipation factor (%)
Frequency (kHz)
Impedance (ohm)
10uF
1.0uF
0.1uF
10uF
1.0uF
0.1uF
10uF
1.0uF
0.01uF
10uF
1.0uF
0.1uF
0.1uF
1.0uF
10uF
0.1uF
1.0uF
10uF
0.01uF
0.01uF
0.1uF
0.01uF
0.01uF
0.01uF
Rating
Voltage
Capacitance
Value(uF) Code dV/dt(V/us) Current(o-p)
(A)
0.010 103 0.48
0.015 153 0.72
0.022 223 1.06
0.033 333 1.58
0.047 473 2.26
0.068 683 3.26
0.100 104 4.80
0.150 154 7.20
0.220 224 7.26
0.330 334 10.89
0.470 474 8.46
0.680 684 12.24
1.000 105 18.00
1.500 155 27.00
2.200 225 22.00
3.300 335 33.00
4.700 475 47.00
6.800 685 54.40
10.000 106 80.00
250VDC
Pulse Handling Capability (dV/dt) Voltage Derating by Temperature
(Max 10000cycles)
48
8
10
18
33
Permissible Current Permissible Voltage
0
50
100
150
200
250
300
-60 -40 -20 0 20 40 60 80 100 120
1
10
100
10 100 1000
0
1
2
3
4
5
10 100 1000
* Please consult Panasonic if your condition exceeds the above spec.
ECQE(F) Type 250VDC Series (Metallized Polyester Film)
Applicable Specifications
Frequency (kHz)
Permissible Current (Arms)
Permissible Voltage (Vrms)
(at sinewave)
Frequency (kHz)
Rated Voltage (VDC)
Surface Temperature of Capacitor(Degree C)
1.0uF
2.2uF
4.7uF
10uF
From 0.01uF to 10uF
0.47uF
0.22uF
0.10uF
0.047u
0.022u
0.01uF
0.01uF
0.022uF
0.047uF
0.10uF
0.22uF
0.47uF
1.0uF
2.2uF
4.7uF
10uF
Temperature Characteristics Frequency Characteristics
0.01
0.1
1
10
100
1000
10000
1 10 100 1000 10000 100000
0
2
4
6
8
10
1 10 100 1000 10000
-10
-5
0
5
10
-60 -40 -20 0 20 40 60 80 100
-10
-5
0
5
10
1 10 100 1000 10000
1.E+07
1.E+08
1.E+09
1.E+10
1.E+11
1.E+12
1.E+13
-60 -40 -20 0 20 40 60 80 100
0
2
4
6
8
10
-60 -40 -20 0 20 40 60 80 100
ECQE(F) Type 400VDC Series (Metallized Polyester Film)
Erectrical Characteristics
at 1kHz
Temperature (Degree C)
Capacitance change (%) Dissipation factor (%)
Temperature (Degree C)
at 1kHz
at DC100V
Temperature (Degree C)
Insuration resistance (ohm)
Capacitance change (%)
Frequency (kHz)
Frequency (kHz)
Dissipation factor (%)
Frequency (kHz)
Impedance (ohm)
2.2uF
1.0uF
0.1uF
2.2uF
1.0uF
0.1uF
2.2uF
1.0uF
0.1uF
0.01uF
0.01uF
0.01uF
0.01uF
0.1uF
1.0uF
2.2uF
0.01uF
0.1uF
1.0uF
2.2uF
2.2uF
1.0uF
0.1uF
0.01uF
Rating
Voltage
Capacitance
Value(uF) Code dV/dt(V/us) Current(o-p)
(A)
0.010 103 1.31
0.015 153 1.97
0.022 223 2.88
0.033 333 4.32
0.047 473 3.67
0.068 683 5.30
0.100 104 7.80
0.150 154 5.55
0.220 224 8.14
0.330 334 12.21
0.470 474 17.39
0.680 684 14.96
1.000 105 22.00
1.200 155 27.00
2.200 225 39.60
Permissible Voltage
Voltage Derating by Temperature
131
Permissible Current
Pulse Handling Capability (dV/dt)
(Max 10000cycles)
400VDC
78
37
22
18
0
100
200
300
400
500
-60 -40 -20 0 20 40 60 80 100 120
0
0.5
1
1.5
2
2.5
3
10 100 1000
1
10
100
10 100 1000
* Please consult Panasonic if your condition exceeds the above spec.
ECQE(F) Type 400VDC Series (Metallized Polyester Film)
Applicable Specifications
Frequency (kHz)
Permissible Current (Arms)
Permissible Voltage (Vrms)
(at sinewave)
Frequency (kHz)
Rated Voltage (VDC)
Surface Temperature of Capacitor(Degree C)
From 0.01uF to 2.2uF
2.2uF
1.0uF
0.47uF
0.22uF
0.1uF
0.047uF
0.022uF
0.01uF
0.01uF
0.022uF
0.047uF
0.1uF
0.22uF
0.47uF
1.0uF
2.2uF
Temperature Characteristics Frequency Characteristics
0.01
0.1
1
10
100
1000
10000
1 10 100 1000 10000 100000
0
2
4
6
8
10
1 10 100 1000 10000
-10
-5
0
5
10
1 10 100 1000 10000
1.E+07
1.E+08
1.E+09
1.E+10
1.E+11
1.E+12
1.E+13
-60 -40 -20 0 20 40 60 80 100
0
2
4
6
8
10
-60 -40 -20 0 20 40 60 80 100
-10
-5
0
5
10
-60 -40 -20 0 20 40 60 80 100
ECQE(F) Type 630VDC Series (Metallized Polyester Film)
Erectrical Characteristics
at 1kHz
Temperature (Degree C)
Capacitance change (%) Dissipation factor (%)
Temperature (Degree C)
at 1kHz
at DC100V
Temperature (Degree C)
Insuration resistance (ohm)
Capacitance change (%)
Frequency (kHz)
Frequency (kHz)
Dissipation factor (%)
Frequency (kHz)
Impedance (ohm)
2.2uF
1.0uF
0.1uF
2.2uF
1.0uF
0.1uF
1.0uF
0.1uF
0.01uF
0.01uF
0.01uF
0.01uF
0.1uF
1.0uF
2.2uF
0.01uF
0.1uF
1.0uF
2.2uF
2.2uF
1.0uF
0.1uF
0.01uF
2.2uF
Rating
Voltage
Capacitance
Value(uF) Code dV/dt(V/us) Current(o-p)
(A)
0.010 103 2.73
0.015 153 4.10
0.022 223 6.01
0.033 333 9.01
0.047 473 12.83
0.068 683 7.89
0.100 104 11.60
0.150 154 17.40
0.220 224 25.52
0.330 334 20.79
0.470 474 29.61
0.680 684 42.84
1.000 105 48.00
1.500 155 72.00
2.200 225 105.60
(Max 10000cycles)
273
Voltage Derating by Temperature
630VDC
Permissible Current Permissible Voltage
116
63
48
Pulse Handling Capability (dV/dt)
0
100
200
300
400
500
600
700
800
-60 -40 -20 0 20 40 60 80 100 120
1
10
100
10 100 1000
0
1
2
3
4
5
10 100 1000
* Please consult Panasonic if your condition exceeds the above spec.
ECQE(F) Type 630VDC Series (Metallized Polyester Film)
Applicable Specifications
Frequency (kHz)
Permissible Current (Arms)
Permissible Voltage (Vrms)
(at sinewave)
Frequency (kHz)
Rated Voltage (VDC)
Surface Temperature of Capacitor(Degree C)
From 0.01uF to 2.2uF
2.2uF
1.0uF
0.47uF
0.22uF
0.1uF
0.047uF
0.022uF
0.01uF
0.01uF
0.022uF
0.047uF
0.1uF
0.22uF
0.47uF
1.0uF
2.2uF
Temperature Characteristics Frequency Characteristics
0.01
0.1
1
10
100
1000
10000
1 10 100 1000 10000 100000
0
2
4
6
8
10
1 10 100 1000 10000
-10
-5
0
5
10
1 10 100 1000 10000
1.E+07
1.E+08
1.E+09
1.E+10
1.E+11
1.E+12
1.E+13
-60 -40 -20 0 20 40 60 80 100
0
2
4
6
8
10
-10
-5
0
5
10
-60 -40 -20 0 20 40 60 80 100
ECQE(F) Type 125VAC Series (Metallized Polyester Film)
Erectrical Characteristics
at 1kHz
Temperature (Degree C)
Capacitance change (%) Dissipation factor (%)
Temperature (Degree C)
at 1kHz
at DC100V
Temperature (Degree C)
Insuration resistance (ohm)
Capacitance change (%)
Frequency (kHz)
Frequency (kHz)
Dissipation factor (%)
Frequency (kHz)
Impedance (ohm)
0.47uF
0.1uF
0.047uF
0.47uF
0.1uF
0.047uF
0.47uF
0.1uF
0.01uF
0.47uF
0.1uF
0.047uF
0.047uF
0.1uF
0.47uF
0.047uF
0.1uF
0.47uF
0.01uF
0.01uF
0.047uF
0.01uF
0.01uF
0.01uF
Temperature Characteristics Frequency Characteristics
0.01
0.1
1
10
100
1000
10000
1 10 100 1000 10000 100000
0
2
4
6
8
10
1 10 100 1000 10000
-10
-5
0
5
10
1 10 100 1000 10000
1.E+07
1.E+08
1.E+09
1.E+10
1.E+11
1.E+12
1.E+13
-60 -40 -20 0 20 40 60 80 100
0
2
4
6
8
10
-60 -40 -20 0 20 40 60 80 100
-10
-5
0
5
10
-60 -40 -20 0 20 40 60 80 100
ECQE(F) Type 250VAC Series (Metallized Polyester Film)
Erectrical Characteristics
at 1kHz
Temperature (Degree C)
Capacitance change (%) Dissipation factor (%)
Temperature (Degree C)
at 1kHz
at DC100V
Temperature (Degree C)
Insuration resistance (ohm)
Capacitance change (%)
Frequency (kHz)
Frequency (kHz)
Dissipation factor (%)
Frequency (kHz)
Impedance (ohm)
0.47uF
0.1uF
0.047uF
0.47uF
0.1uF
0.047uF
0.47uF
0.1uF
0.01uF
0.47uF
0.1uF
0.047uF
0.047uF
0.1uF
0.47uF
0.047uF
0.1uF
0.47uF
0.01uF
0.01uF
0.047uF
0.01uF
0.01uF
0.01uF
Design and specifi cations are each subject to change without notice. Ask factory for the current technical specifi cations before purchase and/or use.
Should a safety concern arise regarding this product, please be sure to contact us immediately.
Aluminum Electrolytic Capacitors/ FR
– EEE-82 –
010 Sleeve
L 14 min. 3 min. =
=
L16 : L±1.5
L20 : L±2.0
Pressure relief
06.3 +
–
08
0D±0.5
F±0.5
0D±0.5
fd±0.05
■ Country of origin
Malaysia
Radial Lead Type
Series: FR Type: A
■ Specifi cations
Category Temp. Range –40 °C to +105 °C
Rated W.V. Range 6.3 V.DC to 100 V.DC
Nominal Cap. Range 4.7 μF to 8200 μF
Capacitance Tolerance ±20 % (120 Hz/+20 °C)
DC Leakage Cur rent I < 0.01 CV (μA) After 2 minutes
tan d
W.V. 6.3 10 16 25 35 50 63 100 (120 Hz/+20 °C) tan d 0.22 0.19 0.16 0.14 0.12 0.10 0.09 0.08
Add 0.02 per 1000 μF for products of 1000 μF or more.
Endurance
After following life test with DC voltage and +105 °C±2 °C ripple current value applied. (The sum
of DC and ripple peak voltage shall not exceed the rated working voltage) when the capacitors
are restored to 20 °C, the capacitors shall meet the limits specifi ed below.
Duration
05×11/ 06.3×11.2 : 5000 hours
08×11.5/ 010×12.5 : 6000 hours (✽ Only EEUFR1V331U (010×12.5) 5000 hours)
08×15/ 010×16 : 8000 hours, 08×20 : 9000 hours
010×20 to 010×25/ 012.5×20 to 012.5×35/ 016×20 to 016×25 : 10000 hours
Capacitance change ±25 % of initial measured value (6.3 V to 10 V : ±30 %)
tan d < 200 % of initial specifi ed value
DC leakage current < initial specifi ed value
Shelf Life After storage for 1000 hours at +105 °C±2 °C with no voltage applied and then being stabilized
at +20 °C, capacitors shall meet the limits specifi ed in Endurance. (With voltage treatment)
■ Di men sions in mm (not to scale)
W.V.(V.DC) Cap (μF) Frequency (Hz)
60 120 1 k 10 k 100 k
6.3 to 100
4.7 to 33 0.45 0.55 0.75 0.90 1.00
47 to 330 0.60 0.70 0.85 0.95 1.00
390 to 1000 0.65 0.75 0.90 0.98 1.00
1200 to 8200 0.75 0.80 0.95 1.00 1.00
■ Frequency correction factor for ripple current
Body Dia. 0D 5 6.3 8 10 12.5 16
Body Length L — — — — 12.5 to 25 30 to 35 —
Lead Dia. 0d 0.5 0.5 0.6 0.6 0.6 0.8 0.8
Lead space F 2.0 2.5 3.5 5.0 5.0 7.5
■ Features
● Low ESR (Same as FM Series)
● Endurance : 5000 h to 10000 h at +105 °C
● RoHS directive compliant
■ Attention
Not applicable for automotive
(Unit : mm)
06 Nov. 2014
Design and specifi cations are each subject to change without notice. Ask factory for the current technical specifi cations before purchase and/or use.
Should a safety concern arise regarding this product, please be sure to contact us immediately.
Aluminum Electrolytic Capacitors/ FR
– EEE-83 –
■ Case size/Impedance/Ripple current
W.V.(V.DC) 6.3 V to 35 V 50 V
Case size
(0D×L)
Imped ance
(Ω/100 kHz)
Ripple Current
(mA r.m.s./100 kHz)
Imped ance
(Ω/100 kHz)
Ripple Current
(mA r.m.s./100 kHz)
+20 °C –10 °C +105 °C +20 °C –10 °C +105 °C
5 × 11 0.300 1.000 280 0.340 1.130 250
6.3 × 11.2 0.130 0.430 455 0.140 0.460 405
8 × 11.5 0.056 0.168 950 0.061 0.183 870
8 × 15 0.041 0.123 1240 0.045 0.135 1140
8 × 20 0.030 0.090 1560 0.033 0.099 1430
10 × 12.5 0.043 0.114 1290 0.042 0.126 1170
10 × 16 0.028 0.078 1790 0.030 0.090 1650
10 × 20 0.020 0.057 2180 0.023 0.069 1890
10 × 25 0.018 0.054 2470 0.022 0.066 2150
12.5 × 20 0.018 0.045 2600 0.022 0.055 2260
12.5 × 25 0.015 0.038 3190 0.018 0.045 2660
12.5 × 30 0.013 0.033 3630 0.016 0.040 3160
12.5 × 35 0.012 0.030 3750 0.014 0.035 3270
16 × 20 0.017 0.043 3300 0.019 0.048 2870
16 × 25 0.014 0.035 3820 0.016 0.040 3320
W.V.(V.DC) 63 V
Case size
(0D×L)
Imped ance
(Ω/100 kHz)
Ripple Current
(mA r.m.s./100 kHz)
+20 °C –10 °C +105 °C
5 × 11 0.510 2.040 175
6.3 × 11.2 0.210 0.840 284
8 × 11.5 0.092 0.368 566
8 × 15 0.068 0.272 741
8 × 20 0.050 0.200 930
10 × 12.5 0.063 0.252 761
10 × 16 0.045 0.180 1073
10 × 20 0.035 0.140 1229
10 × 25 0.033 0.132 1500
12.5 × 20 0.033 0.125 1582
12.5 × 25 0.027 0.092 1995
12.5 × 30 0.024 0.082 2528
12.5 × 35 0.021 0.071 2780
16 × 20 0.029 0.093 2153
16 × 25 0.024 0.074 2988
W.V.(V.DC) 100 V
Case size
(0D×L)
Imped ance
(Ω/100 kHz)
Ripple Current
(mA r.m.s./100 kHz)
+20 °C –10 °C +105 °C
10 × 20 0.084 0.336 1500
06 Nov. 2014
Design and specifi cations are each subject to change without notice. Ask factory for the current technical specifi cations before purchase and/or use.
Should a safety concern arise regarding this product, please be sure to contact us immediately.
Aluminum Electrolytic Capacitors/ FR
– EEE-84 –
■ Standard Prod ucts
W.V. Cap.
(±20 %)
Case size Specifi cation Lead Length
Part No.
Min. Packaging Q'ty
Dia. Length
Ripple
Current
(100 kHz)
(+105 °C)
Impedance
(100 kHz)
(+20 °C)
Endurance
Lead
Dia.
Lead Space
Straight
Leads Taping Straight Taping
✽B
Taping
✽H
(V) (μF) (mm) (mm) (mA r.m.s.) (Ω) (hours) (mm) (mm) (mm) (mm) (pcs) (pcs)
6.3
150 5 11 280 0.300 5000 0.5 2.0 5.0 2.5 EEUFR0J151( ) 200 2000
220 6.3 11.2 455 0.130 5000 0.5 2.5 5.0 2.5 EEUFR0J221( ) 200 2000
330 6.3 11.2 455 0.130 5000 0.5 2.5 5.0 2.5 EEUFR0J331( ) 200 2000
470 6.3 11.2 455 0.130 5000 0.5 2.5 5.0 2.5 EEUFR0J471( ) 200 2000
820 8 11.5 950 0.056 6000 0.6 3.5 5.0 EEUFR0J821( ) 200 1000
1000 8 11.5 950 0.056 6000 0.6 3.5 5.0 EEUFR0J102( ) 200 1000
1200
8 15 1240 0.041 8000 0.6 3.5 5.0 EEUFR0J122L( ) 200 1000
10 12.5 1290 0.043 6000 0.6 5.0 5.0 EEUFR0J122( ) 200 500
1500 8 20 1560 0.030 9000 0.6 3.5 5.0 EEUFR0J152L( ) 200 1000
1800 10 16 1790 0.028 8000 0.6 5.0 5.0 EEUFR0J182( ) 200 500
2200 10 20 2180 0.020 10000 0.6 5.0 5.0 EEUFR0J222( ) 200 500
2700 10 25 2470 0.018 10000 0.6 5.0 5.0 EEUFR0J272L( ) 200 500
3300 10 25 2470 0.018 10000 0.6 5.0 5.0 EEUFR0J332L( ) 200 500
3900 12.5 20 2600 0.018 10000 0.6 5.0 5.0 EEUFR0J392( ) 200 500
4700 12.5 25 3190 0.015 10000 0.6 5.0 5.0 EEUFR0J472( ) 200 500
5600 12.5 30 3630 0.013 10000 0.8 5.0 EEUFR0J562L 100
6800
12.5 35 3750 0.012 10000 0.8 5.0 EEUFR0J682L 100
16 20 3300 0.017 10000 0.8 7.5 7.5 EEUFR0J682S( ) 100 250
8200 16 25 3820 0.014 10000 0.8 7.5 7.5 EEUFR0J822( ) 100 250
10
100 5 11 280 0.300 5000 0.5 2.0 5.0 2.5 EEUFR1A101( ) 200 2000
150 5 11 280 0.300 5000 0.5 2.0 5.0 2.5 EEUFR1A151( ) 200 2000
220 6.3 11.2 455 0.130 5000 0.5 2.5 5.0 2.5 EEUFR1A221( ) 200 2000
270 6.3 11.2 455 0.130 5000 0.5 2.5 5.0 2.5 EEUFR1A271( ) 200 2000
470 8 11.5 950 0.056 6000 0.6 3.5 5.0 EEUFR1A471( ) 200 1000
680 8 11.5 950 0.056 6000 0.6 3.5 5.0 EEUFR1A681( ) 200 1000
820 10 12.5 1290 0.043 6000 0.6 5.0 5.0 EEUFR1A821( ) 200 500
1000
10 16 1790 0.028 8000 0.6 5.0 5.0 EEUFR1A102( ) 200 500
8 15 1240 0.041 8000 0.6 3.5 5.0 EEUFR1A102L( ) 200 1000
1500
8 20 1560 0.030 9000 0.6 3.5 5.0 EEUFR1A152L( ) 200 1000
10 16 1790 0.028 8000 0.6 5.0 5.0 EEUFR1A152( ) 200 500
1800 10 20 2180 0.020 10000 0.6 5.0 5.0 EEUFR1A182( ) 200 500
2200 10 25 2470 0.018 10000 0.6 5.0 5.0 EEUFR1A222L( ) 200 500
3300 12.5 20 2600 0.018 10000 0.6 5.0 5.0 EEUFR1A332( ) 200 500
3900 12.5 25 3190 0.015 10000 0.6 5.0 5.0 EEUFR1A392( ) 200 500
4700
12.5 30 3630 0.013 10000 0.8 5.0 EEUFR1A472L 100
16 20 3300 0.017 10000 0.8 7.5 7.5 EEUFR1A472S( ) 100 250
5600 12.5 35 3750 0.012 10000 0.8 5.0 EEUFR1A562L 100
6800 12.5 35 3750 0.012 10000 0.8 5.0 EEUFR1A682L 100
16 25 3820 0.014 10000 0.8 7.5 7.5 EEUFR1A682( ) 100 250
· When requesting taped product, please put the letter "B" or "H" be tween the "( )". Lead wire pitch ✽B=5 mm, 7.5 mm, H=2.5 mm.
· Please refer to the page of “Taping Dimensions”.
06 Nov. 2014
Design and specifi cations are each subject to change without notice. Ask factory for the current technical specifi cations before purchase and/or use.
Should a safety concern arise regarding this product, please be sure to contact us immediately.
Aluminum Electrolytic Capacitors/ FR
– EEE-85 –
■ Standard Prod ucts
W.V. Cap.
(±20 %)
Case size Specifi cation Lead Length
Part No.
Min. Packaging Q'ty
Dia. Length
Ripple
Current
(100 kHz)
(+105 °C)
Impedance
(100 kHz)
(+20 °C)
Endurance
Lead
Dia.
Lead Space
Straight
Leads Taping Straight Taping
✽B
Taping
✽H
(V) (μF) (mm) (mm) (mA r.m.s.) (Ω) (hours) (mm) (mm) (mm) (mm) (pcs) (pcs)
16
68 5 11 280 0.300 5000 0.5 2.0 5.0 2.5 EEUFR1C680( ) 200 2000
100 5 11 280 0.300 5000 0.5 2.0 5.0 2.5 EEUFR1C101( ) 200 2000
120 6.3 11.2 455 0.130 5000 0.5 2.5 5.0 2.5 EEUFR1C121( ) 200 2000
220 6.3 11.2 455 0.130 5000 0.5 2.5 5.0 2.5 EEUFR1C221( ) 200 2000
470 8 11.5 950 0.056 6000 0.6 3.5 5.0 EEUFR1C471( ) 200 1000
680 8 15 1240 0.041 8000 0.6 3.5 5.0 EEUFR1C681L( ) 200 1000
10 12.5 1290 0.043 6000 0.6 5.0 5.0 EEUFR1C681( ) 200 500
1000 8 20 1560 0.030 9000 0.6 3.5 5.0 EEUFR1C102L( ) 200 1000
10 16 1790 0.028 8000 0.6 5.0 5.0 EEUFR1C102( ) 200 500
1500 10 20 2180 0.020 10000 0.6 5.0 5.0 EEUFR1C152( ) 200 500
10 25 2470 0.018 10000 0.6 5.0 5.0 EEUFR1C152L( ) 200 500
1800 10 25 2470 0.018 10000 0.6 5.0 5.0 EEUFR1C182L( ) 200 500
2200 12.5 20 2600 0.018 10000 0.6 5.0 5.0 EEUFR1C222( ) 200 500
2700 12.5 25 3190 0.015 10000 0.6 5.0 5.0 EEUFR1C272( ) 200 500
3300 12.5 30 3630 0.013 10000 0.8 5.0 EEUFR1C332L 100
16 20 3300 0.017 10000 0.8 7.5 7.5 EEUFR1C332S( ) 100 250
3900 12.5 35 3750 0.012 10000 0.8 5.0 EEUFR1C392L 100
16 20 3300 0.017 10000 0.8 7.5 7.5 EEUFR1C392S( ) 100 250
4700 12.5 35 3750 0.012 10000 0.8 5.0 EEUFR1C472L 100
16 25 3820 0.014 10000 0.8 7.5 7.5 EEUFR1C472( ) 100 250
5600 16 25 3820 0.014 10000 0.8 7.5 7.5 EEUFR1C562( ) 100 250
25
47 5 11 280 0.300 5000 0.5 2.0 5.0 2.5 EEUFR1E470( ) 200 2000
68 5 11 280 0.300 5000 0.5 2.0 5.0 2.5 EEUFR1E680( ) 200 2000
100 6.3 11.2 455 0.130 5000 0.5 2.5 5.0 2.5 EEUFR1E101( ) 200 2000
150 6.3 11.2 455 0.130 5000 0.5 2.5 5.0 2.5 EEUFR1E151( ) 200 2000
220 8 11.5 950 0.056 6000 0.6 3.5 5.0 EEUFR1E221( ) 200 1000
330 8 11.5 950 0.056 6000 0.6 3.5 5.0 EEUFR1E331( ) 200 1000
390 8 15 1240 0.041 8000 0.6 3.5 5.0 EEUFR1E391L( ) 200 1000
470
8 15 1240 0.041 8000 0.6 3.5 5.0 EEUFR1E471Y( ) 200 1000
8 20 1560 0.030 9000 0.6 3.5 5.0 EEUFR1E471L( ) 200 1000
10 12.5 1290 0.043 6000 0.6 5.0 5.0 EEUFR1E471( ) 200 500
560 8 20 1560 0.030 9000 0.6 3.5 5.0 EEUFR1E561L( ) 200 1000
680 8 20 1560 0.030 9000 0.6 3.5 5.0 EEUFR1E681L( ) 200 1000
10 16 1790 0.028 8000 0.6 5.0 5.0 EEUFR1E681( ) 200 500
820 10 20 2180 0.020 10000 0.6 5.0 5.0 EEUFR1E821( ) 200 500
1000 10 20 2180 0.020 10000 0.6 5.0 5.0 EEUFR1E102( ) 200 500
10 25 2470 0.018 10000 0.6 5.0 5.0 EEUFR1E102L( ) 200 500
1200 10 25 2470 0.018 10000 0.6 5.0 5.0 EEUFR1E122L( ) 200 500
1500 12.5 20 2600 0.018 10000 0.6 5.0 5.0 EEUFR1E152( ) 200 500
1800 12.5 25 3190 0.015 10000 0.6 5.0 5.0 EEUFR1E182( ) 200 500
16 20 3300 0.017 10000 0.8 7.5 7.5 EEUFR1E182S( ) 100 250
2200 12.5 30 3630 0.013 10000 0.8 5.0 EEUFR1E222L 100
16 20 3300 0.017 10000 0.8 7.5 7.5 EEUFR1E222S( ) 100 250
2700 12.5 35 3750 0.012 10000 0.8 5.0 EEUFR1E272L 100
16 20 3300 0.017 10000 0.8 7.5 7.5 EEUFR1E272S( ) 100 250
3300 16 25 3820 0.014 10000 0.8 7.5 7.5 EEUFR1E332( ) 100 250
· When requesting taped product, please put the letter "B" or "H" be tween the "( )". Lead wire pitch ✽B=5 mm, 7.5 mm, H=2.5 mm.
· Please refer to the page of “Taping Dimensions”.
06 Nov. 2014
Design and specifi cations are each subject to change without notice. Ask factory for the current technical specifi cations before purchase and/or use.
Should a safety concern arise regarding this product, please be sure to contact us immediately.
Aluminum Electrolytic Capacitors/ FR
– EEE-86 –
■ Standard Prod ucts
W.V. Cap.
(±20 %)
Case size Specifi cation Lead Length
Part No.
Min. Packaging Q'ty
Dia. Length
Ripple
Current
(100 kHz)
(+105 °C)
Impedance
(100 kHz)
(+20 °C)
Endurance
Lead
Dia.
Lead Space
Straight
Leads Taping Straight Taping
✽B
Taping
✽H
(V) (μF) (mm) (mm) (mA r.m.s.) (Ω) (hours) (mm) (mm) (mm) (mm) (pcs) (pcs)
35
33 5 11 280 0.300 5000 0.5 2.0 5.0 2.5 EEUFR1V330( ) 200 2000
68 6.3 11.2 455 0.130 5000 0.5 2.5 5.0 2.5 EEUFR1V680( ) 200 2000
100 8 11.5 950 0.056 6000 0.6 3.5 5.0 EEUFR1V101( ) 200 1000
180 8 11.5 950 0.056 6000 0.6 3.5 5.0 EEUFR1V181( ) 200 1000
220 8 11.5 950 0.056 6000 0.6 3.5 5.0 EEUFR1V221( ) 200 1000
270 8 15 1240 0.041 8000 0.6 3.5 5.0 EEUFR1V271L( ) 200 1000
10 12.5 1290 0.043 6000 0.6 5.0 5.0 EEUFR1V271( ) 200 500
330 10 12.5 1330 0.043 5000 0.6 5.0 5.0 EEUFR1V331U( ) 200 500
390 8 20 1560 0.030 9000 0.6 3.5 5.0 EEUFR1V391L( ) 200 1000
470 8 20 1560 0.030 9000 0.6 3.5 5.0 EEUFR1V471L( ) 200 1000
10 16 1790 0.028 8000 0.6 5.0 5.0 EEUFR1V471( ) 200 500
560 10 20 2180 0.020 10000 0.6 5.0 5.0 EEUFR1V561( ) 200 500
680 10 20 2180 0.020 10000 0.6 5.0 5.0 EEUFR1V681( ) 200 500
10 25 2470 0.018 10000 0.6 5.0 5.0 EEUFR1V681L( ) 200 500
820 10 25 2470 0.018 10000 0.6 5.0 5.0 EEUFR1V821L( ) 200 500
1000 12.5 20 2600 0.018 10000 0.6 5.0 5.0 EEUFR1V102( ) 200 500
1200 12.5 25 3190 0.015 10000 0.6 5.0 5.0 EEUFR1V122( ) 200 500
1500 12.5 30 3630 0.013 10000 0.8 5.0 EEUFR1V152L 100
16 20 3300 0.017 10000 0.8 7.5 7.5 EEUFR1V152S( ) 100 250
1800 12.5 35 3750 0.012 10000 0.8 5.0 EEUFR1V182L 100
16 25 3820 0.014 10000 0.8 7.5 7.5 EEUFR1V182( ) 100 250
2200 12.5 35 3750 0.012 10000 0.8 5.0 EEUFR1V222L 100
16 25 3820 0.014 10000 0.8 7.5 7.5 EEUFR1V222( ) 100 250
50
4.7 5 11 185 0.620 5000 0.5 2.0 5.0 2.5 EEUFR1H4R7( ) 200 2000
10 5 11 250 0.340 5000 0.5 2.0 5.0 2.5 EEUFR1H100( ) 200 2000
22 5 11 250 0.340 5000 0.5 2.0 5.0 2.5 EEUFR1H220( ) 200 2000
47 6.3 11.2 405 0.140 5000 0.5 2.5 5.0 EEUFR1H470( ) 200 2000
56 6.3 11.2 405 0.140 5000 0.5 2.5 5.0 2.5 EEUFR1H560( ) 200 2000
100 8 11.5 870 0.061 6000 0.6 3.5 5.0 EEUFR1H101( ) 200 1000
120 8 15 1140 0.045 8000 0.6 3.5 5.0 EEUFR1H121L( ) 200 1000
150 10 12.5 1170 0.042 6000 0.6 5.0 5.0 EEUFR1H151( ) 200 500
180 8 20 1430 0.033 9000 0.6 3.5 5.0 EEUFR1H181L( ) 200 1000
220 10 16 1650 0.030 8000 0.6 5.0 5.0 EEUFR1H221( ) 200 500
270 10 20 1890 0.023 10000 0.6 5.0 5.0 EEUFR1H271( ) 200 500
330 10 25 2150 0.022 10000 0.6 5.0 5.0 EEUFR1H331L( ) 200 500
470 12.5 20 2260 0.022 10000 0.6 5.0 5.0 EEUFR1H471( ) 200 500
560 12.5 25 2660 0.018 10000 0.6 5.0 5.0 EEUFR1H561( ) 200 500
680 12.5 30 3160 0.016 10000 0.8 5.0 EEUFR1H681L 100
820 12.5 35 3270 0.014 10000 0.8 5.0 EEUFR1H821L 100
16 20 2870 0.019 10000 0.8 7.5 7.5 EEUFR1H821S( ) 100 250
1000 16 25 3320 0.016 10000 0.8 7.5 7.5 EEUFR1H102( ) 100 250
63
18 5 11 175 0.510 5000 0.5 2.0 5.0 2.5 EEUFR1J180( ) 200 2000
47 6.3 11.2 284 0.210 5000 0.5 2.5 5.0 2.5 EEUFR1J470( ) 200 2000
82 8 11.5 566 0.092 6000 0.6 3.5 5.0 EEUFR1J820( ) 200 1000
100 8 15 741 0.068 8000 0.6 3.5 5.0 EEUFR1J101L( ) 200 1000
10 12.5 761 0.063 6000 0.6 5.0 5.0 EEUFR1J101( ) 200 500
120 8 20 930 0.050 9000 0.6 3.5 5.0 EEUFR1J121L( ) 200 1000
10 16 1073 0.045 8000 0.6 5.0 5.0 EEUFR1J121( ) 200 500
150 8 20 930 0.050 9000 0.6 3.5 5.0 EEUFR1J151L( ) 200 1000
10 16 1073 0.045 8000 0.6 5.0 5.0 EEUFR1J151( ) 200 500
180 10 20 1229 0.035 10000 0.6 5.0 5.0 EEUFR1J181( ) 200 500
220 10 25 1500 0.033 10000 0.6 5.0 5.0 EEUFR1J221L( ) 200 500
270
10 20 1229 0.035 10000 0.6 5.0 5.0 EEUFR1J271U( ) 200 500
10 25 1500 0.033 10000 0.6 5.0 5.0 EEUFR1J271L( ) 200 500
12.5 20 1582 0.033 10000 0.6 5.0 5.0 EEUFR1J271( ) 200 500
330 12.5 20 1582 0.033 10000 0.6 5.0 5.0 EEUFR1J331( ) 200 500
390 12.5 25 1995 0.027 10000 0.6 5.0 5.0 EEUFR1J391( ) 200 500
470 12.5 25 1995 0.027 10000 0.6 5.0 5.0 EEUFR1J471( ) 200 500
560 12.5 30 2528 0.024 10000 0.8 5.0 EEUFR1J561L 100
16 20 2153 0.029 10000 0.8 7.5 7.5 EEUFR1J561S( ) 100 250
680 12.5 35 2780 0.021 10000 0.8 5.0 EEUFR1J681L 100
820 16 25 2988 0.024 10000 0.8 7.5 7.5 EEUFR1J821( ) 100 250
100 100 10 20 1500 0.084 10000 0.6 5.0 5.0 EEUFR2A101( ) 200 500
· When requesting taped product, please put the letter "B" or "H" be tween the "( )". Lead wire pitch ✽B=5 mm, 7.5 mm, H=2.5 mm.
· Please refer to the page of “Taping Dimensions”.
06 Nov. 2014
Design and specifi cations are each subject to change without notice. Ask factory for the current technical specifi cations before purchase and/or use.
Should a safety concern arise regarding this product, please be sure to contact us immediately.
Aluminum Electrolytic Capacitors/ M
– EEE-111 –
010 Sleeve
L 14 min. 3 min. =
06.3
=L16
: L±1.0
L20 : L±2.0
Pressure relief +
–
08
0D+0.5
F±0.5
0D+0.5
fd±0.05
■ Features
● Endurance : 85 °C 2000 h
● Smaller than series SU
● RoHS directive compliant
Radial Lead Type
Series: M Type: A
■ Specifi cations
Category Temp. Range –40 °C to + 85 °C –25 °C to +85 °C
Rated W.V. Range 6.3 V.DC to 100 V.DC 160 V.DC to 450 V.DC
Nominal Cap. Range 2.2 μF to 22000 μF 1 μF to 470 μF
Capacitance Tolerance ±20 % (120 Hz/+20 °C)
DC Leakage Cur rent I < 0.01 CV or 3 (μA) After 2 minutes
(Whichever is greater) I < 0.06 CV +10 (μA) After 2 minutes
tan d Please see the attached standard products list
Endurance
After applying rated working voltage for 2000 hours at +85°C±2 °C, when the capacitors are
restored to 20 °C, capacitors shall meet the following limits.
Capacitance change ±20 % of initial measured value
tan d <150 % of initial specifi ed value
DC leakage current >
NXP Semiconductors LPC2468
Single-chip 16-bit/32-bit micro
20. Contents
1 General description . . . . . . . . . . . . . . . . . . . . . . 1
2 Features and benefits . . . . . . . . . . . . . . . . . . . . 1
3 Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
4 Ordering information. . . . . . . . . . . . . . . . . . . . . 3
4.1 Ordering options . . . . . . . . . . . . . . . . . . . . . . . . 3
5 Block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . 4
6 Pinning information. . . . . . . . . . . . . . . . . . . . . . 5
6.1 Pinning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
6.2 Pin description . . . . . . . . . . . . . . . . . . . . . . . . . 8
7 Functional description . . . . . . . . . . . . . . . . . . 24
7.1 Architectural overview . . . . . . . . . . . . . . . . . . 24
7.2 On-chip flash programming memory . . . . . . . 25
7.3 On-chip SRAM . . . . . . . . . . . . . . . . . . . . . . . . 25
7.4 Memory map. . . . . . . . . . . . . . . . . . . . . . . . . . 25
7.5 Interrupt controller . . . . . . . . . . . . . . . . . . . . . 27
7.5.1 Interrupt sources. . . . . . . . . . . . . . . . . . . . . . . 28
7.6 Pin connect block . . . . . . . . . . . . . . . . . . . . . . 28
7.7 External memory controller. . . . . . . . . . . . . . . 28
7.7.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
7.8 General purpose DMA controller . . . . . . . . . . 29
7.8.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
7.9 Fast general purpose parallel I/O . . . . . . . . . . 30
7.9.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
7.10 Ethernet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
7.10.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
7.11 USB interface . . . . . . . . . . . . . . . . . . . . . . . . . 32
7.11.1 USB device controller . . . . . . . . . . . . . . . . . . . 32
7.11.1.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
7.11.2 USB host controller. . . . . . . . . . . . . . . . . . . . . 32
7.11.2.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
7.11.3 USB OTG controller . . . . . . . . . . . . . . . . . . . . 33
7.11.3.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
7.12 CAN controller and acceptance filters . . . . . . 33
7.12.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
7.13 10-bit ADC . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
7.13.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
7.14 10-bit DAC . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
7.14.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
7.15 UARTs. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
7.15.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
7.16 SPI serial I/O controller. . . . . . . . . . . . . . . . . . 35
7.16.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
7.17 SSP serial I/O controller . . . . . . . . . . . . . . . . . 35
7.17.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
7.18 SD/MMC card interface . . . . . . . . . . . . . . . . . 35
7.18.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
7.19 I2C-bus serial I/O controller . . . . . . . . . . . . . . 36
7.19.1 Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
7.20 I2S-bus serial I/O controllers . . . . . . . . . . . . . 36
7.20.1 Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
7.21 General purpose 32-bit timers/external event
counters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
7.21.1 Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
7.22 Pulse width modulator . . . . . . . . . . . . . . . . . . 38
7.22.1 Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
7.23 Watchdog timer . . . . . . . . . . . . . . . . . . . . . . . 39
7.23.1 Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
7.24 RTC and battery RAM . . . . . . . . . . . . . . . . . . 39
7.24.1 Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
7.25 Clocking and power control . . . . . . . . . . . . . . 40
7.25.1 Crystal oscillators. . . . . . . . . . . . . . . . . . . . . . 40
7.25.1.1 Internal RC oscillator . . . . . . . . . . . . . . . . . . . 40
7.25.1.2 Main oscillator . . . . . . . . . . . . . . . . . . . . . . . . 40
7.25.1.3 RTC oscillator . . . . . . . . . . . . . . . . . . . . . . . . 41
7.25.2 PLL. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
7.25.3 Wake-up timer . . . . . . . . . . . . . . . . . . . . . . . . 41
7.25.4 Power control . . . . . . . . . . . . . . . . . . . . . . . . . 42
7.25.4.1 Idle mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
7.25.4.2 Sleep mode . . . . . . . . . . . . . . . . . . . . . . . . . . 42
7.25.4.3 Power-down mode . . . . . . . . . . . . . . . . . . . . . 42
7.25.4.4 Deep power-down mode . . . . . . . . . . . . . . . . 43
7.25.4.5 Power domains . . . . . . . . . . . . . . . . . . . . . . . 43
7.26 System control . . . . . . . . . . . . . . . . . . . . . . . . 44
7.26.1 Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
7.26.2 Brownout detection . . . . . . . . . . . . . . . . . . . . 44
7.26.3 Code security (Code Read Protection - CRP) 44
7.26.4 AHB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
7.26.5 External interrupt inputs . . . . . . . . . . . . . . . . . 45
7.26.6 Memory mapping control . . . . . . . . . . . . . . . . 45
7.27 Emulation and debugging . . . . . . . . . . . . . . . 45
7.27.1 EmbeddedICE . . . . . . . . . . . . . . . . . . . . . . . . 45
7.27.2 Embedded trace. . . . . . . . . . . . . . . . . . . . . . . 46
7.27.3 RealMonitor . . . . . . . . . . . . . . . . . . . . . . . . . . 46
8 Limiting values . . . . . . . . . . . . . . . . . . . . . . . . 47
9 Thermal characteristics . . . . . . . . . . . . . . . . . 48
10 Static characteristics . . . . . . . . . . . . . . . . . . . 49
10.1 Power-down mode . . . . . . . . . . . . . . . . . . . . . 52
10.2 Deep power-down mode . . . . . . . . . . . . . . . . 53
10.3 Electrical pin characteristics. . . . . . . . . . . . . . 55
11 Dynamic characteristics. . . . . . . . . . . . . . . . . 56
11.1 Internal oscillators . . . . . . . . . . . . . . . . . . . . . 57
11.2 I/O pins. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
11.3 USB interface. . . . . . . . . . . . . . . . . . . . . . . . . 57
11.4 Flash memory . . . . . . . . . . . . . . . . . . . . . . . . 58
NXP Semiconductors LPC2468
Single-chip 16-bit/32-bit micro
© NXP B.V. 2013. All rights reserved.
For more information, please visit: http://www.nxp.com
For sales office addresses, please send an email to: salesaddresses@nxp.com
Date of release: 11 January 2013
Document identifier: LPC2468
Please be aware that important notices concerning this document and the product(s)
described herein, have been included in section ‘Legal information’.
11.5 Static external memory interface . . . . . . . . . . 59
11.6 Dynamic external memory interface . . . . . . . . 61
11.7 Timing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
12 ADC electrical characteristics . . . . . . . . . . . . 65
13 DAC electrical characteristics . . . . . . . . . . . . 68
14 Application information. . . . . . . . . . . . . . . . . . 69
14.1 Suggested USB interface solutions . . . . . . . . 69
14.2 Crystal oscillator XTAL input and component
selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
14.3 RTC 32 kHz oscillator component selection. . 75
14.4 XTAL and RTCX Printed Circuit Board (PCB)
layout guidelines. . . . . . . . . . . . . . . . . . . . . . . 76
14.5 Standard I/O pin configuration . . . . . . . . . . . . 76
14.6 Reset pin configuration. . . . . . . . . . . . . . . . . . 77
15 Package outline . . . . . . . . . . . . . . . . . . . . . . . . 78
16 Abbreviations. . . . . . . . . . . . . . . . . . . . . . . . . . 80
17 Revision history. . . . . . . . . . . . . . . . . . . . . . . . 81
18 Legal information. . . . . . . . . . . . . . . . . . . . . . . 82
18.1 Data sheet status . . . . . . . . . . . . . . . . . . . . . . 82
18.2 Definitions. . . . . . . . . . . . . . . . . . . . . . . . . . . . 82
18.3 Disclaimers . . . . . . . . . . . . . . . . . . . . . . . . . . . 82
18.4 Trademarks. . . . . . . . . . . . . . . . . . . . . . . . . . . 83
19 Contact information. . . . . . . . . . . . . . . . . . . . . 83
20 Contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84
1. General description
The LPC2141/42/44/46/48 microcontrollers are based on a 16-bit/32-bit ARM7TDMI-S
CPU with real-time emulation and embedded trace support, that combine the
microcontroller with embedded high-speed flash memory ranging from 32 kB to 512 kB. A
128-bit wide memory interface and a unique accelerator architecture enable 32-bit code
execution at the maximum clock rate. For critical code size applications, the alternative
16-bit Thumb mode reduces code by more than 30 % with minimal performance penalty.
Due to their tiny size and low power consumption, LPC2141/42/44/46/48 are ideal for
applications where miniaturization is a key requirement, such as access control and
point-of-sale. Serial communications interfaces ranging from a USB 2.0 Full-speed
device, multiple UARTs, SPI, SSP to I2C-bus and on-chip SRAM of 8 kB up to 40 kB,
make these devices very well suited for communication gateways and protocol
converters, soft modems, voice recognition and low end imaging, providing both large
buffer size and high processing power. Various 32-bit timers, single or dual 10-bit ADC(s),
10-bit DAC, PWM channels and 45 fast GPIO lines with up to nine edge or level sensitive
external interrupt pins make these microcontrollers suitable for industrial control and
medical systems.
2. Features and benefits
2.1 Key features
16-bit/32-bit ARM7TDMI-S microcontroller in a tiny LQFP64 package.
8 kB to 40 kB of on-chip static RAM and 32 kB to 512 kB of on-chip flash memory.
128-bit wide interface/accelerator enables high-speed 60 MHz operation.
In-System Programming/In-Application Programming (ISP/IAP) via on-chip boot
loader software. Single flash sector or full chip erase in 400 ms and programming of
256 B in 1 ms.
EmbeddedICE RT and Embedded Trace interfaces offer real-time debugging with the
on-chip RealMonitor software and high-speed tracing of instruction execution.
USB 2.0 Full-speed compliant device controller with 2 kB of endpoint RAM.
In addition, the LPC2146/48 provides 8 kB of on-chip RAM accessible to USB by DMA.
One or two (LPC2141/42 vs. LPC2144/46/48) 10-bit ADCs provide a total of 6/14
analog inputs, with conversion times as low as 2.44 s per channel.
Single 10-bit DAC provides variable analog output (LPC2142/44/46/48 only).
Two 32-bit timers/external event counters (with four capture and four compare
channels each), PWM unit (six outputs) and watchdog.
Low power Real-Time Clock (RTC) with independent power and 32 kHz clock input.
LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers; up to 512 kB flash
with ISP/IAP, USB 2.0 full-speed device, 10-bit ADC and DAC
Rev. 5 — 12 August 2011 Product data sheet
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 2 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
Multiple serial interfaces including two UARTs (16C550), two Fast I2C-bus (400 kbit/s),
SPI and SSP with buffering and variable data length capabilities.
Vectored Interrupt Controller (VIC) with configurable priorities and vector addresses.
Up to 45 of 5 V tolerant fast general purpose I/O pins in a tiny LQFP64 package.
Up to 21 external interrupt pins available.
60 MHz maximum CPU clock available from programmable on-chip PLL with settling
time of 100 s.
On-chip integrated oscillator operates with an external crystal from 1 MHz to 25 MHz.
Power saving modes include Idle and Power-down.
Individual enable/disable of peripheral functions as well as peripheral clock scaling for
additional power optimization.
Processor wake-up from Power-down mode via external interrupt or BOD.
Single power supply chip with POR and BOD circuits:
CPU operating voltage range of 3.0 V to 3.6 V (3.3 V 10 %) with 5 V tolerant I/O
pads.
3. Ordering information
3.1 Ordering options
[1] While the USB DMA is the primary user of the additional 8 kB RAM, this RAM is also accessible at any time by the CPU as a general
purpose RAM for data and code storage.
Table 1. Ordering information
Type number Package
Name Description Version
LPC2141FBD64 LQFP64 plastic low profile quad flat package; 64 leads;
body 10 10 1.4 mm
SOT314-2
LPC2142FBD64
LPC2144FBD64
LPC2146FBD64
LPC2148FBD64
Table 2. Ordering options
Type number Flash
memory
RAM Endpoint
USB RAM
ADC (channels
overall)
DAC Temperature
range
LPC2141FBD64 32 kB 8 kB 2 kB 1 (6 channels) - 40 C to +85 C
LPC2142FBD64 64 kB 16 kB 2 kB 1 (6 channels) 1 40 C to +85 C
LPC2144FBD64 128 kB 16 kB 2 kB 2 (14 channels) 1 40 C to +85 C
LPC2146FBD64 256 kB 32 kB + 8 kB shared with
USB DMA[1]
2 kB 2 (14 channels) 1 40 C to +85 C
LPC2148FBD64 512 kB 32 kB + 8 kB shared with
USB DMA[1]
2 kB 2 (14 channels) 1 40 C to +85 C
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 3 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
4. Block diagram
(1) Pins shared with GPIO.
(2) LPC2144/46/48 only.
(3) USB DMA controller with 8 kB of RAM accessible as general purpose RAM and/or DMA is available in LPC2146/48 only.
(4) LPC2142/44/46/48 only.
Fig 1. Block diagram
002aab560
system
clock
TRST(1)
TMS(1)
TCK(1)
TDI(1)
TDO(1)
XTAL2
XTAL1
AMBA AHB
(Advanced High-performance Bus)
INTERNAL
FLASH
CONTROLLER
AHB BRIDGE
EMULATION TRACE
MODULE
TEST/DEBUG
INTERFACE
AHB
AHB TO APB DECODER
BRIDGE
APB
DIVIDER
VECTORED
INTERRUPT
CONTROLLER
SYSTEM
FUNCTIONS
PLL0
USB
clock
PLL1
SYSTEM
CONTROL
32 kB/64 kB/128 kB/
256 kB/512 kB
FLASH
ARM7TDMI-S
LPC2141/42/44/46/48
INTERNAL
SRAM
CONTROLLER
8 kB/16 kB/
32 kB
SRAM
ARM7 local bus
SCL0, SCL1
SDA0, SDA1
4 × CAP0
4 × CAP1
8 × MAT0
8 × MAT1
I
2C-BUS SERIAL
INTERFACES 0 AND 1
CAPTURE/COMPARE
(W/EXTERNAL CLOCK)
TIMER 0/TIMER 1
EINT3 to EINT0 EXTERNAL
INTERRUPTS
D+
D−
UP_LED
CONNECT
VBUS
USB 2.0 FULL-SPEED
DEVICE CONTROLLER
WITH DMA(3)
SCK0, SCK1
MOSI0, MOSI1
MISO0, MISO1
AD0[7:6] and
AD0[4:1]
AD1[7:0](2)
SSEL0, SSEL1
SPI AND SSP
SERIAL INTERFACES
A/D CONVERTERS
0 AND 1(2)
TXD0, TXD1
RXD0, RXD1
DSR1(2),CTS1(2),
RTS1(2), DTR1(2)
DCD1(2),RI1(2)
AOUT(4) D/A CONVERTER UART0/UART1
P0[31:28] and
P0[25:0]
P1[31:16]
RTXC2
RTXC1
VBAT
REAL-TIME CLOCK GENERAL
PURPOSE I/O
PWM6 to PWM0 WATCHDOG
TIMER PWM0
P0[31:28] and
P0[25:0]
P1[31:16]
FAST GENERAL
PURPOSE I/O
8 kB RAM
SHARED WITH
USB DMA(3)
RST
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 4 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
5. Pinning information
5.1 Pinning
Fig 2. LPC2141 pinning
LPC2141
P0.21/PWM5/CAP1.3 P1.20/TRACESYNC
P0.22/CAP0.0/MAT0.0 P0.17/CAP1.2/SCK1/MAT1.2
RTCX1 P0.16/EINT0/MAT0.2/CAP0.2
P1.19/TRACEPKT3 P0.15/EINT2
RTCX2 P1.21/PIPESTAT0
VSS VDD
VDDA VSS
P1.18/TRACEPKT2 P0.14/EINT1/SDA1
P0.25/AD0.4 P1.22/PIPESTAT1
D+ P0.13/MAT1.1
D− P0.12/MAT1.0
P1.17/TRACEPKT1 P0.11/CAP1.1/SCL1
P0.28/AD0.1/CAP0.2/MAT0.2 P1.23/PIPESTAT2
P0.29/AD0.2/CAP0.3/MAT0.3 P0.10/CAP1.0
P0.30/AD0.3/EINT3/CAP0.0 P0.9/RXD1/PWM6/EINT3
P1.16/TRACEPKT0 P0.8/TXD1/PWM4 P0.31/UP_LED/CONNECT P1.27/TDO
VSS VREF
P0.0/TXD0/PWM1 XTAL1
P1.31/TRST XTAL2
P0.1/RXD0/PWM3/EINT0 P1.28/TDI
P0.2/SCL0/CAP0.0
VSSA
VDD P0.23/VBUS
P1.26/RTCK RESET
VSS P1.29/TCK
P0.3/SDA0/MAT0.0/EINT1 P0.20/MAT1.3/SSEL1/EINT3
P0.4/SCK0/CAP0.1/AD0.6 P0.19/MAT1.2/MOSI1/CAP1.2
P1.25/EXTIN0 P0.18/CAP1.3/MISO1/MAT1.3
P0.5/MISO0/MAT0.1/AD0.7 P1.30/TMS
P0.6/MOSI0/CAP0.2
VDD
P0.7/SSEL0/PWM2/EINT2
VSS
P1.24/TRACECLK VBAT
002aab733
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 5 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
Fig 3. LPC2142 pinning
LPC2142
P0.21/PWM5/CAP1.3 P1.20/TRACESYNC
P0.22/CAP0.0/MAT0.0 P0.17/CAP1.2/SCK1/MAT1.2
RTCX1 P0.16/EINT0/MAT0.2/CAP0.2
P1.19/TRACEPKT3 P0.15/EINT2
RTCX2 P1.21/PIPESTAT0
VSS VDD
VDDA VSS
P1.18/TRACEPKT2 P0.14/EINT1/SDA1
P0.25/AD0.4/AOUT P1.22/PIPESTAT1
D+ P0.13/MAT1.1
D− P0.12/MAT1.0
P1.17/TRACEPKT1 P0.11/CAP1.1/SCL1
P0.28/AD0.1/CAP0.2/MAT0.2 P1.23/PIPESTAT2
P0.29/AD0.2/CAP0.3/MAT0.3 P0.10/CAP1.0
P0.30/AD0.3/EINT3/CAP0.0 P0.9/RXD1/PWM6/EINT3
P1.16/TRACEPKT0 P0.8/TXD1/PWM4 P0.31/UP_LED/CONNECT P1.27/TDO
VSS VREF
P0.0/TXD0/PWM1 XTAL1
P1.31/TRST XTAL2
P0.1/RXD0/PWM3/EINT0 P1.28/TDI
P0.2/SCL0/CAP0.0
VSSA
VDD P0.23/VBUS
P1.26/RTCK RESET
VSS P1.29/TCK
P0.3/SDA0/MAT0.0/EINT1 P0.20/MAT1.3/SSEL1/EINT3
P0.4/SCK0/CAP0.1/AD0.6 P0.19/MAT1.2/MOSI1/CAP1.2
P1.25/EXTIN0 P0.18/CAP1.3/MISO1/MAT1.3
P0.5/MISO0/MAT0.1/AD0.7 P1.30/TMS
P0.6/MOSI0/CAP0.2
VDD
P0.7/SSEL0/PWM2/EINT2
VSS
P1.24/TRACECLK VBAT
002aab734
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 6 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
Fig 4. LPC2144/46/48 pinning
LPC2144/2146/2148
P0.21/PWM5/AD1.6/CAP1.3 P1.20/TRACESYNC
P0.22/AD1.7/CAP0.0/MAT0.0 P0.17/CAP1.2/SCK1/MAT1.2
RTCX1 P0.16/EINT0/MAT0.2/CAP0.2
P1.19/TRACEPKT3 P0.15/RI1/EINT2/AD1.5
RTCX2 P1.21/PIPESTAT0
VSS VDD
VDDA VSS
P1.18/TRACEPKT2 P0.14/DCD1/EINT1/SDA1
P0.25/AD0.4/AOUT P1.22/PIPESTAT1
D+ P0.13/DTR1/MAT1.1/AD1.4
D− P0.12/DSR1/MAT1.0/AD1.3
P1.17/TRACEPKT1 P0.11/CTS1/CAP1.1/SCL1
P0.28/AD0.1/CAP0.2/MAT0.2 P1.23/PIPESTAT2
P0.29/AD0.2/CAP0.3/MAT0.3 P0.10/RTS1/CAP1.0/AD1.2
P0.30/AD0.3/EINT3/CAP0.0 P0.9/RXD1/PWM6/EINT3
P1.16/TRACEPKT0 P0.8/TXD1/PWM4/AD1.1 P0.31/UP_LED/CONNECT P1.27/TDO
VSS VREF
P0.0/TXD0/PWM1 XTAL1
P1.31/TRST XTAL2
P0.1/RXD0/PWM3/EINT0 P1.28/TDI
P0.2/SCL0/CAP0.0
VSSA
VDD P0.23/VBUS
P1.26/RTCK RESET
VSS P1.29/TCK
P0.3/SDA0/MAT0.0/EINT1 P0.20/MAT1.3/SSEL1/EINT3
P0.4/SCK0/CAP0.1/AD0.6 P0.19/MAT1.2/MOSI1/CAP1.2
P1.25/EXTIN0 P0.18/CAP1.3/MISO1/MAT1.3
P0.5/MISO0/MAT0.1/AD0.7 P1.30/TMS
P0.6/MOSI0/CAP0.2/AD1.0
VDD
P0.7/SSEL0/PWM2/EINT2
VSS
P1.24/TRACECLK VBAT
002aab735
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 7 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
5.2 Pin description
Table 3. Pin description
Symbol Pin Type Description
P0.0 to P0.31 I/O Port 0: Port 0 is a 32-bit I/O port with individual direction controls for
each bit. Total of 31 pins of the Port 0 can be used as a general
purpose bidirectional digital I/Os while P0.31 is output only pin. The
operation of port 0 pins depends upon the pin function selected via the
pin connect block.
Pins P0.24, P0.26 and P0.27 are not available.
P0.0/TXD0/
PWM1
19[1] I/O P0.0 — General purpose input/output digital pin (GPIO).
O TXD0 — Transmitter output for UART0.
O PWM1 — Pulse Width Modulator output 1.
P0.1/RXD0/
PWM3/EINT0
21[2] I/O P0.1 — General purpose input/output digital pin (GPIO).
I RXD0 — Receiver input for UART0.
O PWM3 — Pulse Width Modulator output 3.
I EINT0 — External interrupt 0 input.
P0.2/SCL0/
CAP0.0
22[3] I/O P0.2 — General purpose input/output digital pin (GPIO).
I/O SCL0 — I
2C0 clock input/output. Open-drain output (for I2C-bus
compliance).
I CAP0.0 — Capture input for Timer 0, channel 0.
P0.3/SDA0/
MAT0.0/EINT1
26[3] I/O P0.3 — General purpose input/output digital pin (GPIO).
I/O SDA0 — I
2C0 data input/output. Open-drain output (for I2C-bus
compliance).
O MAT0.0 — Match output for Timer 0, channel 0.
I EINT1 — External interrupt 1 input.
P0.4/SCK0/
CAP0.1/AD0.6
27[4] I/O P0.4 — General purpose input/output digital pin (GPIO).
I/O SCK0 — Serial clock for SPI0. SPI clock output from master or input
to slave.
I CAP0.1 — Capture input for Timer 0, channel 1.
I AD0.6 — ADC 0, input 6.
P0.5/MISO0/
MAT0.1/AD0.7
29[4] I/O P0.5 — General purpose input/output digital pin (GPIO).
I/O MISO0 — Master In Slave Out for SPI0. Data input to SPI master or
data output from SPI slave.
O MAT0.1 — Match output for Timer 0, channel 1.
I AD0.7 — ADC 0, input 7.
P0.6/MOSI0/
CAP0.2/AD1.0
30[4] I/O P0.6 — General purpose input/output digital pin (GPIO).
I/O MOSI0 — Master Out Slave In for SPI0. Data output from SPI master
or data input to SPI slave.
I CAP0.2 — Capture input for Timer 0, channel 2.
I AD1.0 — ADC 1, input 0. Available in LPC2144/46/48 only.
P0.7/SSEL0/
PWM2/EINT2
31[2] I/O P0.7 — General purpose input/output digital pin (GPIO).
I SSEL0 — Slave Select for SPI0. Selects the SPI interface as a slave.
O PWM2 — Pulse Width Modulator output 2.
I EINT2 — External interrupt 2 input.
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 8 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
P0.8/TXD1/
PWM4/AD1.1
33[4] I/O P0.8 — General purpose input/output digital pin (GPIO).
O TXD1 — Transmitter output for UART1.
O PWM4 — Pulse Width Modulator output 4.
I AD1.1 — ADC 1, input 1. Available in LPC2144/46/48 only.
P0.9/RXD1/
PWM6/EINT3
34[2] I/O P0.9 — General purpose input/output digital pin (GPIO).
I RXD1 — Receiver input for UART1.
O PWM6 — Pulse Width Modulator output 6.
I EINT3 — External interrupt 3 input.
P0.10/RTS1/
CAP1.0/AD1.2
35[4] I/O P0.10 — General purpose input/output digital pin (GPIO).
O RTS1 — Request to Send output for UART1. LPC2144/46/48 only.
I CAP1.0 — Capture input for Timer 1, channel 0.
I AD1.2 — ADC 1, input 2. Available in LPC2144/46/48 only.
P0.11/CTS1/
CAP1.1/SCL1
37[3] I/O P0.11 — General purpose input/output digital pin (GPIO).
I CTS1 — Clear to Send input for UART1. Available in LPC2144/46/48
only.
I CAP1.1 — Capture input for Timer 1, channel 1.
I/O SCL1 — I
2C1 clock input/output. Open-drain output (for I2C-bus
compliance)
P0.12/DSR1/
MAT1.0/AD1.3
38[4] I/O P0.12 — General purpose input/output digital pin (GPIO).
I DSR1 — Data Set Ready input for UART1. Available in
LPC2144/46/48 only.
O MAT1.0 — Match output for Timer 1, channel 0.
I AD1.3 — ADC 1 input 3. Available in LPC2144/46/48 only.
P0.13/DTR1/
MAT1.1/AD1.4
39[4] I/O P0.13 — General purpose input/output digital pin (GPIO).
O DTR1 — Data Terminal Ready output for UART1. LPC2144/46/48
only.
O MAT1.1 — Match output for Timer 1, channel 1.
I AD1.4 — ADC 1 input 4. Available in LPC2144/46/48 only.
P0.14/DCD1/
EINT1/SDA1
41[3] I/O P0.14 — General purpose input/output digital pin (GPIO).
I DCD1 — Data Carrier Detect input for UART1. LPC2144/46/48 only.
I EINT1 — External interrupt 1 input.
I/O SDA1 — I
2C1 data input/output. Open-drain output (for I2C-bus
compliance).
Note: LOW on this pin while RESET is LOW forces on-chip boot
loader to take over control of the part after reset.
P0.15/RI1/
EINT2/AD1.5
45[4] I/O P0.15 — General purpose input/output digital pin (GPIO).
I RI1 — Ring Indicator input for UART1. Available in LPC2144/46/48
only.
I EINT2 — External interrupt 2 input.
I AD1.5 — ADC 1, input 5. Available in LPC2144/46/48 only.
Table 3. Pin description …continued
Symbol Pin Type Description
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 9 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
P0.16/EINT0/
MAT0.2/CAP0.2
46[2] I/O P0.16 — General purpose input/output digital pin (GPIO).
I EINT0 — External interrupt 0 input.
O MAT0.2 — Match output for Timer 0, channel 2.
I CAP0.2 — Capture input for Timer 0, channel 2.
P0.17/CAP1.2/
SCK1/MAT1.2
47[1] I/O P0.17 — General purpose input/output digital pin (GPIO).
I CAP1.2 — Capture input for Timer 1, channel 2.
I/O SCK1 — Serial Clock for SSP. Clock output from master or input to
slave.
O MAT1.2 — Match output for Timer 1, channel 2.
P0.18/CAP1.3/
MISO1/MAT1.3
53[1] I/O P0.18 — General purpose input/output digital pin (GPIO).
I CAP1.3 — Capture input for Timer 1, channel 3.
I/O MISO1 — Master In Slave Out for SSP. Data input to SPI master or
data output from SSP slave.
O MAT1.3 — Match output for Timer 1, channel 3.
P0.19/MAT1.2/
MOSI1/CAP1.2
54[1] I/O P0.19 — General purpose input/output digital pin (GPIO).
O MAT1.2 — Match output for Timer 1, channel 2.
I/O MOSI1 — Master Out Slave In for SSP. Data output from SSP master
or data input to SSP slave.
I CAP1.2 — Capture input for Timer 1, channel 2.
P0.20/MAT1.3/
SSEL1/EINT3
55[2] I/O P0.20 — General purpose input/output digital pin (GPIO).
O MAT1.3 — Match output for Timer 1, channel 3.
I SSEL1 — Slave Select for SSP. Selects the SSP interface as a slave.
I EINT3 — External interrupt 3 input.
P0.21/PWM5/
AD1.6/CAP1.3
1[4] I/O P0.21 — General purpose input/output digital pin (GPIO).
O PWM5 — Pulse Width Modulator output 5.
I AD1.6 — ADC 1, input 6. Available in LPC2144/46/48 only.
I CAP1.3 — Capture input for Timer 1, channel 3.
P0.22/AD1.7/
CAP0.0/MAT0.0
2[4] I/O P0.22 — General purpose input/output digital pin (GPIO).
I AD1.7 — ADC 1, input 7. Available in LPC2144/46/48 only.
I CAP0.0 — Capture input for Timer 0, channel 0.
O MAT0.0 — Match output for Timer 0, channel 0.
P0.23/VBUS 58[1] I/O P0.23 — General purpose input/output digital pin (GPIO).
I VBUS — Indicates the presence of USB bus power.
Note: This signal must be HIGH for USB reset to occur.
P0.25/AD0.4/
AOUT
9[5] I/O P0.25 — General purpose input/output digital pin (GPIO).
I AD0.4 — ADC 0, input 4.
O AOUT — DAC output. Available in LPC2142/44/46/48 only.
P0.28/AD0.1/
CAP0.2/MAT0.2
13[4] I/O P0.28 — General purpose input/output digital pin (GPIO).
I AD0.1 — ADC 0, input 1.
I CAP0.2 — Capture input for Timer 0, channel 2.
O MAT0.2 — Match output for Timer 0, channel 2.
Table 3. Pin description …continued
Symbol Pin Type Description
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 10 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
P0.29/AD0.2/
CAP0.3/MAT0.3
14[4] I/O P0.29 — General purpose input/output digital pin (GPIO).
I AD0.2 — ADC 0, input 2.
I CAP0.3 — Capture input for Timer 0, channel 3.
O MAT0.3 — Match output for Timer 0, channel 3.
P0.30/AD0.3/
EINT3/CAP0.0
15[4] I/O P0.30 — General purpose input/output digital pin (GPIO).
I AD0.3 — ADC 0, input 3.
I EINT3 — External interrupt 3 input.
I CAP0.0 — Capture input for Timer 0, channel 0.
P0.31/UP_LED/
CONNECT
17[6] O P0.31 — General purpose output only digital pin (GPO).
O UP_LED — USB GoodLink LED indicator. It is LOW when device is
configured (non-control endpoints enabled). It is HIGH when the
device is not configured or during global suspend.
O CONNECT — Signal used to switch an external 1.5 k resistor under
the software control. Used with the SoftConnect USB feature.
Important: This is an digital output only pin. This pin MUST NOT be
externally pulled LOW when RESET pin is LOW or the JTAG port will
be disabled.
P1.0 to P1.31 I/O Port 1: Port 1 is a 32-bit bidirectional I/O port with individual direction
controls for each bit. The operation of port 1 pins depends upon the
pin function selected via the pin connect block. Pins 0 through 15 of
port 1 are not available.
P1.16/
TRACEPKT0
16[6] I/O P1.16 — General purpose input/output digital pin (GPIO). Standard
I/O port with internal pull-up.
O TRACEPKT0 — Trace Packet, bit 0.
P1.17/
TRACEPKT1
12[6] I/O P1.17 — General purpose input/output digital pin (GPIO). Standard
I/O port with internal pull-up.
O TRACEPKT1 — Trace Packet, bit 1.
P1.18/
TRACEPKT2
8[6] I/O P1.18 — General purpose input/output digital pin (GPIO). Standard
I/O port with internal pull-up.
O TRACEPKT2 — Trace Packet, bit 2.
P1.19/
TRACEPKT3
4[6] I/O P1.19 — General purpose input/output digital pin (GPIO). Standard
I/O port with internal pull-up.
O TRACEPKT3 — Trace Packet, bit 3.
P1.20/
TRACESYNC
48[6] I/O P1.20 — General purpose input/output digital pin (GPIO). Standard
I/O port with internal pull-up.
O TRACESYNC — Trace Synchronization.
Note: LOW on this pin while RESET is LOW enables pins P1.25:16 to
operate as Trace port after reset.
P1.21/
PIPESTAT0
44[6] I/O P1.21 — General purpose input/output digital pin (GPIO). Standard
I/O port with internal pull-up.
O PIPESTAT0 — Pipeline Status, bit 0.
P1.22/
PIPESTAT1
40[6] I/O P1.22 — General purpose input/output digital pin (GPIO). Standard
I/O port with internal pull-up.
O PIPESTAT1 — Pipeline Status, bit 1.
Table 3. Pin description …continued
Symbol Pin Type Description
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 11 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
P1.23/
PIPESTAT2
36[6] I/O P1.23 — General purpose input/output digital pin (GPIO). Standard
I/O port with internal pull-up.
O PIPESTAT2 — Pipeline Status, bit 2.
P1.24/
TRACECLK
32[6] I/O P1.24 — General purpose input/output digital pin (GPIO). Standard
I/O port with internal pull-up.
O TRACECLK — Trace Clock.
P1.25/EXTIN0 28[6] I/O P1.25 — General purpose input/output digital pin (GPIO). Standard
I/O port with internal pull-up.
I EXTIN0 — External Trigger Input.
P1.26/RTCK 24[6] I/O P1.26 — General purpose input/output digital pin (GPIO).
I/O RTCK — Returned Test Clock output. Extra signal added to the JTAG
port. Assists debugger synchronization when processor frequency
varies. Bidirectional pin with internal pull-up.
Note: LOW on RTCK while RESET is LOW enables pins P1[31:26] to
operate as Debug port after reset.
P1.27/TDO 64[6] I/O P1.27 — General purpose input/output digital pin (GPIO).
O TDO — Test Data out for JTAG interface.
P1.28/TDI 60[6] I/O P1.28 — General purpose input/output digital pin (GPIO).
I TDI — Test Data in for JTAG interface.
P1.29/TCK 56[6] I/O P1.29 — General purpose input/output digital pin (GPIO).
I TCK — Test Clock for JTAG interface. This clock must be slower than
16 of the CPU clock (CCLK) for the JTAG interface to operate.
P1.30/TMS 52[6] I/O P1.30 — General purpose input/output digital pin (GPIO).
I TMS — Test Mode Select for JTAG interface.
P1.31/TRST 20[6] I/O P1.31 — General purpose input/output digital pin (GPIO).
I TRST — Test Reset for JTAG interface.
D+ 10[7] I/O USB bidirectional D+ line.
D 11[7] I/O USB bidirectional D line.
RESET 57[8] I External reset input: A LOW on this pin resets the device, causing
I/O ports and peripherals to take on their default states, and processor
execution to begin at address 0. TTL with hysteresis, 5 V tolerant.
XTAL1 62[9] I Input to the oscillator circuit and internal clock generator circuits.
XTAL2 61[9] O Output from the oscillator amplifier.
RTCX1 3[9][10] I Input to the RTC oscillator circuit.
RTCX2 5[9][10] O Output from the RTC oscillator circuit.
VSS 6, 18, 25, 42,
50
I Ground: 0 V reference.
VSSA 59 I Analog ground: 0 V reference. This should nominally be the same
voltage as VSS, but should be isolated to minimize noise and error.
VDD 23, 43, 51 I 3.3 V power supply: This is the power supply voltage for the core and
I/O ports.
Table 3. Pin description …continued
Symbol Pin Type Description
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 12 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
[1] 5 V tolerant pad (no built-in pull-up resistor) providing digital I/O functions with TTL levels and hysteresis and 10 ns slew rate control.
[2] 5 V tolerant pad (no built-in pull-up resistor) providing digital I/O functions with TTL levels and hysteresis and 10 ns slew rate control. If
configured for an input function, this pad utilizes built-in glitch filter that blocks pulses shorter than 3 ns.
[3] Open-drain 5 V tolerant digital I/O I2C-bus 400 kHz specification compatible pad. It requires external pull-up to provide an output
functionality.
[4] 5 V tolerant pad (no built-in pull-up resistor) providing digital I/O (with TTL levels and hysteresis and 10 ns slew rate control) and analog
input function. If configured for an input function, this pad utilizes built-in glitch filter that blocks pulses shorter than 3 ns. When
configured as an ADC input, digital section of the pad is disabled.
[5] 5 V tolerant pad (no built-in pull-up resistor) providing digital I/O (with TTL levels and hysteresis and 10 ns slew rate control) and analog
output function. When configured as the DAC output, digital section of the pad is disabled.
[6] 5 V tolerant pad with built-in pull-up resistor providing digital I/O functions with TTL levels and hysteresis and 10 ns slew rate control.
The pull-up resistor’s value typically ranges from 60 k to 300 k.
[7] Pad is designed in accordance with the Universal Serial Bus (USB) specification, revision 2.0 (Full-speed and Low-speed mode only).
[8] 5 V tolerant pad providing digital input (with TTL levels and hysteresis) function only.
[9] Pad provides special analog functionality.
[10] When unused, the RTCX1 pin can be grounded or left floating. For lowest power leave it floating.
The other RTC pin, RTCX2, should be left floating.
VDDA 7 I Analog 3.3 V power supply: This should be nominally the same
voltage as VDD but should be isolated to minimize noise and error.
This voltage is only used to power the on-chip ADC(s) and DAC.
VREF 63 I ADC reference voltage: This should be nominally less than or equal
to the VDD voltage but should be isolated to minimize noise and error.
Level on this pin is used as a reference for ADC(s) and DAC.
VBAT 49 I RTC power supply voltage: 3.3 V on this pin supplies the power to
the RTC.
Table 3. Pin description …continued
Symbol Pin Type Description
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 13 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
6. Functional description
6.1 Architectural overview
The ARM7TDMI-S is a general purpose 32-bit microprocessor, which offers high
performance and very low power consumption. The ARM architecture is based on
Reduced Instruction Set Computer (RISC) principles, and the instruction set and related
decode mechanism are much simpler than those of microprogrammed Complex
Instruction Set Computers (CISC). This simplicity results in a high instruction throughput
and impressive real-time interrupt response from a small and cost-effective processor
core.
Pipeline techniques are employed so that all parts of the processing and memory systems
can operate continuously. Typically, while one instruction is being executed, its successor
is being decoded, and a third instruction is being fetched from memory.
The ARM7TDMI-S processor also employs a unique architectural strategy known as
Thumb, which makes it ideally suited to high-volume applications with memory
restrictions, or applications where code density is an issue.
The key idea behind Thumb is that of a super-reduced instruction set. Essentially, the
ARM7TDMI-S processor has two instruction sets:
• The standard 32-bit ARM set.
• A 16-bit Thumb set.
The Thumb set’s 16-bit instruction length allows it to approach twice the density of
standard ARM code while retaining most of the ARM’s performance advantage over a
traditional 16-bit processor using 16-bit registers. This is possible because Thumb code
operates on the same 32-bit register set as ARM code.
Thumb code is able to provide up to 65 % of the code size of ARM, and 160 % of the
performance of an equivalent ARM processor connected to a 16-bit memory system.
The particular flash implementation in the LPC2141/42/44/46/48 allows for full speed
execution also in ARM mode. It is recommended to program performance critical and
short code sections (such as interrupt service routines and DSP algorithms) in ARM
mode. The impact on the overall code size will be minimal but the speed can be increased
by 30 % over Thumb mode.
6.2 On-chip flash program memory
The LPC2141/42/44/46/48 incorporate a 32 kB, 64 kB, 128 kB, 256 kB and 512 kB flash
memory system respectively. This memory may be used for both code and data storage.
Programming of the flash memory may be accomplished in several ways. It may be
programmed In System via the serial port. The application program may also erase and/or
program the flash while the application is running, allowing a great degree of flexibility for
data storage field firmware upgrades, etc. Due to the architectural solution chosen for an
on-chip boot loader, flash memory available for user’s code on LPC2141/42/44/46/48 is
32 kB, 64 kB, 128 kB, 256 kB and 500 kB respectively.
The LPC2141/42/44/46/48 flash memory provides a minimum of 100000 erase/write
cycles and 20 years of data-retention.
LPC2141_42_44_46_48 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2011. All rights reserved.
Product data sheet Rev. 5 — 12 August 2011 14 of 45
NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
6.3 On-chip static RAM
On-chip static RAM may be used for code and/or data storage. The SRAM may be
accessed as 8-bit, 16-bit, and 32-bit. The LPC2141, LPC2142/44 and LPC2146/48
provide 8 kB, 16 kB and 32 kB of static RAM respectively.
In case of LPC2146/48 only, an 8 kB SRAM block intended to be utilized mainly by the
USB can also be used as a general purpose RAM for data storage and code storage and
execution.
6.4 Memory map
The LPC2141/42/44/46/48 memory map incorporates several distinct regions, as shown
in Figure 5.
In addition, the CPU interrupt vectors may be remapped to allow them to reside in either
flash memory (the default) or on-chip static RAM. This is described in Section 6.19
“System control”.
Fig 5. LPC2141/42/44/46/48 memory map
AHB PERIPHERALS
VPB PERIPHERALS
RESERVED ADDRESS SPACE
BOOT BLOCK (12 kB REMAPPED FROM
ON-CHIP FLASH MEMORY
RESERVED ADDRESS SPACE
0xFFFF FFFF
0xF000 0000
0xE000 0000
0xC000 0000
0x8000 0000
0x7FFF FFFF
0x7FD0 2000
TOTAL OF 512 kB ON-CHIP NON-VOLATILE MEMORY
(LPC2148) 0x0004 0000
0x0007 FFFF
TOTAL OF 256 kB ON-CHIP NON-VOLATILE MEMORY
(LPC2146) 0x0002 0000
0x0003 FFFF
TOTAL OF 128 kB ON-CHIP NON-VOLATILE MEMORY
(LPC2144) 0x0001 0000
0x0001 FFFF
TOTAL OF 64 kB ON-CHIP NON-VOLATILE MEMORY
(LPC2142) 0x0000 8000
0x0000 FFFF
TOTAL OF 32 kB ON-CHIP NON-VOLATILE MEMORY
(LPC2141) 0x0000 0000
0x0000 7FFF
RESERVED ADDRESS SPACE 0x0008 0000
0x3FFF FFFF
8 kB ON-CHIP STATIC RAM (LPC2141) 0x4000 0000
0x4000 1FFF
16 kB ON-CHIP STATIC RAM (LPC2142/2144) 0x4000 2000
0x4000 3FFF
32 kB ON-CHIP STATIC RAM (LPC2146/2148) 0x4000 4000
0x4000 7FFF
RESERVED ADDRESS SPACE 0x4000 8000
0x7FCF FFFF
8 kB ON-CHIP USB DMA RAM (LPC2146/2148) 0x7FD0 0000
0x7FD0 1FFF
0x7FFF D000
0x7FFF CFFF
4.0 GB
3.75 GB
3.5 GB
3.0 GB
2.0 GB
1.0 GB
0.0 GB
002aab558
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6.5 Interrupt controller
The Vectored Interrupt Controller (VIC) accepts all of the interrupt request inputs and
categorizes them as Fast Interrupt reQuest (FIQ), vectored Interrupt ReQuest (IRQ), and
non-vectored IRQ as defined by programmable settings. The programmable assignment
scheme means that priorities of interrupts from the various peripherals can be dynamically
assigned and adjusted.
FIQ has the highest priority. If more than one request is assigned to FIQ, the VIC
combines the requests to produce the FIQ signal to the ARM processor. The fastest
possible FIQ latency is achieved when only one request is classified as FIQ, because then
the FIQ service routine does not need to branch into the interrupt service routine but can
run from the interrupt vector location. If more than one request is assigned to the FIQ
class, the FIQ service routine will read a word from the VIC that identifies which FIQ
source(s) is (are) requesting an interrupt.
Vectored IRQs have the middle priority. Sixteen of the interrupt requests can be assigned
to this category. Any of the interrupt requests can be assigned to any of the 16 vectored
IRQ slots, among which slot 0 has the highest priority and slot 15 has the lowest.
Non-vectored IRQs have the lowest priority.
The VIC combines the requests from all the vectored and non-vectored IRQs to produce
the IRQ signal to the ARM processor. The IRQ service routine can start by reading a
register from the VIC and jumping there. If any of the vectored IRQs are pending, the VIC
provides the address of the highest-priority requesting IRQs service routine, otherwise it
provides the address of a default routine that is shared by all the non-vectored IRQs. The
default routine can read another VIC register to see what IRQs are active.
6.5.1 Interrupt sources
Each peripheral device has one interrupt line connected to the Vectored Interrupt
Controller, but may have several internal interrupt flags. Individual interrupt flags may also
represent more than one interrupt source.
6.6 Pin connect block
The pin connect block allows selected pins of the microcontroller to have more than one
function. Configuration registers control the multiplexers to allow connection between the
pin and the on chip peripherals. Peripherals should be connected to the appropriate pins
prior to being activated, and prior to any related interrupt(s) being enabled. Activity of any
enabled peripheral function that is not mapped to a related pin should be considered
undefined.
The Pin Control Module with its pin select registers defines the functionality of the
microcontroller in a given hardware environment.
After reset all pins of Port 0 and Port 1 are configured as input with the following
exceptions: If debug is enabled, the JTAG pins will assume their JTAG functionality; if
trace is enabled, the Trace pins will assume their trace functionality. The pins associated
with the I2C0 and I2C1 interface are open drain.
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6.7 Fast general purpose parallel I/O (GPIO)
Device pins that are not connected to a specific peripheral function are controlled by the
GPIO registers. Pins may be dynamically configured as inputs or outputs. Separate
registers allow setting or clearing any number of outputs simultaneously. The value of the
output register may be read back, as well as the current state of the port pins.
LPC2141/42/44/46/48 introduce accelerated GPIO functions over prior LPC2000 devices:
• GPIO registers are relocated to the ARM local bus for the fastest possible I/O timing.
• Mask registers allow treating sets of port bits as a group, leaving other bits
unchanged.
• All GPIO registers are byte addressable.
• Entire port value can be written in one instruction.
6.7.1 Features
• Bit-level set and clear registers allow a single instruction set or clear of any number of
bits in one port.
• Direction control of individual bits.
• Separate control of output set and clear.
• All I/O default to inputs after reset.
6.8 10-bit ADC
The LPC2141/42 contain one and the LPC2144/46/48 contain two analog to digital
converters. These converters are single 10-bit successive approximation analog to digital
converters. While ADC0 has six channels, ADC1 has eight channels. Therefore, total
number of available ADC inputs for LPC2141/42 is 6 and for LPC2144/46/48 is 14.
6.8.1 Features
• 10 bit successive approximation analog to digital converter.
• Measurement range of 0 V to VREF (2.5 V VREF VDDA).
• Each converter capable of performing more than 400000 10-bit samples per second.
• Every analog input has a dedicated result register to reduce interrupt overhead.
• Burst conversion mode for single or multiple inputs.
• Optional conversion on transition on input pin or timer match signal.
• Global Start command for both converters (LPC2142/44/46/48 only).
6.9 10-bit DAC
The DAC enables the LPC2141/42/44/46/48 to generate a variable analog output. The
maximum DAC output voltage is the VREF voltage.
6.9.1 Features
• 10-bit DAC.
• Buffered output.
• Power-down mode available.
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• Selectable speed versus power.
6.10 USB 2.0 device controller
The USB is a 4-wire serial bus that supports communication between a host and a
number (127 max) of peripherals. The host controller allocates the USB bandwidth to
attached devices through a token based protocol. The bus supports hot plugging,
unplugging, and dynamic configuration of the devices. All transactions are initiated by the
host controller.
The LPC2141/42/44/46/48 is equipped with a USB device controller that enables
12 Mbit/s data exchange with a USB host controller. It consists of a register interface,
serial interface engine, endpoint buffer memory and DMA controller. The serial interface
engine decodes the USB data stream and writes data to the appropriate end point buffer
memory. The status of a completed USB transfer or error condition is indicated via status
registers. An interrupt is also generated if enabled.
A DMA controller (available in LPC2146/48 only) can transfer data between an endpoint
buffer and the USB RAM.
6.10.1 Features
• Fully compliant with USB 2.0 Full-speed specification.
• Supports 32 physical (16 logical) endpoints.
• Supports control, bulk, interrupt and isochronous endpoints.
• Scalable realization of endpoints at run time.
• Endpoint maximum packet size selection (up to USB maximum specification) by
software at run time.
• RAM message buffer size based on endpoint realization and maximum packet size.
• Supports SoftConnect and GoodLink LED indicator. These two functions are sharing
one pin.
• Supports bus-powered capability with low suspend current.
• Supports DMA transfer on all non-control endpoints (LPC2146/48 only).
• One duplex DMA channel serves all endpoints (LPC2146/48 only).
• Allows dynamic switching between CPU controlled and DMA modes (only in
LPC2146/48).
• Double buffer implementation for bulk and isochronous endpoints.
6.11 UARTs
The LPC2141/42/44/46/48 each contain two UARTs. In addition to standard transmit and
receive data lines, the LPC2144/46/48 UART1 also provides a full modem control
handshake interface.
Compared to previous LPC2000 microcontrollers, UARTs in LPC2141/42/44/46/48
introduce a fractional baud rate generator for both UARTs, enabling these microcontrollers
to achieve standard baud rates such as 115200 with any crystal frequency above 2 MHz.
In addition, auto-CTS/RTS flow-control functions are fully implemented in hardware
(UART1 in LPC2144/46/48 only).
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6.11.1 Features
• 16 B Receive and Transmit FIFOs.
• Register locations conform to 16C550 industry standard.
• Receiver FIFO trigger points at 1 B, 4 B, 8 B, and 14 B
• Built-in fractional baud rate generator covering wide range of baud rates without a
need for external crystals of particular values.
• Transmission FIFO control enables implementation of software (XON/XOFF) flow
control on both UARTs.
• LPC2144/46/48 UART1 equipped with standard modem interface signals. This
module also provides full support for hardware flow control (auto-CTS/RTS).
6.12 I2C-bus serial I/O controller
The LPC2141/42/44/46/48 each contain two I2C-bus controllers.
The I2C-bus is bidirectional, for inter-IC control using only two wires: a Serial Clock Line
(SCL), and a Serial DAta line (SDA). Each device is recognized by a unique address and
can operate as either a receiver-only device (e.g., an LCD driver or a transmitter with the
capability to both receive and send information (such as memory)). Transmitters and/or
receivers can operate in either master or slave mode, depending on whether the chip has
to initiate a data transfer or is only addressed. The I2C-bus is a multi-master bus, it can be
controlled by more than one bus master connected to it.
The I2C-bus implemented in LPC2141/42/44/46/48 supports bit rates up to 400 kbit/s
(Fast I2C-bus).
6.12.1 Features
• Compliant with standard I2C-bus interface.
• Easy to configure as master, slave, or master/slave.
• Programmable clocks allow versatile rate control.
• Bidirectional data transfer between masters and slaves.
• Multi-master bus (no central master).
• Arbitration between simultaneously transmitting masters without corruption of serial
data on the bus.
• Serial clock synchronization allows devices with different bit rates to communicate via
one serial bus.
• Serial clock synchronization can be used as a handshake mechanism to suspend and
resume serial transfer.
• The I2C-bus can be used for test and diagnostic purposes.
6.13 SPI serial I/O controller
The LPC2141/42/44/46/48 each contain one SPI controller. The SPI is a full duplex serial
interface, designed to handle multiple masters and slaves connected to a given bus. Only
a single master and a single slave can communicate on the interface during a given data
transfer. During a data transfer the master always sends a byte of data to the slave, and
the slave always sends a byte of data to the master.
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6.13.1 Features
• Compliant with SPI specification.
• Synchronous, Serial, Full Duplex, Communication.
• Combined SPI master and slave.
• Maximum data bit rate of one eighth of the input clock rate.
6.14 SSP serial I/O controller
The LPC2141/42/44/46/48 each contain one Serial Synchronous Port controller (SSP).
The SSP controller is capable of operation on a SPI, 4-wire SSI, or Microwire bus. It can
interact with multiple masters and slaves on the bus. However, only a single master and a
single slave can communicate on the bus during a given data transfer. The SSP supports
full duplex transfers, with data frames of 4 bits to 16 bits of data flowing from the master to
the slave and from the slave to the master. Often only one of these data flows carries
meaningful data.
6.14.1 Features
• Compatible with Motorola’s SPI, TI’s 4-wire SSI and National Semiconductor’s
Microwire buses.
• Synchronous serial communication.
• Master or slave operation.
• 8-frame FIFOs for both transmit and receive.
• Four bits to 16 bits per frame.
6.15 General purpose timers/external event counters
The Timer/Counter is designed to count cycles of the peripheral clock (PCLK) or an
externally supplied clock and optionally generate interrupts or perform other actions at
specified timer values, based on four match registers. It also includes four capture inputs
to trap the timer value when an input signal transitions, optionally generating an interrupt.
Multiple pins can be selected to perform a single capture or match function, providing an
application with ‘or’ and ‘and’, as well as ‘broadcast’ functions among them.
The LPC2141/42/44/46/48 can count external events on one of the capture inputs if the
minimum external pulse is equal or longer than a period of the PCLK. In this configuration,
unused capture lines can be selected as regular timer capture inputs, or used as external
interrupts.
6.15.1 Features
• A 32-bit timer/counter with a programmable 32-bit prescaler.
• External event counter or timer operation.
• Four 32-bit capture channels per timer/counter that can take a snapshot of the timer
value when an input signal transitions. A capture event may also optionally generate
an interrupt.
• Four 32-bit match registers that allow:
– Continuous operation with optional interrupt generation on match.
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– Stop timer on match with optional interrupt generation.
– Reset timer on match with optional interrupt generation.
• Four external outputs per timer/counter corresponding to match registers, with the
following capabilities:
– Set LOW on match.
– Set HIGH on match.
– Toggle on match.
– Do nothing on match.
6.16 Watchdog timer
The purpose of the watchdog is to reset the microcontroller within a reasonable amount of
time if it enters an erroneous state. When enabled, the watchdog will generate a system
reset if the user program fails to ‘feed’ (or reload) the watchdog within a predetermined
amount of time.
6.16.1 Features
• Internally resets chip if not periodically reloaded.
• Debug mode.
• Enabled by software but requires a hardware reset or a watchdog reset/interrupt to be
disabled.
• Incorrect/Incomplete feed sequence causes reset/interrupt if enabled.
• Flag to indicate watchdog reset.
• Programmable 32-bit timer with internal pre-scaler.
• Selectable time period from (Tcy(PCLK) 256 4) to (Tcy(PCLK) 232 4) in multiples of
Tcy(PCLK) 4.
6.17 Real-time clock
The RTC is designed to provide a set of counters to measure time when normal or idle
operating mode is selected. The RTC has been designed to use little power, making it
suitable for battery powered systems where the CPU is not running continuously (Idle
mode).
6.17.1 Features
• Measures the passage of time to maintain a calendar and clock.
• Ultra-low power design to support battery powered systems.
• Provides Seconds, Minutes, Hours, Day of Month, Month, Year, Day of Week, and
Day of Year.
• Can use either the RTC dedicated 32 kHz oscillator input or clock derived from the
external crystal/oscillator input at XTAL1. Programmable reference clock divider
allows fine adjustment of the RTC.
• Dedicated power supply pin can be connected to a battery or the main 3.3 V.
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6.18 Pulse width modulator
The PWM is based on the standard timer block and inherits all of its features, although
only the PWM function is pinned out on the LPC2141/42/44/46/48. The timer is designed
to count cycles of the peripheral clock (PCLK) and optionally generate interrupts or
perform other actions when specified timer values occur, based on seven match registers.
The PWM function is also based on match register events.
The ability to separately control rising and falling edge locations allows the PWM to be
used for more applications. For instance, multi-phase motor control typically requires
three non-overlapping PWM outputs with individual control of all three pulse widths and
positions.
Two match registers can be used to provide a single edge controlled PWM output. One
match register (MR0) controls the PWM cycle rate, by resetting the count upon match.
The other match register controls the PWM edge position. Additional single edge
controlled PWM outputs require only one match register each, since the repetition rate is
the same for all PWM outputs. Multiple single edge controlled PWM outputs will all have a
rising edge at the beginning of each PWM cycle, when an MR0 match occurs.
Three match registers can be used to provide a PWM output with both edges controlled.
Again, the MR0 match register controls the PWM cycle rate. The other match registers
control the two PWM edge positions. Additional double edge controlled PWM outputs
require only two match registers each, since the repetition rate is the same for all PWM
outputs.
With double edge controlled PWM outputs, specific match registers control the rising and
falling edge of the output. This allows both positive going PWM pulses (when the rising
edge occurs prior to the falling edge), and negative going PWM pulses (when the falling
edge occurs prior to the rising edge).
6.18.1 Features
• Seven match registers allow up to six single edge controlled or three double edge
controlled PWM outputs, or a mix of both types.
• The match registers also allow:
– Continuous operation with optional interrupt generation on match.
– Stop timer on match with optional interrupt generation.
– Reset timer on match with optional interrupt generation.
• Supports single edge controlled and/or double edge controlled PWM outputs. Single
edge controlled PWM outputs all go HIGH at the beginning of each cycle unless the
output is a constant LOW. Double edge controlled PWM outputs can have either edge
occur at any position within a cycle. This allows for both positive going and negative
going pulses.
• Pulse period and width can be any number of timer counts. This allows complete
flexibility in the trade-off between resolution and repetition rate. All PWM outputs will
occur at the same repetition rate.
• Double edge controlled PWM outputs can be programmed to be either positive going
or negative going pulses.
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• Match register updates are synchronized with pulse outputs to prevent generation of
erroneous pulses. Software must ‘release’ new match values before they can become
effective.
• May be used as a standard timer if the PWM mode is not enabled.
• A 32-bit Timer/Counter with a programmable 32-bit Prescaler.
6.19 System control
6.19.1 Crystal oscillator
On-chip integrated oscillator operates with external crystal in range of 1 MHz to 25 MHz.
The oscillator output frequency is called fosc and the ARM processor clock frequency is
referred to as CCLK for purposes of rate equations, etc. fosc and CCLK are the same
value unless the PLL is running and connected. Refer to Section 6.19.2 “PLL” for
additional information.
6.19.2 PLL
The PLL accepts an input clock frequency in the range of 10 MHz to 25 MHz. The input
frequency is multiplied up into the range of 10 MHz to 60 MHz with a Current Controlled
Oscillator (CCO). The multiplier can be an integer value from 1 to 32 (in practice, the
multiplier value cannot be higher than 6 on this family of microcontrollers due to the upper
frequency limit of the CPU). The CCO operates in the range of 156 MHz to 320 MHz, so
there is an additional divider in the loop to keep the CCO within its frequency range while
the PLL is providing the desired output frequency. The output divider may be set to divide
by 2, 4, 8, or 16 to produce the output clock. Since the minimum output divider value is 2,
it is insured that the PLL output has a 50 % duty cycle. The PLL is turned off and
bypassed following a chip reset and may be enabled by software. The program must
configure and activate the PLL, wait for the PLL to Lock, then connect to the PLL as a
clock source. The PLL settling time is 100 s.
6.19.3 Reset and wake-up timer
Reset has two sources on the LPC2141/42/44/46/48: the RESET pin and watchdog reset.
The RESET pin is a Schmitt trigger input pin with an additional glitch filter. Assertion of
chip reset by any source starts the Wake-up Timer (see Wake-up Timer description
below), causing the internal chip reset to remain asserted until the external reset is
de-asserted, the oscillator is running, a fixed number of clocks have passed, and the
on-chip flash controller has completed its initialization.
When the internal reset is removed, the processor begins executing at address 0, which is
the reset vector. At that point, all of the processor and peripheral registers have been
initialized to predetermined values.
The Wake-up Timer ensures that the oscillator and other analog functions required for
chip operation are fully functional before the processor is allowed to execute instructions.
This is important at power on, all types of reset, and whenever any of the aforementioned
functions are turned off for any reason. Since the oscillator and other functions are turned
off during Power-down mode, any wake-up of the processor from Power-down mode
makes use of the Wake-up Timer.
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The Wake-up Timer monitors the crystal oscillator as the means of checking whether it is
safe to begin code execution. When power is applied to the chip, or some event caused
the chip to exit Power-down mode, some time is required for the oscillator to produce a
signal of sufficient amplitude to drive the clock logic. The amount of time depends on
many factors, including the rate of VDD ramp (in the case of power on), the type of crystal
and its electrical characteristics (if a quartz crystal is used), as well as any other external
circuitry (e.g. capacitors), and the characteristics of the oscillator itself under the existing
ambient conditions.
6.19.4 Brownout detector
The LPC2141/42/44/46/48 include 2-stage monitoring of the voltage on the VDD pins. If
this voltage falls below 2.9 V, the BOD asserts an interrupt signal to the VIC. This signal
can be enabled for interrupt; if not, software can monitor the signal by reading dedicated
register.
The second stage of low voltage detection asserts reset to inactivate the
LPC2141/42/44/46/48 when the voltage on the VDD pins falls below 2.6 V. This reset
prevents alteration of the flash as operation of the various elements of the chip would
otherwise become unreliable due to low voltage. The BOD circuit maintains this reset
down below 1 V, at which point the POR circuitry maintains the overall reset.
Both the 2.9 V and 2.6 V thresholds include some hysteresis. In normal operation, this
hysteresis allows the 2.9 V detection to reliably interrupt, or a regularly-executed event
loop to sense the condition.
6.19.5 Code security
This feature of the LPC2141/42/44/46/48 allow an application to control whether it can be
debugged or protected from observation.
If after reset on-chip boot loader detects a valid checksum in flash and reads 0x8765 4321
from address 0x1FC in flash, debugging will be disabled and thus the code in flash will be
protected from observation. Once debugging is disabled, it can be enabled only by
performing a full chip erase using the ISP.
6.19.6 External interrupt inputs
The LPC2141/42/44/46/48 include up to nine edge or level sensitive External Interrupt
Inputs as selectable pin functions. When the pins are combined, external events can be
processed as four independent interrupt signals. The External Interrupt Inputs can
optionally be used to wake-up the processor from Power-down mode.
Additionally capture input pins can also be used as external interrupts without the option
to wake the device up from Power-down mode.
6.19.7 Memory mapping control
The Memory Mapping Control alters the mapping of the interrupt vectors that appear
beginning at address 0x0000 0000. Vectors may be mapped to the bottom of the on-chip
flash memory, or to the on-chip static RAM. This allows code running in different memory
spaces to have control of the interrupts.
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6.19.8 Power control
The LPC2141/42/44/46/48 supports two reduced power modes: Idle mode and
Power-down mode.
In Idle mode, execution of instructions is suspended until either a reset or interrupt occurs.
Peripheral functions continue operation during Idle mode and may generate interrupts to
cause the processor to resume execution. Idle mode eliminates power used by the
processor itself, memory systems and related controllers, and internal buses.
In Power-down mode, the oscillator is shut down and the chip receives no internal clocks.
The processor state and registers, peripheral registers, and internal SRAM values are
preserved throughout Power-down mode and the logic levels of chip output pins remain
static. The Power-down mode can be terminated and normal operation resumed by either
a reset or certain specific interrupts that are able to function without clocks. Since all
dynamic operation of the chip is suspended, Power-down mode reduces chip power
consumption to nearly zero.
Selecting an external 32 kHz clock instead of the PCLK as a clock-source for the on-chip
RTC will enable the microcontroller to have the RTC active during Power-down mode.
Power-down current is increased with RTC active. However, it is significantly lower than in
Idle mode.
A Power Control for Peripherals feature allows individual peripherals to be turned off if
they are not needed in the application, resulting in additional power savings during active
and Idle mode.
6.19.9 APB bus
The APB divider determines the relationship between the processor clock (CCLK) and the
clock used by peripheral devices (PCLK). The APB divider serves two purposes. The first
is to provide peripherals with the desired PCLK via APB bus so that they can operate at
the speed chosen for the ARM processor. In order to achieve this, the APB bus may be
slowed down to 12 to 14 of the processor clock rate. Because the APB bus must work
properly at power-up (and its timing cannot be altered if it does not work since the APB
divider control registers reside on the APB bus), the default condition at reset is for the
APB bus to run at 14 of the processor clock rate. The second purpose of the APB divider
is to allow power savings when an application does not require any peripherals to run at
the full processor rate. Because the APB divider is connected to the PLL output, the PLL
remains active (if it was running) during Idle mode.
6.20 Emulation and debugging
The LPC2141/42/44/46/48 support emulation and debugging via a JTAG serial port. A
trace port allows tracing program execution. Debugging and trace functions are
multiplexed only with GPIOs on Port 1. This means that all communication, timer and
interface peripherals residing on Port 0 are available during the development and
debugging phase as they are when the application is run in the embedded system itself.
6.20.1 EmbeddedICE
Standard ARM EmbeddedICE logic provides on-chip debug support. The debugging of
the target system requires a host computer running the debugger software and an
EmbeddedICE protocol convertor. EmbeddedICE protocol convertor converts the remote
debug protocol commands to the JTAG data needed to access the ARM core.
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The ARM core has a Debug Communication Channel (DCC) function built-in. The DCC
allows a program running on the target to communicate with the host debugger or another
separate host without stopping the program flow or even entering the debug state. The
DCC is accessed as a co-processor 14 by the program running on the ARM7TDMI-S
core. The DCC allows the JTAG port to be used for sending and receiving data without
affecting the normal program flow. The DCC data and control registers are mapped in to
addresses in the EmbeddedICE logic.
This clock must be slower than 16 of the CPU clock (CCLK) for the JTAG interface to
operate.
6.20.2 Embedded trace
Since the LPC2141/42/44/46/48 have significant amounts of on-chip memory, it is not
possible to determine how the processor core is operating simply by observing the
external pins. The Embedded Trace Macrocell (ETM) provides real-time trace capability
for deeply embedded processor cores. It outputs information about processor execution to
the trace port.
The ETM is connected directly to the ARM core and not to the main AMBA system bus. It
compresses the trace information and exports it through a narrow trace port. An external
trace port analyzer must capture the trace information under software debugger control.
Instruction trace (or PC trace) shows the flow of execution of the processor and provides a
list of all the instructions that were executed. Instruction trace is significantly compressed
by only broadcasting branch addresses as well as a set of status signals that indicate the
pipeline status on a cycle by cycle basis. Trace information generation can be controlled
by selecting the trigger resource. Trigger resources include address comparators,
counters and sequencers. Since trace information is compressed the software debugger
requires a static image of the code being executed. Self-modifying code can not be traced
because of this restriction.
6.20.3 RealMonitor
RealMonitor is a configurable software module, developed by ARM Inc., which enables
real-time debug. It is a lightweight debug monitor that runs in the background while users
debug their foreground application. It communicates with the host using the DCC, which is
present in the EmbeddedICE logic. The LPC2141/42/44/46/48 contain a specific
configuration of RealMonitor software programmed into the on-chip flash memory.
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NXP Semiconductors LPC2141/42/44/46/48
Single-chip 16-bit/32-bit microcontrollers
7. Limiting values
[1] The following applies to the Limiting values:
a) This product includes circuitry specifically designed for the protection of its internal devices from the damaging effects of excessive
static charge. Nonetheless, it is suggested that conventional precautions be taken to avoid applying greater than the rated
maximum.
b) Parameters are valid over operating temperature range unless otherwise specified. All voltages are with respect to VSS unless
otherwise noted.
[2] Including voltage on outputs in 3-state mode.
[3] Not to exceed 4.6 V.
[4] The peak current is limited to 25 times the corresponding maximum current.
[5] Dependent on package type.
[6] Human body model: equivalent to discharging a 100 pF capacitor through a 1.5 k series resistor.
Table 4. Limiting values
In accordance with the Absolute Maximum Rating System (IEC 60134).[1]
Symbol Parameter Conditions Min Max Unit
VDD supply voltage (core and external rail) 0.5 +3.6 V
VDDA analog 3.3 V pad supply voltage 0.5 +4.6 V
Vi(VBAT) input voltage on pin VBAT for the RTC 0.5 +4.6 V
Vi(VREF) input voltage on pin VREF 0.5 +4.6 V
VIA analog input voltage on ADC related
pins
0.5 +5.1 V
VI input voltage 5 V tolerant I/O
pins; only valid
when the VDD
supply voltage is
present
[2] 0.5 +6.0 V
other I/O pins [2][3] 0.5 VDD + 0.5 V
IDD supply current per supply pin [4] - 100 mA
ISS ground current per ground pin [4] - 100 mA
Isink sink current for I2C-bus; DC;
T = 85 C
- 20 mA
Tstg storage temperature [5] 65 +150 C
Ptot(pack) total power dissipation (per package) based on package
heat transfer, not
device power
consumption
- 1.5 W
Vesd electrostatic discharge voltage human body model [6]
all pins 4000 +4000 V
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Single-chip 16-bit/32-bit microcontrollers
8. Static characteristics
Table 5. Static characteristics
Tamb = 40 C to +85 C for commercial applications, unless otherwise specified.
Symbol Parameter Conditions Min Typ[1] Max Unit
VDD supply voltage [2] 3.0 3.3 3.6 V
VDDA analog supply voltage 3.3 V pad 3.0 3.3 3.6 V
Vi(VBAT) input voltage on pin
VBAT
[3] 2.0 3.3 3.6 V
Vi(VREF) input voltage on pin
VREF
2.5 3.3 VDDA V
Standard port pins, RESET, P1.26/RTCK
IIL LOW-level input current VI = 0 V; no pull-up - - 3 A
IIH HIGH-level input current VI = VDD; no pull-down - - 3 A
IOZ OFF-state output
current
VO = 0 V; VO = VDD; no
pull-up/down
--3 A
Ilatch I/O latch-up current (0.5VDD) < VI < (1.5VDD);
Tj
< 125 C
- - 100 mA
VI input voltage pin configured to provide a
digital function
[4][5][6]
[7]
0- 5.5 V
VO output voltage output active 0 - VDD V
VIH HIGH-level input voltage 2.0 - - V
VIL LOW-level input voltage - - 0.8 V
Vhys hysteresis voltage 0.4 - - V
VOH HIGH-level output
voltage
IOH = 4 mA [8] VDD 0.4 - - V
VOL LOW-level output
voltage
IOL = 4 mA [8] --0.4 V
IOH HIGH-level output
current
VOH = VDD 0.4 V [8] 4 - - mA
IOL LOW-level output
current
VOL = 0.4 V [8] 4- - mA
IOHS HIGH-level short-circuit
output current
VOH =0V [9] - - 45 mA
IOLS LOW-level short-circuit
output current
VOL = VDDA [9] --50 mA
Ipd pull-down current VI =5V [10] 10 50 150 A
Ipu pull-up current VI =0V [11] 15 50 85 A
VDD < VI <5V [10] 000 A
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Single-chip 16-bit/32-bit microcontrollers
IDD(act) active mode supply
current
VDD = 3.3 V; Tamb = 25 C;
code
while(1){}
executed from flash, no active
peripherals
CCLK = 10 MHz
- 15 50
mA
CCLK = 60 MHz - 40 70 mA
VDD = 3.3 V; Tamb = 25 C;
code executed from flash; USB
enabled and active; all other
peripherals disabled
CCLK = 12 MHz
- 27 70
mA
CCLK = 60 MHz - 57 90 mA
IDD(pd) Power-down mode
supply current
VDD = 3.3 V; Tamb = 25 C - 40 100 A
VDD = 3.3 V; Tamb = 85 C -250 500 A
IBATpd Power-down mode
battery supply current
RTC clock = 32 kHz
(from RTCXn pins);
Tamb = 25 C
VDD = 3.0 V; Vi(VBAT) = 2.5 V
[12] - 15 30
A
VDD = 3.0 V; Vi(VBAT) = 3.0 V - 20 40 A
IBATact active mode battery
supply current
CCLK = 60 MHz;
PCLK = 15 MHz;
PCLK enabled to RTCK;
RTC clock = 32 kHz
(from RTCXn pins);
Tamb = 25 C
VDD = 3.0 V; Vi(VBAT) = 3.0 V
[12] - 78 -
A
IBATact(opt) optimized active mode
battery supply current
PCLK disabled to RTCK in the
PCONP register;
RTC clock = 32 kHz
(from RTCXn pins);
Tamb = 25 C; Vi(VBAT) = 3.3 V
CCLK = 25 MHz
[12][13] - 23 -
A
CCLK = 60 MHz - 30 - A
I
2C-bus pins
VIH HIGH-level input voltage 0.7VDD --V
VIL LOW-level input voltage - - 0.3VDD V
Vhys hysteresis voltage - 0.05VDD - V
VOL LOW-level output
voltage
IOLS = 3 mA [8] --0.4 V
ILI input leakage current VI = VDD [14] - 24 A
VI = 5 V - 10 22 A
Oscillator pins
Vi(XTAL1) input voltage on pin
XTAL1
0.5 1.8 1.95 V
Table 5. Static characteristics …continued
Tamb = 40 C to +85 C for commercial applications, unless otherwise specified.
Symbol Parameter Conditions Min Typ[1] Max Unit
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Single-chip 16-bit/32-bit microcontrollers
[1] Typical ratings are not guaranteed. The values listed are at room temperature (25 C), nominal supply voltages.
[2] Core and external rail.
[3] The RTC typically fails when Vi(VBAT) drops below 1.6 V.
[4] Including voltage on outputs in 3-state mode.
[5] VDD supply voltages must be present.
[6] 3-state outputs go into 3-state mode when VDD is grounded.
[7] Please also see the errata note mentioned in errata sheet.
[8] Accounts for 100 mV voltage drop in all supply lines.
[9] Allowed as long as the current limit does not exceed the maximum current allowed by the device.
[10] Minimum condition for VI = 4.5 V, maximum condition for VI = 5.5 V.
[11] Applies to P1.16 to P1.31.
[12] On pin VBAT.
[13] Optimized for low battery consumption.
[14] To VSS.
[15] Includes external resistors of 33 ± 1 % on D+ and D.
Vo(XTAL2) output voltage on pin
XTAL2
0.5 1.8 1.95 V
Vi(RTCX1) input voltage on pin
RTCX1
0.5 1.8 1.95 V
Vo(RTCX2) output voltage on pin
RTCX2
0.5 1.8 1.95 V
USB pins
IOZ OFF-state output
current
0V 85 C [12] 15 50 100 A
VDD(3V3) < VI <5V [11] 00 0 A
I
2C-bus pins (P0[27] and P0[28])
VIH HIGH-level input
voltage
0.7VDD(3V3) - -V
VIL LOW-level input voltage - - 0.3VDD(3V3) V
Vhys hysteresis voltage - 0.05VDD(3V3) - V
VOL LOW-level output
voltage
IOLS = 3 mA [9] -- 0.4 V
ILI input leakage current VI = VDD(3V3) [13] -2 4 A
VI = 5 V - 10 22 A
Oscillator pins
Vi(XTAL1) input voltage on pin
XTAL1
0.5 1.8 1.95 V
Vo(XTAL2) output voltage on pin
XTAL2
0.5 1.8 1.95 V
Vi(RTCX1) input voltage on pin
RTCX1
0.5 1.8 1.95 V
Vo(RTCX2) output voltage on pin
RTCX2
0.5 1.8 1.95 V
Table 8. Static characteristics …continued
Tamb = 40 C to +85 C for standard devices, 40 C to +125 C for LPC2364HBD only, unless otherwise specified.
Symbol Parameter Conditions Min Typ[1] Max Unit
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Single-chip 16-bit/32-bit microcontrollers
[1] Typical ratings are not guaranteed. The values listed are at room temperature (25 C), nominal supply voltages.
[2] The RTC typically fails when Vi(VBAT) drops below 1.6 V.
[3] VDD(DCDC)(3V3) = 3.3 V; VDD(3V3) = 3.3 V; Vi(VBAT) = 3.3 V; Tamb = 25 C.
[4] On pin VBAT.
[5] Including voltage on outputs in 3-state mode.
[6] VDD(3V3) supply voltages must be present.
[7] 3-state outputs go into 3-state mode when VDD(3V3) is grounded.
[8] Please also see the errata note in errata sheet.
[9] Accounts for 100 mV voltage drop in all supply lines.
[10] Allowed as long as the current limit does not exceed the maximum current allowed by the device.
[11] Minimum condition for VI = 4.5 V, maximum condition for VI = 5.5 V.
[12] LPC2364HBD only.
[13] To VSS.
[14] Includes external resistors of 33 1 % on D+ and D.
USB pins (LPC2364/66/68 only)
IOZ OFF-state output
current
0V 85 C [3] 1 -60 MHz
IRC; 40 C to +85 C 3.96 4 4.04 MHz
IRC; > 85 C [3] 3.98 4.02 4.06 MHz
External clock
fosc oscillator frequency 1 - 25 MHz
Tcy(clk) clock cycle time 40 - 1000 ns
tCHCX clock HIGH time Tcy(clk) 0.4 - - ns
tCLCX clock LOW time Tcy(clk) 0.4 - - ns
tCLCH clock rise time - - 5 ns
tCHCL clock fall time - - 5 ns
I
2C-bus pins (P0[27] and P0[28])
tf(o) output fall time VIH to VIL 20 + 0.1 Cb
[4] - - ns
SSP interface
tsu(SPI_MISO) SPI_MISO set-up time Tamb = 25 C; measured
in SPI Master mode; see
Figure 15
- 11- ns
Fig 13. External clock timing (with an amplitude of at least Vi(RMS) = 200 mV)
tCHCL tCLCX
tCHCX
Tcy(clk)
tCLCH
002aaa907
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Single-chip 16-bit/32-bit microcontrollers
11.1 Internal oscillators
[1] Parameters are valid over operating temperature range unless otherwise specified.
[2] Typical ratings are not guaranteed. The values listed are at room temperature (25 C), nominal supply voltages.
11.2 I/O pins
[1] Applies to standard I/O pins and RESET pin.
11.3 USB interface
[1] Characterized but not implemented as production test. Guaranteed by design.
Table 10. Dynamic characteristic: internal oscillators
Tamb = 40 C to +85 C; 3.0 V VDD(3V3) 3.6 V.[1]
Symbol Parameter Conditions Min Typ[2] Max Unit
fosc(RC) internal RC oscillator frequency - 3.96 4.02 4.04 MHz
fi(RTC) RTC input frequency - - 32.768 - kHz
Table 11. Dynamic characteristic: I/O pins[1]
Tamb = 40 C to +85 C; VDD(3V3) over specified ranges.
Symbol Parameter Conditions Min Typ Max Unit
tr rise time pin configured as output 3.0 - 5.0 ns
tf fall time pin configured as output 2.5 - 5.0 ns
Table 12. Dynamic characteristics of USB pins (full-speed) (LPC2364/66/68 only)
CL = 50 pF; Rpu = 1.5 k on D+ to VDD(3V3), unless otherwise specified.
Symbol Parameter Conditions Min Typ Max Unit
tr rise time 10 % to 90 % 8.5 - 13.8 ns
tf fall time 10 % to 90 % 7.7 - 13.7 ns
tFRFM differential rise and fall time
matching
tr / tf - -109 %
VCRS output signal crossover voltage 1.3 - 2.0 V
tFEOPT source SE0 interval of EOP see Figure 14 160 - 175 ns
tFDEOP source jitter for differential transition
to SE0 transition
see Figure 14 2 - +5 ns
tJR1 receiver jitter to next transition 18.5 - +18.5 ns
tJR2 receiver jitter for paired transitions 10 % to 90 % 9 - +9 ns
tEOPR1 EOP width at receiver must reject as
EOP; see
Figure 14
[1] 40 - - ns
tEOPR2 EOP width at receiver must accept as
EOP; see
Figure 14
[1] 82 - - ns
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Single-chip 16-bit/32-bit microcontrollers
11.4 Flash memory
[1] Number of program/erase cycles.
[2] Programming times are given for writing 256 bytes from RAM to the flash. Data must be written to the flash in blocks of 256 bytes.
Table 13. Dynamic characteristics of flash
Tamb = 40 C to +85 C for standard devices, 40 C to +125 C for LPC2364HBD only, unless otherwise specified;
VDD(3V3) = 3.0 V to 3.6 V; all voltages are measured with respect to ground.
Symbol Parameter Conditions Min Typ Max Unit
Nendu endurance [1] 10000 100000 - cycles
tret retention time powered; 100 cycles 10 - - years
unpowered; 100 cycles 20 - - years
ter erase time sector or multiple
consecutive sectors
95 100 105 ms
tprog programming time [2] 0.95 1 1.05 ms
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Single-chip 16-bit/32-bit microcontrollers
11.5 Timing
Fig 14. Differential data-to-EOP transition skew and EOP width
002aab561
TPERIOD
differential
data lines
crossover point
source EOP width: tFEOPT
receiver EOP width: tEOPR1, tEOPR2
crossover point
extended
differential data to
SE0/EOP skew
n × TPERIOD + tFDEOP
Fig 15. MISO line set-up time in SSP Master mode
tsu(SPI_MISO)
SCK
shifting edges
MOSI
MISO
002aad326
sampling edges
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Single-chip 16-bit/32-bit microcontrollers
12. ADC electrical characteristics
[1] Conditions: VSSA = 0 V, VDDA = 3.3 V.
[2] The ADC is monotonic, there are no missing codes.
[3] The differential linearity error (ED) is the difference between the actual step width and the ideal step width. See Figure 16.
[4] The integral non-linearity (EL(adj)) is the peak difference between the center of the steps of the actual and the ideal transfer curve after
appropriate adjustment of gain and offset errors. See Figure 16.
[5] The offset error (EO) is the absolute difference between the straight line which fits the actual curve and the straight line which fits the
ideal curve. See Figure 16.
[6] The gain error (EG) is the relative difference in percent between the straight line fitting the actual transfer curve after removing offset
error, and the straight line which fits the ideal transfer curve. See Figure 16.
[7] The absolute error (ET) is the maximum difference between the center of the steps of the actual transfer curve of the non-calibrated
ADC and the ideal transfer curve. See Figure 16.
[8] See Figure 17.
Table 14. ADC characteristics
VDDA = 2.5 V to 3.6 V; Tamb = 40 C to +85 C, unless otherwise specified; ADC frequency 4.5 MHz.
Symbol Parameter Conditions Min Typ Max Unit
VIA analog input voltage 0 - VDDA V
Cia analog input capacitance - - 1 pF
ED differential linearity error [1][2][3] - - 1 LSB
EL(adj) integral non-linearity [1][4] - - 2 LSB
EO offset error [1][5] - - 3 LSB
EG gain error [1][6] - - 0.5 %
ET absolute error [1][7] - - 4 LSB
Rvsi voltage source interface
resistance
[8] --40 k
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Single-chip 16-bit/32-bit microcontrollers
(1) Example of an actual transfer curve.
(2) The ideal transfer curve.
(3) Differential linearity error (ED).
(4) Integral non-linearity (EL(adj)).
(5) Center of a step of the actual transfer curve.
Fig 16. ADC characteristics
1023
1022
1021
1020
1019
(2)
(1)
123456 7 1018 1019 1020 1021 1022 1023 1024
7
6
5
4
3
2
1
0
1018
(5)
(4)
(3)
1 LSB
(ideal)
code
out
offset
error
EO
gain
error
EG
offset error
EO
VIA (LSBideal)
002aae604
Vi(VREF) − VSSA
1024
1 LSB =
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Single-chip 16-bit/32-bit microcontrollers
Fig 17. Suggested ADC interface - LPC2364/65/66/67/68 AD0[y] pin
LPC23XX
AD0[y]SAMPLE
AD0[y] 20 kΩ
3 pF 5 pF
Rvsi
VSS
VEXT
002aac610
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13. DAC electrical characteristics
14. Application information
14.1 Suggested USB interface solutions (LPC2364/66/68 only)
Table 15. DAC electrical characteristics
VDDA = 3.0 V to 3.6 V; Tamb = 40 C to +85 C unless otherwise specified
Symbol Parameter Conditions Min Typ Max Unit
ED differential linearity error - 1 - LSB
EL(adj) integral non-linearity - 1.5 - LSB
EO offset error - 0.6 - %
EG gain error - 0.6 - %
CL load capacitance - 200 - pF
RL load resistance 1 - - k
Fig 18. LPC2364/66/68 USB interface on a self-powered device
LPC23XX
USB-B
connector
USB_D+
USB_CONNECT
SoftConnect switch
USB_D−
VBUS
VSS
VDD(3V3)
R1
1.5 kΩ
RS = 33 Ω
002aac578
RS = 33 Ω
USB_UP_LED
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Single-chip 16-bit/32-bit microcontrollers
14.2 Crystal oscillator XTAL input and component selection
The input voltage to the on-chip oscillators is limited to 1.8 V. If the oscillator is driven by a
clock in slave mode, it is recommended that the input be coupled through a capacitor with
Ci
= 100 pF. To limit the input voltage to the specified range, choose an additional
capacitor to ground Cg which attenuates the input voltage by a factor Ci
/ (Ci
+ Cg). In
slave mode, a minimum of 200 mV (RMS) is needed.
In slave mode the input clock signal should be coupled by means of a capacitor of 100 pF
(Figure 20), with an amplitude between 200 mV (RMS) and 1000 mV (RMS). This
corresponds to a square wave signal with a signal swing of between 280 mV and 1.4 V.
The XTAL2 pin in this configuration can be left unconnected.
External components and models used in oscillation mode are shown in Figure 21 and in
Table 16 and Table 17. Since the feedback resistance is integrated on chip, only a crystal
and the capacitances CX1 and CX2 need to be connected externally in case of
fundamental mode oscillation (the fundamental frequency is represented by L, CL and
RS). Capacitance CP in Figure 21 represents the parallel package capacitance and should
not be larger than 7 pF. Parameters FOSC, CL, RS and CP are supplied by the crystal
manufacturer.
Fig 19. LPC2364/66/68 USB interface on a bus-powered device
LPC23XX
VDD(3V3)
R1
1.5 kΩ
R2
USB_UP_LED
002aac579
USB-B
connector USB_D+
USB_D−
VBUS
VSS
RS = 33 Ω
RS = 33 Ω
Fig 20. Slave mode operation of the on-chip oscillator
LPC2xxx
XTAL1
Ci
100 pF
Cg
002aae718
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Fig 21. Oscillator modes and models: oscillation mode of operation and external crystal
model used for CX1/CX2 evaluation
Table 16. Recommended values for CX1/CX2 in oscillation mode (crystal and external
components parameters): low frequency mode
Fundamental oscillation
frequency FOSC
Crystal load
capacitance CL
Maximum crystal
series resistance RS
External load
capacitors CX1/CX2
1 MHz to 5 MHz 10 pF < 300 18 pF, 18 pF
20 pF < 300 39 pF, 39 pF
30 pF < 300 57 pF, 57 pF
5 MHz to 10 MHz 10 pF < 300 18 pF, 18 pF
20 pF < 200 39 pF, 39 pF
30 pF < 100 57 pF, 57 pF
10 MHz to 15 MHz 10 pF < 160 18 pF, 18 pF
20 pF < 60 39 pF, 39 pF
15 MHz to 20 MHz 10 pF < 80 18 pF, 18 pF
Table 17. Recommended values for CX1/CX2 in oscillation mode (crystal and external
components parameters): high frequency mode
Fundamental oscillation
frequency FOSC
Crystal load
capacitance CL
Maximum crystal
series resistance RS
External load
capacitors CX1, CX2
15 MHz to 20 MHz 10 pF < 180 18 pF, 18 pF
20 pF < 100 39 pF, 39 pF
20 MHz to 25 MHz 10 pF < 160 18 pF, 18 pF
20 pF < 80 39 pF, 39 pF
002aag469
LPC2xxx
XTAL1 XTAL2
CX1 CX2
XTAL
= CL CP
RS
L
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14.3 RTC 32 kHz oscillator component selection
The RTC external oscillator circuit is shown in Figure 22. Since the feedback resistance is
integrated on chip, only a crystal, the capacitances CX1 and CX2 need to be connected
externally to the microcontroller.
Table 18 gives the crystal parameters that should be used. CL is the typical load
capacitance of the crystal and is usually specified by the crystal manufacturer. The actual
CL influences oscillation frequency. When using a crystal that is manufactured for a
different load capacitance, the circuit will oscillate at a slightly different frequency
(depending on the quality of the crystal) compared to the specified one. Therefore for an
accurate time reference it is advised to use the load capacitors as specified in Table 18
that belong to a specific CL. The value of external capacitances CX1 and CX2 specified in
this table are calculated from the internal parasitic capacitances and the CL. Parasitics
from PCB and package are not taken into account.
14.4 XTAL and RTCX Printed Circuit Board (PCB) layout guidelines
The crystal should be connected on the PCB as close as possible to the oscillator input
and output pins of the chip. Take care that the load capacitors Cx1, Cx2, and Cx3 in case of
third overtone crystal usage have a common ground plane. The external components
must also be connected to the ground plain. Loops must be made as small as possible in
order to keep the noise coupled in via the PCB as small as possible. Also parasitics
should stay as small as possible. Values of Cx1 and Cx2 should be chosen smaller
accordingly to the increase in parasitics of the PCB layout.
Fig 22. RTC oscillator modes and models: oscillation mode of operation and external
crystal model used for CX1/CX2 evaluation
Table 18. Recommended values for the RTC external 32 kHz oscillator CX1/CX2 components
Crystal load capacitance
CL
Maximum crystal series
resistance RS
External load capacitors CX1/CX2
11 pF < 100 k 18 pF, 18 pF
13 pF < 100 k 22 pF, 22 pF
15 pF < 100 k 27 pF, 27 pF
002aaf495
LPC2xxx
RTCX1 RTCX2
CX1 CX2
32 kHz XTAL
= CL CP
RS
L
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NXP Semiconductors LPC2364/65/66/67/68
Single-chip 16-bit/32-bit microcontrollers
14.5 Standard I/O pin configuration
Figure 23 shows the possible pin modes for standard I/O pins with analog input function:
• Digital output driver
• Digital input: Pull-up enabled/disabled
• Digital input: Pull-down enabled/disabled
• Analog input (for ADC input channels)
The default configuration for standard I/O pins is input with pull-up enabled. The weak
MOS devices provide a drive capability equivalent to pull-up and pull-down resistors.
Fig 23. Standard I/O pin configuration with analog input
PIN
VDD
ESD
VSS
ESD
VDD
weak
pull-up
weak
pull-down
output enable
output
pull-up enable
pull-down enable
data input
analog input
select analog input
002aaf496
pin configured
as digital output
driver
pin configured
as digital input
pin configured
as analog input
LPC2364_65_66_67_68 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2013. All rights reserved.
Product data sheet Rev. 7.1 — 16 October 2013 60 of 69
NXP Semiconductors LPC2364/65/66/67/68
Single-chip 16-bit/32-bit microcontrollers
14.6 Reset pin configuration
Fig 24. Reset pin configuration
VSS
reset
002aaf274
VDD
VDD
VDD
Rpu ESD
ESD
20 ns RC
GLITCH FILTER PIN
LPC2364_65_66_67_68 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2013. All rights reserved.
Product data sheet Rev. 7.1 — 16 October 2013 61 of 69
NXP Semiconductors LPC2364/65/66/67/68
Single-chip 16-bit/32-bit microcontrollers
15. Package outline
Fig 25. Package outline SOT407-1 (LQFP100)
UNIT
A
max. A1 A2 A3 bp c E(1) e HE L Lp ywv Z θ
OUTLINE REFERENCES
VERSION
EUROPEAN
PROJECTION ISSUE DATE
IEC JEDEC JEITA
mm 1.6 0.15
0.05
1.45
1.35 0.25 0.27
0.17
0.20
0.09
14.1
13.9 0.5 16.25
15.75
1.15
0.85
7
0
o
1 0.2 0.08 0.08 o
DIMENSIONS (mm are the original dimensions)
Note
1. Plastic or metal protrusions of 0.25 mm maximum per side are not included.
0.75
0.45
SOT407-1 136E20 MS-026 00-02-01
03-02-20
D(1) (1)(1)
14.1
13.9
HD
16.25
15.75
Z E
1.15
0.85
D
bp
e
θ
E
A1
A
Lp
detail X
L
(A ) 3
B
25
c
DH
bp
EH A2
v M B
D
ZD
A
ZE
e
v M A
X
1
100
76
75 51
50
26
y
pin 1 index
w M
w M
0 5 10 mm
scale
LQFP100: plastic low profile quad flat package; 100 leads; body 14 x 14 x 1.4 mm SOT407-1
LPC2364_65_66_67_68 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2013. All rights reserved.
Product data sheet Rev. 7.1 — 16 October 2013 62 of 69
NXP Semiconductors LPC2364/65/66/67/68
Single-chip 16-bit/32-bit microcontrollers
Fig 26. Package outline SOT926-1 (TFBGA100)
OUTLINE REFERENCES
VERSION
EUROPEAN
PROJECTION ISSUE DATE
IEC JEDEC JEITA
SOT926-1 - - - - - - - - -
SOT926-1
05-12-09
05-12-22
UNIT A
max
mm 1.2 0.4
0.3
0.8
0.65
0.5
0.4
9.1
8.9
9.1
8.9
A1
DIMENSIONS (mm are the original dimensions)
TFBGA100: plastic thin fine-pitch ball grid array package; 100 balls; body 9 x 9 x 0.7 mm
A2 b D E e2
7.2
e
0.8
e1
7.2
v
0.15
w
0.05
y
0.08
y1
0.1
0 2.5 5 mm
scale
b
e2
e1
e
e
1/2 e
1/2 e
∅ v M AC B
∅ w M C
ball A1
index area
A
B
C
D
E
F
H
K
G
J
13579 2 4 6 8 10
ball A1
index area
B A
E
D
C
y1 C y
X
detail X
A
A1
A2
LPC2364_65_66_67_68 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2013. All rights reserved.
Product data sheet Rev. 7.1 — 16 October 2013 63 of 69
NXP Semiconductors LPC2364/65/66/67/68
Single-chip 16-bit/32-bit microcontrollers
16. Abbreviations
Table 19. Abbreviations
Acronym Description
ADC Analog-to-Digital Converter
AHB Advanced High-performance Bus
AMBA Advanced Microcontroller Bus Architecture
APB Advanced Peripheral Bus
BOD BrownOut Detection
CAN Controller Area Network
DAC Digital-to-Analog Converter
DCC Debug Communication Channel
DMA Direct Memory Access
DSP Digital Signal Processing
EOP End Of Packet
ETM Embedded Trace Macrocell
GPIO General Purpose Input/Output
IrDA Infrared Data Association
JTAG Joint Test Action Group
MII Media Independent Interface
MIIM Media Independent Interface Management
PHY Physical Layer
PLL Phase-Locked Loop
PWM Pulse Width Modulator
RMII Reduced Media Independent Interface
SE0 Single Ended Zero
SPI Serial Peripheral Interface
SSI Serial Synchronous Interface
SSP Synchronous Serial Port
TTL Transistor-Transistor Logic
UART Universal Asynchronous Receiver/Transmitter
USB Universal Serial Bus
LPC2364_65_66_67_68 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2013. All rights reserved.
Product data sheet Rev. 7.1 — 16 October 2013 64 of 69
NXP Semiconductors LPC2364/65/66/67/68
Single-chip 16-bit/32-bit microcontrollers
17. Revision history
Table 20. Revision history
Document ID Release date Data sheet status Change
notice
Supersedes
LPC2364_65_66_67_68 v.7.1 20131016 Product data sheet - LPC2364_65_66_67_68 v.7
Modifications: • Table 4 “Pin description”, Table note 6: Changed glitch filter spec from 5 ns to 10 ns.
• Table 9 “Dynamic characteristics”: Changed min clock cycle time from 42 to 40.
LPC2364_65_66_67_68 v.7 20111020 Product data sheet - LPC2364_65_66_67_68 v.6
Modifications: • Table 13 “Dynamic characteristics of flash”: Added characteristics for ter and tprog.
• Table 4 “Pin description”: Updated description for USB_UP_LED.
• Table 4 “Pin description”: Added Table note 12 “If the RTC is not used, these pins can
be left floating.” for RTCX1 and RTCX2 pins.
• Table 4 “Pin description”: Added Table note 8 “This pin has a built-in pull-up resistor.”
for DBGEN, TMS, TDI, TRST, and RTCK pins.
• Table 4 “Pin description”: Added Table note 7 “This pin has no built-in pull-up and no
built-in pull-down resistor.” for TCK and TDO pins.
• Table 5 “Limiting values”: Added “non-operating” to conditions column of Tstg.
• Table 5 “Limiting values”: Updated Table note 5 “The maximum non-operating
storage temperature is different than the temperature for required shelf life which
should be determined based on required shelf lifetime. Please refer to the JEDEC
spec (J-STD-033B.1) for further details.”.
• Table 5 “Limiting values”: Updated storage temperature min/max to 65/+150.
• Added Table 7 “Thermal resistance value (C/W): ±15 %”.
• Added Table 10 “Dynamic characteristic: internal oscillators”.
• Added Table 11 “Dynamic characteristic: I/O pins[1]”.
• Table 8 “Static characteristics”: Changed Vhys typ value from 0.5VDD(3V3) to
0.05VDD(3V3).
• Table 13 “Dynamic characteristics of flash”: Updated table.
• Added Section 9 “Thermal characteristics”.
• Added Section 10.3 “Electrical pin characteristics”.
• Added Section 14.2 “Crystal oscillator XTAL input and component selection”.
• Added Section 14.3 “RTC 32 kHz oscillator component selection”.
• Added Section 14.4 “XTAL and RTCX Printed Circuit Board (PCB) layout guidelines”.
• Added Section 14.5 “Standard I/O pin configuration”.
• Added Section 14.6 “Reset pin configuration”.
LPC2364_65_66_67_68 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2013. All rights reserved.
Product data sheet Rev. 7.1 — 16 October 2013 65 of 69
NXP Semiconductors LPC2364/65/66/67/68
Single-chip 16-bit/32-bit microcontrollers
LPC2364_65_66_67_68 v.6 20100201 Product data sheet - LPC2364_65_66_67_68 v.5
Modifications: • Table 5 “Limiting values”: Changed VESD min/max to 2500/+2500.
• Table 6: Updated min, typical and max values for oscillator pins.
• Table 6: Updated conditions and typical values for IDD(DCDC)pd(3V3), IBATact;
IDD(DCDC)dpd(3V3) and IBAT added.
• Table 9 “Dynamic characteristics of flash”: Changed flash endurance spec from
100000 to 10000 minimum cycles.
• Added Table 11 “DAC electrical characteristics”.
• Section 7.2 “On-chip flash programming memory”: Removed text regarding flash
endurance minimum specs.
• Added Section 7.24.4.4 “Deep power-down mode”.
• Section 7.25.2 “Brownout detection”: Changed VDD(3V3) to VDD(DCDC)(3V3).
• Added Section 9.2 “Deep power-down mode”.
• Added Section 13.2 “XTAL1 input”.
• Added Section 13.3 “XTAL and RTC Printed-Circuit Board (PCB) layout guidelines”.
• Added table note for XTAL1 and XTAL2 pins in Table 3.
LPC2364_65_66_67_68 v.5 20090409 Product data sheet - LPC2364_65_66_67_68 v.4
Modifications: • Added part LPC2364HBD100.
• Section 7.2: Added sentence clarifying SRAM speeds for LPC2364HBD.
• Table 5: Updated Vesd min/max.
• Table 6: Updated ZDRV Table note [14].
• Table 6: Vhys, moved 0.4 from typ to min column.
• Table 6: Ipu, added specs for >85 C.
• Table 6: Removed Rpu.
• Table 7: CCLK and IRC, added specs for >85 C.
• Added Table 9.
• Updated Figure 14.
• Updated Figure 11.
LPC2364_65_66_67_68 v.4 20080417 Product data sheet - LPC2364_66_68 v.3
LPC2364_66_68 v.3 20071220 Product data sheet - LPC2364_66_68 v.2
LPC2364_66_68 v.2 20071001 Preliminary data sheet - LPC2364_66_68 v.1
LPC2364_66_68 v.1 20070103 Preliminary data sheet - -
Table 20. Revision history …continued
Document ID Release date Data sheet status Change
notice
Supersedes
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Product data sheet Rev. 7.1 — 16 October 2013 66 of 69
NXP Semiconductors LPC2364/65/66/67/68
Single-chip 16-bit/32-bit microcontrollers
18. Legal information
18.1 Data sheet status
[1] Please consult the most recently issued document before initiating or completing a design.
[2] The term ‘short data sheet’ is explained in section “Definitions”.
[3] The product status of device(s) described in this document may have changed since this document was published and may differ in case of multiple devices. The latest product status
information is available on the Internet at URL http://www.nxp.com.
18.2 Definitions
Draft — The document is a draft version only. The content is still under
internal review and subject to formal approval, which may result in
modifications or additions. NXP Semiconductors does not give any
representations or warranties as to the accuracy or completeness of
information included herein and shall have no liability for the consequences of
use of such information.
Short data sheet — A short data sheet is an extract from a full data sheet
with the same product type number(s) and title. A short data sheet is intended
for quick reference only and should not be relied upon to contain detailed and
full information. For detailed and full information see the relevant full data
sheet, which is available on request via the local NXP Semiconductors sales
office. In case of any inconsistency or conflict with the short data sheet, the
full data sheet shall prevail.
Product specification — The information and data provided in a Product
data sheet shall define the specification of the product as agreed between
NXP Semiconductors and its customer, unless NXP Semiconductors and
customer have explicitly agreed otherwise in writing. In no event however,
shall an agreement be valid in which the NXP Semiconductors product is
deemed to offer functions and qualities beyond those described in the
Product data sheet.
18.3 Disclaimers
Limited warranty and liability — Information in this document is believed to
be accurate and reliable. However, NXP Semiconductors does not give any
representations or warranties, expressed or implied, as to the accuracy or
completeness of such information and shall have no liability for the
consequences of use of such information. NXP Semiconductors takes no
responsibility for the content in this document if provided by an information
source outside of NXP Semiconductors.
In no event shall NXP Semiconductors be liable for any indirect, incidental,
punitive, special or consequential damages (including - without limitation - lost
profits, lost savings, business interruption, costs related to the removal or
replacement of any products or rework charges) whether or not such
damages are based on tort (including negligence), warranty, breach of
contract or any other legal theory.
Notwithstanding any damages that customer might incur for any reason
whatsoever, NXP Semiconductors’ aggregate and cumulative liability towards
customer for the products described herein shall be limited in accordance
with the Terms and conditions of commercial sale of NXP Semiconductors.
Right to make changes — NXP Semiconductors reserves the right to make
changes to information published in this document, including without
limitation specifications and product descriptions, at any time and without
notice. This document supersedes and replaces all information supplied prior
to the publication hereof.
Suitability for use — NXP Semiconductors products are not designed,
authorized or warranted to be suitable for use in life support, life-critical or
safety-critical systems or equipment, nor in applications where failure or
malfunction of an NXP Semiconductors product can reasonably be expected
to result in personal injury, death or severe property or environmental
damage. NXP Semiconductors and its suppliers accept no liability for
inclusion and/or use of NXP Semiconductors products in such equipment or
applications and therefore such inclusion and/or use is at the customer’s own
risk.
Applications — Applications that are described herein for any of these
products are for illustrative purposes only. NXP Semiconductors makes no
representation or warranty that such applications will be suitable for the
specified use without further testing or modification.
Customers are responsible for the design and operation of their applications
and products using NXP Semiconductors products, and NXP Semiconductors
accepts no liability for any assistance with applications or customer product
design. It is customer’s sole responsibility to determine whether the NXP
Semiconductors product is suitable and fit for the customer’s applications and
products planned, as well as for the planned application and use of
customer’s third party customer(s). Customers should provide appropriate
design and operating safeguards to minimize the risks associated with their
applications and products.
NXP Semiconductors does not accept any liability related to any default,
damage, costs or problem which is based on any weakness or default in the
customer’s applications or products, or the application or use by customer’s
third party customer(s). Customer is responsible for doing all necessary
testing for the customer’s applications and products using NXP
Semiconductors products in order to avoid a default of the applications and
the products or of the application or use by customer’s third party
customer(s). NXP does not accept any liability in this respect.
Limiting values — Stress above one or more limiting values (as defined in
the Absolute Maximum Ratings System of IEC 60134) will cause permanent
damage to the device. Limiting values are stress ratings only and (proper)
operation of the device at these or any other conditions above those given in
the Recommended operating conditions section (if present) or the
Characteristics sections of this document is not warranted. Constant or
repeated exposure to limiting values will permanently and irreversibly affect
the quality and reliability of the device.
Terms and conditions of commercial sale — NXP Semiconductors
products are sold subject to the general terms and conditions of commercial
sale, as published at http://www.nxp.com/profile/terms, unless otherwise
agreed in a valid written individual agreement. In case an individual
agreement is concluded only the terms and conditions of the respective
agreement shall apply. NXP Semiconductors hereby expressly objects to
applying the customer’s general terms and conditions with regard to the
purchase of NXP Semiconductors products by customer.
No offer to sell or license — Nothing in this document may be interpreted or
construed as an offer to sell products that is open for acceptance or the grant,
conveyance or implication of any license under any copyrights, patents or
other industrial or intellectual property rights.
Document status[1][2] Product status[3] Definition
Objective [short] data sheet Development This document contains data from the objective specification for product development.
Preliminary [short] data sheet Qualification This document contains data from the preliminary specification.
Product [short] data sheet Production This document contains the product specification.
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Product data sheet Rev. 7.1 — 16 October 2013 67 of 69
NXP Semiconductors LPC2364/65/66/67/68
Single-chip 16-bit/32-bit microcontrollers
Export control — This document as well as the item(s) described herein
may be subject to export control regulations. Export might require a prior
authorization from competent authorities.
Non-automotive qualified products — Unless this data sheet expressly
states that this specific NXP Semiconductors product is automotive qualified,
the product is not suitable for automotive use. It is neither qualified nor tested
in accordance with automotive testing or application requirements. NXP
Semiconductors accepts no liability for inclusion and/or use of
non-automotive qualified products in automotive equipment or applications.
In the event that customer uses the product for design-in and use in
automotive applications to automotive specifications and standards, customer
(a) shall use the product without NXP Semiconductors’ warranty of the
product for such automotive applications, use and specifications, and (b)
whenever customer uses the product for automotive applications beyond
NXP Semiconductors’ specifications such use shall be solely at customer’s
own risk, and (c) customer fully indemnifies NXP Semiconductors for any
liability, damages or failed product claims resulting from customer design and
use of the product for automotive applications beyond NXP Semiconductors’
standard warranty and NXP Semiconductors’ product specifications.
18.4 Trademarks
Notice: All referenced brands, product names, service names and trademarks
are the property of their respective owners.
I
2C-bus — logo is a trademark of NXP B.V.
19. Contact information
For more information, please visit: http://www.nxp.com
For sales office addresses, please send an email to: salesaddresses@nxp.com
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Product data sheet Rev. 7.1 — 16 October 2013 68 of 69
continued >>
NXP Semiconductors LPC2364/65/66/67/68
Single-chip 16-bit/32-bit microcontrollers
20. Contents
1 General description . . . . . . . . . . . . . . . . . . . . . . 1
2 Features and benefits . . . . . . . . . . . . . . . . . . . . 1
3 Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
4 Ordering information. . . . . . . . . . . . . . . . . . . . . 3
4.1 Ordering options . . . . . . . . . . . . . . . . . . . . . . . . 4
5 Block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . 5
6 Pinning information. . . . . . . . . . . . . . . . . . . . . . 6
6.1 Pinning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
6.2 Pin description . . . . . . . . . . . . . . . . . . . . . . . . 10
7 Functional description . . . . . . . . . . . . . . . . . . 18
7.1 Architectural overview . . . . . . . . . . . . . . . . . . 18
7.2 On-chip flash programming memory . . . . . . . 19
7.3 On-chip SRAM . . . . . . . . . . . . . . . . . . . . . . . . 19
7.4 Memory map. . . . . . . . . . . . . . . . . . . . . . . . . . 19
7.5 Interrupt controller . . . . . . . . . . . . . . . . . . . . . 20
7.5.1 Interrupt sources. . . . . . . . . . . . . . . . . . . . . . . 21
7.6 Pin connect block . . . . . . . . . . . . . . . . . . . . . . 21
7.7 General purpose DMA controller . . . . . . . . . . 21
7.7.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
7.8 Fast general purpose parallel I/O . . . . . . . . . . 22
7.8.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
7.9 Ethernet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
7.9.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
7.10 USB interface (LPC2364/66/68 only) . . . . . . . 24
7.10.1 USB device controller . . . . . . . . . . . . . . . . . . . 24
7.10.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
7.11 CAN controller and acceptance filters
(LPC2364/66/68 only). . . . . . . . . . . . . . . . . . . 25
7.11.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
7.12 10-bit ADC . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
7.12.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
7.13 10-bit DAC . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
7.13.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
7.14 UARTs. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
7.14.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
7.15 SPI serial I/O controller. . . . . . . . . . . . . . . . . . 26
7.15.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
7.16 SSP serial I/O controller . . . . . . . . . . . . . . . . . 27
7.16.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
7.17 SD/MMC card interface (LPC2367/68 only) . . 27
7.17.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
7.18 I2C-bus serial I/O controllers. . . . . . . . . . . . . . 27
7.18.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
7.19 I2S-bus serial I/O controllers. . . . . . . . . . . . . . 28
7.19.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
7.20 General purpose 32-bit timers/external
event counters . . . . . . . . . . . . . . . . . . . . . . . . 29
7.20.1 Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
7.21 Pulse width modulator . . . . . . . . . . . . . . . . . . 29
7.21.1 Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
7.22 Watchdog timer . . . . . . . . . . . . . . . . . . . . . . . 30
7.22.1 Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
7.23 RTC and battery RAM . . . . . . . . . . . . . . . . . . 31
7.23.1 Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
7.24 Clocking and power control . . . . . . . . . . . . . . 31
7.24.1 Crystal oscillators. . . . . . . . . . . . . . . . . . . . . . 31
7.24.1.1 Internal RC oscillator . . . . . . . . . . . . . . . . . . . 32
7.24.1.2 Main oscillator . . . . . . . . . . . . . . . . . . . . . . . . 32
7.24.1.3 RTC oscillator . . . . . . . . . . . . . . . . . . . . . . . . 32
7.24.2 PLL. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
7.24.3 Wake-up timer . . . . . . . . . . . . . . . . . . . . . . . . 32
7.24.4 Power control . . . . . . . . . . . . . . . . . . . . . . . . . 33
7.24.4.1 Idle mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
7.24.4.2 Sleep mode . . . . . . . . . . . . . . . . . . . . . . . . . . 33
7.24.4.3 Power-down mode . . . . . . . . . . . . . . . . . . . . . 34
7.24.4.4 Deep power-down mode . . . . . . . . . . . . . . . . 34
7.24.4.5 Power domains . . . . . . . . . . . . . . . . . . . . . . . 34
7.25 System control . . . . . . . . . . . . . . . . . . . . . . . . 35
7.25.1 Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
7.25.2 Brownout detection . . . . . . . . . . . . . . . . . . . . 35
7.25.3 Code security
(Code Read Protection - CRP) . . . . . . . . . . . 36
7.25.4 AHB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
7.25.5 External interrupt inputs . . . . . . . . . . . . . . . . . 36
7.25.6 Memory mapping control . . . . . . . . . . . . . . . . 37
7.26 Emulation and debugging . . . . . . . . . . . . . . . 37
7.26.1 EmbeddedICE . . . . . . . . . . . . . . . . . . . . . . . . 37
7.26.2 Embedded trace. . . . . . . . . . . . . . . . . . . . . . . 37
7.26.3 RealMonitor . . . . . . . . . . . . . . . . . . . . . . . . . . 38
8 Limiting values . . . . . . . . . . . . . . . . . . . . . . . . 39
9 Thermal characteristics . . . . . . . . . . . . . . . . . 40
10 Static characteristics . . . . . . . . . . . . . . . . . . . 41
10.1 Power-down mode . . . . . . . . . . . . . . . . . . . . . 44
10.2 Deep power-down mode . . . . . . . . . . . . . . . . 45
10.3 Electrical pin characteristics. . . . . . . . . . . . . . 47
11 Dynamic characteristics. . . . . . . . . . . . . . . . . 48
11.1 Internal oscillators . . . . . . . . . . . . . . . . . . . . . 49
11.2 I/O pins. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
11.3 USB interface. . . . . . . . . . . . . . . . . . . . . . . . . 49
11.4 Flash memory . . . . . . . . . . . . . . . . . . . . . . . . 50
11.5 Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
12 ADC electrical characteristics . . . . . . . . . . . . 52
13 DAC electrical characteristics . . . . . . . . . . . . 55
14 Application information . . . . . . . . . . . . . . . . . 55
NXP Semiconductors LPC2364/65/66/67/68
Single-chip 16-bit/32-bit microcontrollers
© NXP B.V. 2013. All rights reserved.
For more information, please visit: http://www.nxp.com
For sales office addresses, please send an email to: salesaddresses@nxp.com
Date of release: 16 October 2013
Document identifier: LPC2364_65_66_67_68
Please be aware that important notices concerning this document and the product(s)
described herein, have been included in section ‘Legal information’.
14.1 Suggested USB interface solutions
(LPC2364/66/68 only). . . . . . . . . . . . . . . . . . . 55
14.2 Crystal oscillator XTAL input and component
selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
14.3 RTC 32 kHz oscillator component selection. . 58
14.4 XTAL and RTCX Printed Circuit Board
(PCB) layout guidelines . . . . . . . . . . . . . . . . . 58
14.5 Standard I/O pin configuration . . . . . . . . . . . . 59
14.6 Reset pin configuration. . . . . . . . . . . . . . . . . . 60
15 Package outline . . . . . . . . . . . . . . . . . . . . . . . . 61
16 Abbreviations. . . . . . . . . . . . . . . . . . . . . . . . . . 63
17 Revision history. . . . . . . . . . . . . . . . . . . . . . . . 64
18 Legal information. . . . . . . . . . . . . . . . . . . . . . . 66
18.1 Data sheet status . . . . . . . . . . . . . . . . . . . . . . 66
18.2 Definitions. . . . . . . . . . . . . . . . . . . . . . . . . . . . 66
18.3 Disclaimers . . . . . . . . . . . . . . . . . . . . . . . . . . . 66
18.4 Trademarks. . . . . . . . . . . . . . . . . . . . . . . . . . . 67
19 Contact information. . . . . . . . . . . . . . . . . . . . . 67
20 Contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
©2002 Fairchild Semiconductor Corporation
www.fairchildsemi.com
Rev. 1.0.1
Features
• 5V ±1% Reference
• Oscillator Sync Terminal
• Internal Soft Start
• Deadtime Control
• Under Voltage Lockout
Description
The KA3525A is a monolithic integrated circuit that
includes all of the control circuits necessary for a pulse width
modulating regulator. There are a voltage reference, an error
amplifier, a pulse width modulator, an oscillator, an under
voltage lockout, a soft start circuit, and the output driver in
the chip.
16-DIP
1
Internal Block Diagram
16
15
12
1
2
9
8
10
5
7
3 6 4
14
11
13
U.V.L.O. BAND GAP
REF 5V
LATCH
S R
F/F Q
Q 5K
VC
OUTPUT A
OUTPUT B
OSCILLATOR
DISCHARGE
5K
ERR
AMP
PWM
COMP
_
+
_
+
CT
VREF
VCC
GND
EA(-)
EA(+)
EAOUT
C
(SOFT
START)
SHUT DOWN
SYNC RT OSC
OUTPUT
KA3525A
SMPS Controller
KA3525A
2
Absolute Maximum Ratings
Electrical Characteristics
(VCC = 20V, TA = 0 to +70°C, unless otherwise specified)
Parameter Symbol Value Unit
Supply Voltage VCC 40 V
Collector Supply Voltage VC 40 V
Output Current, Sink or Source IO 500 mA
Reference Output Current IREF 50 mA
Oscillator Charging Current ICHG(OSC) 5 mA
Power Dissipation (TA = 25°C) PD 1000 m/W
Operating Temperature TOPR 0 ~ +70 °C
Storage Temperature TSTG -65 ~ +150 °C
Lead Temperature (Soldering, 10sec) TLEAD +300 °C
Parameter Symbol Conditions Min. Typ. Max. Unit
REFERENCE SECTION
Reference Output Voltage VREF TJ = 25°C 5.0 5.1 5.2 V
Line Regulation ∆VREF VCC = 8 to 35V - 9 20 mV
Load Regulation ∆VREF IREF = 0 to 20mA - 20 50 mV
Short Circuit Output Current ISC VREF = 0, TJ = 25°C - 80 100 mA
Total Output Variation (Note1) ∆VREF Line, Load and Temperature 4.95 - 5.25 V
Temperature Stability (Note1) STT - - 20 50 mV
Long Term Stability (Note1) ST TJ = 125°C ,1KHRS - 20 50 mV
OSCILLATOR SECTION
Initial Accuracy (Note1, 2) ACCUR TJ = 25°C - ±3 ±6 %
Frequency Change With Voltage ∆f/∆VCC VCC = 8 to 35V (Note1, 2) - ±0.8 ±2 %
Maximum Frequency f(MAX) RT = 2kΩ, CT = 470pF 400 430 - kHz
Minimum Frequency f(MIN) RT = 200kΩ, CT = 0.1uF - 60 120 Hz
Clock Amplitude (Note1, 2) V(CLK) - 34- V
Clock Width (Note1, 2) tW(CLK) TJ = 25°C 0.3 0.6 1 µs
Sync Threshold VTH(SYNC) - 1.2 2 2.8 V
Sync Input Current II(SYNC) Sync = 3.5V - 1.3 2.5 mA
KA3525A
3
Electrical Characteristics (Continued)
(VCC = 20V, TA = 0 to +70°C, unless otherwise specified)
Note :
1. These parameters. although guaranteed over the recommended operating conditions, are not 100% tested in production
2. Tested at fOSC=40kHz (RT =3.6K, CT =0.01uF, RI = 0Ω)
Parameter Symbol Conditions Min. Typ. Max. Unit
ERROR AMPLIFIER SECTION (VCM = 5.1V)
Input Offset Voltage VIO - - 1.5 10 mV
Input Bias Current IBIAS - - 1 10 µA
Input Offset Current IIO - - 0.1 1 µA
Open Loop Voltage Gain GVO RL ≥ 10MΩ 60 80 - dB
Common Mode Rejection Ratio CMRR VCM = 1.5 to 5.2V 60 90 - dB
Power Supply Rejection Ratio PSRR VCC = 8 to 3.5V 50 60 - dB
PWM COMPARATOR SECTION
Minimum Duty Cycle D(MIN) - - - 0%
Maximum Duty Cycle D(MAX) - 45 49 - %
Input Threshold Voltage (Note2) VTH1 Zero Duty Cycle 0.7 0.9 - V
Input Threshold Voltage (Note2) VTH2 Max Duty Cycle - 3.2 3.6 V
SOFT-START SECTION
Soft Start Current ISOFT VSD = 0V, VSS = 0V 25 51 80 µA
Soft Start Low Level Voltage VSL VSD = 25V - 0.3 0.7 V
Shutdown Threshold Voltage VTH(SD) - 0.9 1.3 1.7 V
Shutdown Input Current IN(SD) VSD = 2.5V - 0.3 1 mA
OUTPUT SECTION
Low Output Voltage I VOL I ISINK = 20mA - 0.1 0.4 V
Low Output Voltage II VOL II ISINK = 100mA - 0.05 2 V
High Output Voltage I VCH I ISOURCE = 20mA 18 19 - V
High Output Voltage II VCH II ISOURCE = 100mA 17 18 - V
Under Voltage Lockout VUV V8 and V9 = High 6 7 8 V
Collector Leakage Current ILKG VCC = 35V - 80 200 µA
Rise Time (Note1) tR CL = 1uF, TJ = 25°C - 80 600 ns
Fall Time (Note1) tF CL = 1uF, TJ = 25°C - 70 300 ns
STANDBY CURRENT
Supply Current ICC VCC = 35V - 12 20 mA
KA3525A
4
Test Circuit
16
15
12
1
2
9
8
10
5 7
13
11
14
3 6
BAND GAP
REF 5V U.V.L.O.
A
B
0.1
Vcc
0.1
3k
RWM
ADJ
10k
1.5K
10K
0.01
5.0uF
5.0k
5.0k
5.0k
100
F/F
ERR
AMP ERR
AMP
OSCILLATOR
LATCH
S
S R
SOFT START +
SHUTDOWN
VREF
CT
RAMP
0.009 0.1
+
3.6k
0.001
DEAD
TIME
OUT B
10k
10k
OUT A
VC
CLOCK
_
+
+
_
RT
KA3525A
5
Mechanical Dimensions
Package
#1
#8 #9
#16
6.40 ±0.20
7.62
0.300
2.54
0.100
0.252 ±0.008
0~15° 0.25 +0.10
–0.05
0.010 +0.004
–0.002
3.30 ±0.30
0.130 ±0.012
3.25 ±0.20
0.128 ±0.008 19.40 ±0.20 0.764 ±0.008
19.80
0.780 MAX
5.08
0.200
0.38
0.014
MAX
MIN
0.81
0.032 ( ) 0.46 ±0.10
0.018 ±0.004
0.059 ±0.004
1.50 ±0.10
16-DIP
KA3525A
10/2/02 0.0m 001
Stock#DSxxxxxxxx
2002 Fairchild Semiconductor Corporation
LIFE SUPPORT POLICY
FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES
OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR
CORPORATION. As used herein:
1. Life support devices or systems are devices or systems
which, (a) are intended for surgical implant into the body,
or (b) support or sustain life, and (c) whose failure to
perform when properly used in accordance with
instructions for use provided in the labeling, can be
reasonably expected to result in a significant injury of the
user.
2. A critical component in any component of a life support
device or system whose failure to perform can be
reasonably expected to cause the failure of the life support
device or system, or to affect its safety or effectiveness.
www.fairchildsemi.com
DISCLAIMER
FAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY
PRODUCTS HEREIN TO IMPROVE RELIABILITY, FUNCTION OR DESIGN. FAIRCHILD DOES NOT ASSUME ANY
LIABILITY ARISING OUT OF THE APPLICATION OR USE OF ANY PRODUCT OR CIRCUIT DESCRIBED HEREIN; NEITHER
DOES IT CONVEY ANY LICENSE UNDER ITS PATENT RIGHTS, NOR THE RIGHTS OF OTHERS.
Ordering Information
Product Number Package Operating Temperature
KA3525A 16-DIP 0 ~ +70°C
©2006 Fairchild Semiconductor Corporation
www.fairchildsemi.com
FPS Rev.1.0.6 TM is a trademark of Fairchild Semiconductor Corporation.
Features
• Internal Avalanche Rugged Sense FET
• Advanced Burst-Mode operation consumes under 1 W at
240VAC & 0.5W load
• Precision Fixed Operating Frequency (66kHz)
• Internal Start-up Circuit
• Improved Pulse by Pulse Current Limiting
• Over Voltage Protection (OVP)
• Over Load Protection (OLP)
• Internal Thermal Shutdown Function (TSD)
• Auto-Restart Mode
• Under Voltage Lock Out (UVLO) with hysteresis
• Low Operating Current (2.5mA)
• Built-in Soft Start
Application
• SMPS for LCD monitor and STB
• Adaptor
Description
The FSDM0565RB is an integrated Pulse Width Modulator
(PWM) and Sense FET specifically designed for high
performance offline Switch Mode Power Supplies (SMPS)
with minimal external components. This device is an
integrated high voltage power switching regulator which
combine an avalanche rugged Sense FET with a current mode
PWM control block. The PWM controller includes integrated
fixed frequency oscillator, under voltage lockout, leading edge
blanking (LEB), optimized gate driver, internal soft start,
temperature compensated precise current sources for a loop
compensation and self protection circuitry. Compared with
discrete MOSFET and PWM controller solution, it can reduce
total cost, component count, size and weight simultaneously
increasing efficiency, productivity, and system reliability. This
device is a basic platform well suited for cost effective
designs of flyback converters.
Table 1. Maximum Output Power
Notes:
1. Typical continuous power in a non-ventilated enclosed
adapter measured at 50°C ambient.
2. Maximum practical continuous power in an open frame
design at 50°C ambient.
3. 230 VAC or 100/115 VAC with doubler.
Typical Circuit
Figure 1. Typical Flyback Application
OUTPUT POWER TABLE
PRODUCT
230VAC ±15%(3) 85-265VAC
Adapter(1)
Open
Frame(2)
Adapter(1)
Open
Frame(2)
FSDM0565RB 60W 70W 50W 60W
FSDM0565RBI 60W 70W 50W 60W
FSDM07652RB 70W 80W 60W 70W
Drain
Source
Vstr
Vfb Vcc
PWM
AC
IN DC
OUT
FSDM0565RB
Green Mode Fairchild Power Switch (FPSTM)
FSDM0565RB
2
Internal Block Diagram
Figure 2. Functional Block Diagram of FSDM0565RB
8V/12V
3 1
2
4
5
Vref Internal
Bias
S
Q
Q
R
OSC
Vcc Vref
Idelay IFB
VSD
TSD
Vovp
Vcc
VCL
S
Q
Q
R
R
2.5R
Vcc good
Vcc Drain
N.C
FB
GND
Gate
driver
6
Vstr
Istart
Vcc good
0.5/0.7V
LEB
PWM
Soft start
+
-
FSDM0565RB
3
Pin Definitions
Pin Configuration
Figure 3. Pin Configuration (Top View)
Pin Number Pin Name Pin Function Description
1 Drain This pin is the high voltage power Sense FET drain. It is designed to drive the
transformer directly.
2 GND This pin is the control ground and the Sense FET source.
3 Vcc
This pin is the positive supply voltage input. During start up, the power is supplied
by an internal high voltage current source that is connected to the Vstr pin.
When Vcc reaches 12V, the internal high voltage current source is disabled and
the power is supplied from the auxiliary transformer winding.
4 Vfb
This pin is internally connected to the inverting input of the PWM comparator.
The collector of an opto-coupler is typically tied to this pin. For stable operation,
a capacitor should be placed between this pin and GND. If the voltage of this pin
reaches 6.0V, the over load protection is activated resulting in shutdown of the
FPSTM.
5 N.C -
6 Vstr
This pin is connected directly to the high voltage DC link. At startup, the internal
high voltage current source supplies internal bias and charges the external capacitor
that is connected to the Vcc pin. Once Vcc reaches 12V, the internal current
source is disabled.
6.Vstr
5.N.C.
4.Vfb
3.Vcc
2.GND
1.Drain
TO-220F-6L
6.Vstr
5.N.C.
4.Vfb
3.Vcc
2.GND
1.Drain
I2-PAK-6L
FSDM0565RB
4
Absolute Maximum Ratings
(Ta=25°C, unless otherwise specified)
Notes:
1. Repetitive rating: Pulse width limited by maximum junction temperature
2. L=14mH, starting Tj=25°C
3. L=13uH, starting Tj=25°C
Thermal Impedance
Notes:
1. Free standing with no heat-sink under natural convection.
2. Infinite cooling condition - Refer to the SEMI G30-88.
Parameter Symbol Value Unit
Drain-source voltage VDSS 650 V
Vstr Max Voltage VSTR 650 V
Pulsed Drain current (Tc=25°C)(1) IDM 11 ADC
Continuous Drain Current(Tc=25°C) ID
2.8 A
Continuous Drain Current(Tc=100°C) 1.7 A
Single pulsed avalanche energy (2) EAS 190 mJ
Single pulsed avalanche current (3) IAS - A
Supply voltage VCC 20 V
Input voltage range VFB -0.3 to VCC V
Total power dissipation(Tc=25°C) PD(Watt H/S)
45
(TO-220-6L) W
75
(I2-PAK-6L)
Operating junction temperature Tj Internally limited °C
Operating ambient temperature TA -25 to +85 °C
Storage temperature range TSTG -55 to +150 °C
ESD Capability, HBM Model (All pins
excepts for Vstr and Vfb)
- 2.0
(GND-Vstr/Vfb=1.5kV)
kV
ESD Capability, Machine Model (All pins
excepts for Vstr and Vfb)
- 300
(GND-Vstr/Vfb=225V)
V
Parameter Symbol Package Value Unit
Junction-to-Ambient Thermal θJA(1) TO-220F-6L 49.90 °C/W
I2-PAK-6L 30
Junction-to-Case Thermal θJC(2) TO-220F-6L 2.78 °C/W
I2-PAK-6L 1.67
FSDM0565RB
5
Electrical Characteristics
(Ta = 25°C unless otherwise specified)
Parameter Symbol Condition Min. Typ. Max. Unit
Sense FET SECTION
Drain source breakdown voltage BVDSS VGS = 0V, ID = 250μA 650 - - V
Zero gate voltage drain current IDSS
VDS = 650V, VGS = 0V - - 500 μA
VDS= 520V
VGS = 0V, TC = 125°C - - 500 μA
Static drain source on resistance (1) RDS(ON) VGS = 10V, ID = 2.5A - 1.76 2.2 Ω
Output capacitance COSS
VGS = 0V, VDS = 25V,
f = 1MHz - 78 - pF
Turn on delay time TD(ON) VDD= 325V, ID= 5A
(MOSFET switching
time is essentially
independent of
operating temperature)
- 22 -
ns
Rise time TR - 52 -
Turn off delay time TD(OFF) - 95 -
Fall time TF - 50 -
CONTROL SECTION
Initial frequency FOSC VFB = 3V 60 66 72 kHz
Voltage stability FSTABLE 13V ≤ Vcc ≤ 18V 0 1 3 %
Temperature stability (2) ΔFOSC -25°C ≤ Ta ≤ 85°C 0 ±5 ±10 %
Maximum duty cycle DMAX - 77 82 87 %
Minimum duty cycle DMIN - - - 0%
Start threshold voltage VSTART VFB=GND 11 12 13 V
Stop threshold voltage VSTOP VFB=GND 7 8 9 V
Feedback source current IFB VFB=GND 0.7 0.9 1.1 mA
Soft-start time TS Vfb=3 - 10 15 ms
Leading Edge Blanking time TLEB - - 250 - ns
BURST MODE SECTION
Burst Mode Voltages (2)
VBURH Vcc=14V - 0.7 - V
VBURL Vcc=14V - 0.5 - V
PROTECTION SECTION
Peak current limit (4) IOVER VFB=5V, VCC=14V 2.0 2.25 2.5 A
Over voltage protection VOVP - 18 19 20 V
Thermal shutdown temperature (2) TSD 130 145 160 °C
Shutdown feedback voltage VSD VFB ≥ 5.5V 5.5 6.0 6.5 V
Shutdown delay current IDELAY VFB=5V 2.8 3.5 4.2 μA
FSDM0565RB
6
Notes:
1. Pulse test : Pulse width ≤ 300μS, duty ≤ 2%
2. These parameters, although guaranteed at the design, are not tested in mass production.
3. These parameters, although guaranteed, are tested in EDS(wafer test) process.
4. These parameters indicate the inductor current.
5. This parameter is the current flowing into the control IC.
TOTAL DEVICE SECTION
Operating supply current (5)
IOP VFB=GND, VCC=14V
IOP(MIN) VFB=GND, VCC=10V - 2.5 5 mA
IOP(MAX) VFB=GND, VCC=18V
FSDM0565RB
7
Comparison Between FS6M07652RTC and FSDM0565RB
Function FS6M07652RTC FSDM0565RB FSDM0565RB Advantages
Soft-Start Adjustable soft-start
time using an
external capacitor
Internal soft-start with
typically 10ms (fixed)
• Gradually increasing current limit
during soft-start further reduces peak
current and voltage component
stresses
• Eliminates external components used
for soft-start in most applications
• Reduces or eliminates output
overshoot
Burst Mode Operation • Built into controller
• Output voltage
drops to around
half
• Built into controller
• Output voltage fixed
• Improve light load efficiency
• Reduces no-load consumption
FSDM0565RB
8
Typical Performance Characteristics
(These Characteristic Graphs are Normalized at Ta= 25°C)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-25 0 25 50 75 100 125 150
Junction Temperature(℃)
Operating Frequency
(Fosc)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-25 0 25 50 75 100 125 150
Junction Temperature(℃)
Start Thershold Voltage
(Vstart)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-25 0 25 50 75 100 125 150
Junction Temperature(℃)
Stop Threshold Voltage
(Vstop)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-25 0 25 50 75 100 125 150
Junction Temperature(℃)
Maximum Duty Cycle
(Dmax)
Operating Current vs. Temp Start Threshold Voltage vs. Temp
Stop Threshold Voltage vs. Temp Operating Freqency vs. Temp
Maximum Duty vs. Temp Feedback Source Current vs. Temp
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-25 0 25 50 75 100 125 150
Junction Temperature(℃)
Operating Current
(Iop)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-25 0 25 50 75 100 125 150
Junction Temperature(℃)
FB Source Current
(Ifb)
FSDM0565RB
9
Typical Performance Characteristics (Continued)
(These Characteristic Graphs are Normalized at Ta= 25°C)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-25 0 25 50 75 100 125 150
Junction Temperature(℃)
Shutdown Delay Current
(Idelay)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-25 0 25 50 75 100 125 150
Junction Temperature(℃)
Over Voltage Protection
(Vovp)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-50 -25 0 25 50 75 100 125
Junction Temperature(℃)
Peak Current Limit(Self protection)
(Iover)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-25 0 25 50 75 100 125 150
Junction Temperature(℃)
FB Burst Mode Enable Voltage
(Vfbe)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-25 0 25 50 75 100 125 150
Junction Temperature(℃)
FB Burst Mode Disable Voltage
(Vfbd)
ShutDown Feedback Voltage vs. Temp ShutDown Delay Current vs. Temp
Over Voltage Protection vs. Temp Burst Mode Enable Voltage vs. Temp
Burst Mode Disable Voltage vs. Temp Current Limit vs. Temp
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-25 0 25 50 75 100 125 150
Junction Temperature(℃)
Shutdown FB Voltage
(Vsd)
FSDM0565RB
10
Typical Performance Characteristics (Continued)
(These Characteristic Graphs are Normalized at Ta= 25°C)
Soft Start Time vs. Temp
0.0
0.2
0.4
0.6
0.8
1.0
1.2
-50 -25 0 25 50 75 100 125
Junction Temperature(℃)
Soft Start Time
(Normalized to 25℃)
FSDM0565RB
11
Functional Description
1. Startup : In previous generations of Fairchild Power
Switches (FPSTM) the Vcc pin had an external start-up
resistor to the DC input voltage line. In this generation the
startup resistor is replaced by an internal high voltage current
source. At startup, an internal high voltage current source
supplies the internal bias and charges the external capacitor
(Cvcc) that is connected to the Vcc pin as illustrated in
Figure 4. When Vcc reaches 12V, the FSDM0565RB begins
switching and the internal high voltage current source is
disabled. Then, the FSDM0565RB continues its normal
switching operation and the power is supplied from the
auxiliary transformer winding unless Vcc goes below the
stop voltage of 8V.
Figure 4. Internal startup circuit
2. Feedback Control : FSDM0565RB employs current
mode control, as shown in Figure 5. An opto-coupler (such
as the H11A817A) and shunt regulator (such as the KA431)
are typically used to implement the feedback network.
Comparing the feedback voltage with the voltage across the
Rsense resistor plus an offset voltage makes it possible to
control the switching duty cycle. When the reference pin
voltage of the KA431 exceeds the internal reference voltage
of 2.5V, the H11A817A LED current increases, thus pulling
down the feedback voltage and reducing the duty cycle. This
event typically happens when the input voltage is increased
or the output load is decreased.
2.1 Pulse-by-pulse current limit: Because current mode
control is employed, the peak current through the Sense FET
is limited by the inverting input of PWM comparator (Vfb*)
as shown in Figure 5. Assuming that the 0.9mA current
source flows only through the internal resistor (2.5R +R= 2.8
kΩ), the cathode voltage of diode D2 is about 2.5V. Since D1
is blocked when the feedback voltage (Vfb) exceeds 2.5V,
the maximum voltage of the cathode of D2 is clamped at this
voltage, thus clamping Vfb*. Therefore, the peak value of
the current through the Sense FET is limited.
2.2 Leading edge blanking (LEB) : At the instant the
internal Sense FET is turned on, there usually exists a high
current spike through the Sense FET, caused by primary-side
capacitance and secondary-side rectifier reverse recovery.
Excessive voltage across the Rsense resistor would lead to
incorrect feedback operation in the current mode PWM
control. To counter this effect, the FSDM0565RB employs a
leading edge blanking (LEB) circuit. This circuit inhibits the
PWM comparator for a short time (TLEB) after the Sense
FET is turned on.
Figure 5. Pulse width modulation (PWM) circuit
3. Protection Circuit : The FSDM0565RB has several self
protective functions such as over load protection (OLP), over
voltage protection (OVP) and thermal shutdown (TSD).
Because these protection circuits are fully integrated into the
IC without external components, the reliability can be
improved without increasing cost. Once the fault condition
occurs, switching is terminated and the Sense FET remains
off. This causes Vcc to fall. When Vcc reaches the UVLO
stop voltage, 8V, the protection is reset and the internal high
voltage current source charges the Vcc capacitor via the Vstr
pin. When Vcc reaches the UVLO start voltage,12V, the
FSDM0565RB resumes its normal operation. In this manner,
the auto-restart can alternately enable and disable the
switching of the power Sense FET until the fault condition is
eliminated (see Figure 6).
8V/12V
3
Vref
Internal
Bias
Vcc
6 Vstr
Istart
Vcc good
VDC
CVcc
4 OSC
Vcc Vref
Idelay IFB
VSD
R
2.5R
Gate
driver
OLP
D1 D2
+
Vfb*
-
Vfb
KA431
CB
Vo
H11A817A
Rsense
SenseFET
FSDM0565RB
12
Figure 6. Auto restart operation
3.1 Over Load Protection (OLP) : Overload is defined as
the load current exceeding a pre-set level due to an
unexpected event. In this situation, the protection circuit
should be activated in order to protect the SMPS. However,
even when the SMPS is in the normal operation, the over
load protection circuit can be activated during the load
transition. In order to avoid this undesired operation, the over
load protection circuit is designed to be activated after a
specified time to determine whether it is a transient situation
or an overload situation. Because of the pulse-by-pulse
current limit capability, the maximum peak current through
the Sense FET is limited, and therefore the maximum input
power is restricted with a given input voltage. If the output
consumes beyond this maximum power, the output voltage
(Vo) decreases below the set voltage. This reduces the
current through the opto-coupler LED, which also reduces
the opto-coupler transistor current, thus increasing the
feedback voltage (Vfb). If Vfb exceeds 2.5V, D1 is blocked
and the 3.5uA current source starts to charge CB slowly up to
Vcc. In this condition, Vfb continues increasing until it
reaches 6V, when the switching operation is terminated as
shown in Figure 7. The delay time for shutdown is the time
required to charge CB from 2.5V to 6.0V with 3.5uA. In
general, a 10 ~ 50 ms delay time is typical for most
applications.
Figure 7. Over load protection
3.2 Over voltage Protection (OVP) : If the secondary side
feedback circuit were to malfunction or a solder defect
caused an open in the feedback path, the current through the
opto-coupler transistor becomes almost zero. Then, Vfb
climbs up in a similar manner to the over load situation,
forcing the preset maximum current to be supplied to the
SMPS until the over load protection is activated. Because
more energy than required is provided to the output, the
output voltage may exceed the rated voltage before the over
load protection is activated, resulting in the breakdown of the
devices in the secondary side. In order to prevent this
situation, an over voltage protection (OVP) circuit is
employed. In general, Vcc is proportional to the output
voltage and the FSDM0565RB uses Vcc instead of directly
monitoring the output voltage. If VCC exceeds 19V, an OVP
circuit is activated resulting in the termination of the
switching operation. In order to avoid undesired activation of
OVP during normal operation, Vcc should be designed to be
below 19V.
3.3 Thermal Shutdown (TSD) : The Sense FET and the
control IC are built in one package. This makes it easy for
the control IC to detect the heat generation from the Sense
FET. When the temperature exceeds approximately 150°C,
the thermal shutdown is activated.
4. Soft Start : The FSDM0565RB has an internal soft start
circuit that increases PWM comparator inverting input
voltage together with the Sense FET current slowly after it
starts up. The typical soft start time is 10msec, The pulse
width to the power switching device is progressively
increased to establish the correct working conditions for
transformers, inductors, and capacitors. The voltage on the
output capacitors is progressively increased with the
intention of smoothly establishing the required output
voltage. It also helps to prevent transformer saturation and
reduce the stress on the secondary diode during startup.
Fault
situation
8V
12V
Vcc
Vds
t
Fault
occurs Fault
removed
Normal
operation
Normal
operation
Power
on
VFB
t
2.5V
6.0V
Over load protection
T12= Cfb*(6.0-2.5)/I delay
T1 T2
FSDM0565RB
13
5. Burst operation : In order to minimize power dissipation
in standby mode, the FSDM0565RB enters burst mode
operation. As the load decreases, the feedback voltage
decreases. As shown in Figure 8, the device automatically
enters burst mode when the feedback voltage drops below
VBURL(500mV). At this point switching stops and the
output voltages start to drop at a rate dependent on standby
current load. This causes the feedback voltage to rise. Once
it passes VBURH(700mV) switching resumes. The feedback
voltage then falls and the process repeats. Burst mode
operation alternately enables and disables switching of the
power Sense FET thereby reducing switching loss in
Standby mode.
Figure 8. Waveforms of burst operation
VFB
Vds
0.5V
0.7V
Ids
Vo
Voset
time
Switching
disabled
T1 T2 T3
Switching
disabled T4
FSDM0565RB
14
Typical application circuit
Features
• High efficiency (>81% at 85Vac input)
• Low zero load power consumption (<300mW at 240Vac input)
• Low standby mode power consumption (<800mW at 240Vac input and 0.3W load)
• Low component count
• Enhanced system reliability through various protection functions
• Internal soft-start (10ms)
Key Design Notes
• Resistors R102 and R105 are employed to prevent start-up at low input voltage. After startup, there is no power loss in these
resistors since the startup pin is internally disconnected after startup.
• The delay time for over load protection is designed to be about 50ms with C106 of 47nF. If a faster triggering of OLP is
required, C106 can be reduced to 10nF.
• Zener diode ZD102 is used for a safety test such as UL. When the drain pin and feedback pin are shorted, the zener diode
fails and remains short, which causes the fuse (F1) blown and prevents explosion of the opto-coupler (IC301). This zener
diode also increases the immunity against line surge.
1. Schematic
Application Output power Input voltage Output voltage (Max current)
LCD Monitor 40W Universal input
(85-265Vac)
5V (2.0A)
12V (2.5A)
3
4
C102
220nF
275VAC
LF101
23mH
C101
220nF
275VAC
RT1
5D-9
F1
FUSE
250V
2A
C103
100uF
400V
R102
30kΩ
R105
40kΩ
R103
56kΩ
2W
C104
2.2nF
1kV D101
UF 4007
C106
47nF
50V
C105
22uF
50V
D102
TVR10G
R104
5Ω
1
2
3
4
5
T1
EER3016
BD101
2KBP06M3N257
1
2
R101
560kΩ
1W
IC1
FSDM0565RB
Vstr
NC
Vfb
Vcc
Drain
GND
1
2
3 4
5
6
ZD101
22V
8
10
D202
MBRF10100
C201
1000uF
25V
C202
1000uF
25V
L201
12V, 2.5A
6
7
D201
MBRF1045
C203
1000uF
10V
C204
1000uF
10V
L202
5V, 2A
R201
1kΩ
R202
1.2kΩ
R204
5.6kΩ
R203
12kΩ C205
47nF
R205
5.6kΩ
C301
4.7nF
IC301
H11A817A IC201
KA431
ZD102
10V
FSDM0565RB
15
2. Transformer Schematic Diagram
3.Winding Specification
4.Electrical Characteristics
5. Core & Bobbin
Core : EER 3016
Bobbin : EER3016
Ae(mm2) : 96
No Pin (s→f) Wire Turns Winding Method
Na 4 → 5 0.2φ × 1 8 Center Winding
Insulation: Polyester Tape t = 0.050mm, 2Layers
Np/2 2 → 1 0.4φ × 1 18 Solenoid Winding
Insulation: Polyester Tape t = 0.050mm, 2Layers
N12V 10 → 8 0.3φ × 3 7 Center Winding
Insulation: Polyester Tape t = 0.050mm, 2Layers
N5V 7 → 6 0.3φ × 3 3 Center Winding
Insulation: Polyester Tape t = 0.050mm, 2Layers
Np/2 3 → 2 0.4φ × 1 18 Solenoid Winding
Outer Insulation: Polyester Tape t = 0.050mm, 2Layers
Pin Specification Remarks
Inductance 1 - 3 520uH ± 10% 100kHz, 1V
Leakage Inductance 1 - 3 10uH Max 2nd all short
EER3016
Np
/2 N12V
Na
1
2
3
4
5 6
7
8
9
10
Np
/2
N5V
FSDM0565RB
16
6.Demo Circuit Part List
Part Value Note Part Value Note
Fuse C301 4.7nF Polyester Film Cap.
F101 2A/250V
NTC Inductor
RT101 5D-9 L201 5uH Wire 1.2mm
Resistor L202 5uH Wire 1.2mm
R101 560K 1W
R102 30K 1/4W
R103 56K 2W
R104 5 1/4W Diode
R105 40K 1/4W D101 UF4007
R201 1K 1/4W D102 TVR10G
R202 1.2K 1/4W D201 MBRF1045
R203 12K 1/4W D202 MBRF10100
R204 5.6K 1/4W ZD101 Zener Diode 22V
R205 5.6K 1/4W ZD102 Zener Diode 10V
Bridge Diode
BD101 2KBP06M 3N257 Bridge Diode
Capacitor
C101 220nF/275VAC Box Capacitor Line Filter
C102 220nF/275VAC Box Capacitor LF101 23mH Wire 0.4mm
C103 100uF/400V Electrolytic Capacitor IC
C104 2.2nF/1kV Ceramic Capacitor IC101 FSDM0565RB FPSTM(5A,650V)
C105 22uF/50V Electrolytic Capacitor IC201 KA431(TL431) Voltage reference
C106 47nF/50V Ceramic Capacitor IC301 H11A817A Opto-coupler
C201 1000uF/25V Electrolytic Capacitor
C202 1000uF/25V Electrolytic Capacitor
C203 1000uF/10V Electrolytic Capacitor
C204 1000uF/10V Electrolytic Capacitor
C205 47nF/50V Ceramic Capacitor
FSDM0565RB
17
7. Layout
Figure 9. Layout Considerations for FSDM0565RB
Figure 10. Layout Considerations for FSDM0565RB
FSDM0565RB
18
Package Dimensions
TO-220F-6L(Forming)
FSDM0565RB
19
Package Dimensions (Continued)
I2-PAK-6L(Forming)
FSDM0565RB
1/9/06 0.0m 001
© 2006 Fairchild Semiconductor Corporation
LIFE SUPPORT POLICY
FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES
OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR
CORPORATION. As used herein:
1. Life support devices or systems are devices or systems
which, (a) are intended for surgical implant into the body,
or (b) support or sustain life, and (c) whose failure to
perform when properly used in accordance with
instructions for use provided in the labeling, can be
reasonably expected to result in a significant injury of the
user.
2. A critical component in any component of a life support
device or system whose failure to perform can be
reasonably expected to cause the failure of the life support
device or system, or to affect its safety or effectiveness.
www.fairchildsemi.com
DISCLAIMER
FAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY
PRODUCTS HEREIN TO IMPROVE RELIABILITY, FUNCTION OR DESIGN. FAIRCHILD DOES NOT ASSUME ANY
LIABILITY ARISING OUT OF THE APPLICATION OR USE OF ANY PRODUCT OR CIRCUIT DESCRIBED HEREIN; NEITHER
DOES IT CONVEY ANY LICENSE UNDER ITS PATENT RIGHTS, NOR THE RIGHTS OF OTHERS.
Ordering Information
WDTU : Forming Type
Product Number Package Marking Code BVdss Rds(on)Max.
FSDM0565RBWDTU TO-220F-6L(Forming) DM0565R 650V 2.2 Ω
FSDM0565RBIWDTU I2-PAK-6L (Forming) DM0565R 650V 2.2 Ω
Data Sheet: JN5148-001
IEEE802.15.4 Wireless Microcontroller
© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 1
Overview Features: Transceiver
• 2.4GHz IEEE802.15.4 compliant
• Time of Flight ranging engine
• 128-bit AES security processor
• MAC accelerator with packet
formatting, CRCs, address check,
auto-acks, timers
• 500 & 667kbps data rate modes
• Integrated sleep oscillator for low
power
• On chip power regulation for 2.0V
to 3.6V battery operation
• Deep sleep current 100nA
• Sleep current with active sleep
timer 1.25µA
• <$0.50 external component cost
• Rx current 17.5mA
• Tx current 15.0mA
• Receiver sensitivity -95dBm
• Transmit power 2.5dBm
Features: Microcontroller
• Low power 32-bit RISC CPU, 4 to
32MHz clock speed
• Variable instruction width for high
coding efficiency
• Multi-stage instruction pipeline
• 128kB ROM and 128kB RAM for
bootloaded program code & data
• JTAG debug interface
• 4-input 12-bit ADC, 2 12-bit
DACs, 2 comparators
• 3 application timer/counters,
• 2 UARTs
• SPI port with 5 selects
• 2-wire serial interface
• 4-wire digital audio interface
• Watchdog timer
• Low power pulse counters
• Up to 21 DIO
Industrial temp (-40°C to +85°C)
8x8mm 56-lead Punched QFN
Lead-free and RoHS compliant
The JN5148-001 is an ultra low power, high performance wireless
microcontroller targeted at JenNet and ZigBee PRO networking
applications. The device features an enhanced 32-bit RISC processor
offering high coding efficiency through variable width instructions, a multistage
instruction pipeline and low power operation with programmable clock
speeds. It also includes a 2.4GHz IEEE802.15.4 compliant transceiver,
128kB of ROM, 128kB of RAM, and a rich mix of analogue and digital
peripherals. The large memory footprint allows the device to run both a
network stack (e.g. ZigBee PRO) and an embedded application or in a coprocessor
mode. The operating current is below 18mA, allowing operation
direct from a coin cell.
Enhanced peripherals include low power pulse counters running in sleep
mode designed for pulse counting in AMR applications and a unique Time
of Flight ranging engine, allowing accurate location services to be
implemented on wireless sensor networks. It also includes a 4-wire I2
S
audio interface, to interface directly to mainstream audio CODECs, as well
as conventional MCU peripherals.
Block Diagram
32-bit
RISC CPU Timers
UAR Ts
12-bit ADC,
Comparators
12-bit DACs,
Temp Sensor
2-Wire Serial
RAM SPI 128kB
128-bit AES
Encryption
Accelerator
2.4GHz
Radio
ROM
128kB
Power
Management
XTAL
O-QPSK
Modem
IEEE802.15.4
MAC
Accelerator
32-byte
OTP eFuse
4-Wire Audio
Sleep Counters
Time of Flight
Engine
Watchdog
Timer
Benefits
• Single chip integrates
transceiver and
microcontroller for wireless
sensor networks
• Large memory footprint to
run ZigBee PRO or JenNet
together with an application
• Very low current solution for
long battery life
• Highly featured 32-bit RISC
CPU for high performance
and low power
• System BOM is low in
component count and cost
• Extensive user peripherals
Applications
• Robust and secure low power
wireless applications
• ZigBee PRO and JenNet
networks
• Smart metering
(e.g. AMR)
• Home and commercial building
automation
• Location Aware services – e.g.
Asset Tracking
• Industrial systems
• Telemetry
• Remote Control
• Toys and gaming peripherals2 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
Contents
1 Introduction 6
1.1 Wireless Transceiver 6
1.2 RISC CPU and Memory 6
1.3 Peripherals 7
1.4 Block Diagram 8
2 Pin Configurations 9
2.1 Pin Assignment 10
2.2 Pin Descriptions 12
2.2.1 Power Supplies 12
2.2.2 Reset 12
2.2.3 32MHz Oscillator 12
2.2.4 Radio 12
2.2.5 Analogue Peripherals 13
2.2.6 Digital Input/Output 13
3 CPU 15
4 Memory Organisation 16
4.1 ROM 16
4.2 RAM 17
4.3 OTP eFuse Memory 17
4.4 External Memory 17
4.4.1 External Memory Encryption 18
4.5 Peripherals 18
4.6 Unused Memory Addresses 18
5 System Clocks 19
5.1 16MHz System Clock 19
5.1.1 32MHz Oscillator 19
5.1.2 24MHz RC Oscillator 19
5.2 32kHz System Clock 20
5.2.1 32kHz RC Oscillator 20
5.2.2 32kHz Crystal Oscillator 20
5.2.3 32kHz External Clock 20
6 Reset 21
6.1 Internal Power-on Reset 21
6.2 External Reset 22
6.3 Software Reset 22
6.4 Brown-out Detect 23
6.5 Watchdog Timer 23
7 Interrupt System 24
7.1 System Calls 24
7.2 Processor Exceptions 24
7.2.1 Bus Error 24
7.2.2 Alignment 24
7.2.3 Illegal Instruction 24
7.2.4 Stack Overflow 24
7.3 Hardware Interrupts 25© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 3
8 Wireless Transceiver 26
8.1 Radio 26
8.1.1 Radio External Components 27
8.1.2 Antenna Diversity 27
8.2 Modem 29
8.3 Baseband Processor 30
8.3.1 Transmit 30
8.3.2 Reception 30
8.3.3 Auto Acknowledge 31
8.3.4 Beacon Generation 31
8.3.5 Security 31
8.4 Security Coprocessor 31
8.5 Location Awareness 31
8.6 Higher Data Rates 32
9 Digital Input/Output 33
10 Serial Peripheral Interface 35
11 Timers 38
11.1 Peripheral Timer/Counters 38
11.1.1 Pulse Width Modulation Mode 39
11.1.2 Capture Mode 39
11.1.3 Counter/Timer Mode 40
11.1.4 Delta-Sigma Mode 40
11.1.5 Example Timer / Counter Application 41
11.2 Tick Timer 41
11.3 Wakeup Timers 42
11.3.1 RC Oscillator Calibration 43
12 Pulse Counters 44
13 Serial Communications 45
13.1 Interrupts 46
13.2 UART Application 46
14 JTAG Debug Interface 47
15 Two-Wire Serial Interface 48
15.1 Connecting Devices 48
15.2 Clock Stretching 49
15.3 Master Two-wire Serial Interface 49
15.4 Slave Two-wire Serial Interface 50
16 Four-Wire Digital Audio Interface 51
17 Random Number Generator 53
18 Sample FIFO 54
19 Intelligent Peripheral Interface 55
19.1 Data Transfer Format 55
19.2 JN5148 (Slave) Initiated Data Transfer 56
19.3 Remote (Master) Processor Initiated Data Transfer 564 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
20 Analogue Peripherals 58
20.1 Analogue to Digital Converter 59
20.1.1 Operation 59
20.1.2 Supply Monitor 60
20.1.3 Temperature Sensor 60
20.2 Digital to Analogue Converter 60
20.2.1 Operation 60
20.3 Comparators 61
21 Power Management and Sleep Modes 62
21.1 Operating Modes 62
21.1.1 Power Domains 62
21.2 Active Processing Mode 62
21.2.1 CPU Doze 62
21.3 Sleep Mode 62
21.3.1 Wakeup Timer Event 63
21.3.2 DIO Event 63
21.3.3 Comparator Event 63
21.3.4 Pulse Counter 63
21.4 Deep Sleep Mode 63
22 Electrical Characteristics 64
22.1 Maximum Ratings 64
22.2 DC Electrical Characteristics 64
22.2.1 Operating Conditions 64
22.2.2 DC Current Consumption 65
22.2.3 I/O Characteristics 66
22.3 AC Characteristics 66
22.3.1 Reset and Voltage Brown-Out 66
22.3.2 SPI MasterTiming 68
22.3.3 Intelligent Peripheral (SPI Slave) Timing 68
22.3.4 Two-wire Serial Interface 69
22.3.5 Four-Wire Digital Audio Interface 70
22.3.6 Wakeup and Boot Load Timings 70
22.3.7 Bandgap Reference 71
22.3.8 Analogue to Digital Converters 71
22.3.9 Digital to Analogue Converters 72
22.3.10 Comparators 73
22.3.11 32kHz RC Oscillator 73
22.3.12 32kHz Crystal Oscillator 74
22.3.13 32MHz Crystal Oscillator 74
22.3.14 24MHz RC Oscillator 75
22.3.15 Temperature Sensor 75
22.3.16 Radio Transceiver 76© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 5
Appendix A Mechanical and Ordering Information 81
A.1 56-pin QFN Package Drawing 81
A.2 PCB Decal 82
A.3 Ordering Information 83
A.4 Device Package Marking 84
A.5 Tape and Reel Information 85
A.5.1 Tape Orientation and Dimensions 85
A.5.2 Reel Information: 180mm Reel 86
A.5.3 Reel Information: 330mm Reel 87
A.5.4 Dry Pack Requirement for Moisture Sensitive Material 87
Appendix B Development Support 88
B.1 Crystal Oscillators 88
B.1.1 Crystal Equivalent Circuit 88
B.1.2 Crystal Load Capacitance 88
B.1.3 Crystal ESR and Required Transconductance 89
B.2 32MHz Oscillator 90
B.3 32kHz Oscillator 92
B.4 JN5148 Module Reference Designs 94
B.4.1 Schematic Diagram 94
B.4.2 PCB Design and Reflow Profile 96
Related Documents 97
RoHS Compliance 97
Status Information 97
Disclaimers 98
Trademarks 98
Version Control 99
Contact Details 1006 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
1 Introduction
The JN5148-001 is an IEEE802.15.4 wireless microcontroller that provides a fully integrated solution for applications
using the IEEE802.15.4 standard in the 2.4 - 2.5GHz ISM frequency band [1], including JenNet and ZigBee PRO. It
includes all of the functionality required to meet the IEEE802.15.4, JenNet and ZigBee PRO specifications and has
additional processor capability to run a wide range of applications including, but not limited to Smart Energy,
Automatic Meter Reading, Remote Control, Home and Building Automation, Toys and Gaming.
Applications that transfer data wirelessly tend to be more complex than wired ones. Wireless protocols make
stringent demands on frequencies, data formats, timing of data transfers, security and other issues. Application
development must consider the requirements of the wireless network in addition to the product functionality and user
interfaces. To minimise this complexity, NXP provides a series of software libraries and interfaces that control the
transceiver and peripherals of the JN5148. These libraries and interfaces remove the need for the developer to
understand wireless protocols and greatly simplifies the programming complexities of power modes, interrupts and
hardware functionality.
In view of the above, the register details of the JN5148 are not provided in the datasheet.
The device includes a Wireless Transceiver, RISC CPU, on chip memory and an extensive range of peripherals.
Hereafter, the JN5148-001 will be referred to as JN5148.
1.1 Wireless Transceiver
The Wireless Transceiver comprises a 2.45GHz radio, a modem, a baseband controller and a security coprocessor.
In addition, the radio also provides an output to control transmit-receive switching of external devices such as power
amplifiers allowing applications that require increased transmit power to be realised very easily. Appendix B.4,
describes a complete reference design including Printed Circuit Board (PCB) design and Bill Of Materials (BOM).
The security coprocessor provides hardware-based 128-bit AES-CCM* modes as specified by the IEEE802.15.4
2006 standard. Specifically this includes encryption and authentication covered by the MIC –32/ -64/ -128, ENC and
ENC-MIC –32/ -64/ -128 modes of operation.
The transceiver elements (radio, modem and baseband) work together to provide IEEE802.15.4 Medium Access
Control (MAC) under the control of a protocol stack. Applications incorporating IEEE802.15.4 functionality can be
rapidly developed by combining user-developed application software with a protocol stack library.
1.2 RISC CPU and Memory
A 32-bit RISC CPU allows software to be run on chip, its processing power being shared between the IEEE802.15.4
MAC protocol, other higher layer protocols and the user application. The JN5148 has a unified memory architecture,
code memory, data memory, peripheral devices and I/O ports are organised within the same linear address space.
The device contains 128kbytes of ROM, 128kbytes of RAM and a 32-byte One Time Programmable (OTP) eFuse
memory. © NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 7
1.3 Peripherals
The following peripherals are available on chip:
• Master SPI port with five select outputs
• Two UARTs with support for hardware or software flow control
• Three programmable Timer/Counters – all three support Pulse Width Modulation (PWM) capability, two have
capture/compare facility
• Two programmable Sleep Timers and a Tick Timer
• Two-wire serial interface (compatible with SMbus and I2
C) supporting master and slave operation
• Four-wire digital audio interface (compatible with I²S)
• Slave SPI port for Intelligent peripheral mode (shared with digital I/O)
• Twenty-one digital I/O lines (multiplexed with peripherals such as timers and UARTs)
• Four channel, 12-bit, Analogue to Digital converter
• Two 12-bit Digital to Analogue converters
• Two programmable analogue comparators
• Internal temperature sensor and battery monitor
• Time Of Flight ranging engine
• Two low power pulse counters
• Random number generator
• Watchdog Timer and Voltage Brown-out
• Sample FIFO for digital audio interface or ADC/DAC
• JTAG hardware debug port
User applications access the peripherals using the Integrated Peripherals API. This allows applications to use a
tested and easily understood view of the peripherals allowing rapid system development. 8 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
1.4 Block Diagram
32-bit RISC CPU
Reset
SPI
Master
MUX
UART0
UART1
Wakeup
Timer1
Wakeup
Timer0
Security
Coprocessor
DIO6/TXD0/JTAG_TDO
DIO7/RXD0/JTAG_TDI
DIO4/CTS0/JTAG_TCK
DIO5/RTS0/JTAG_TMS
DIO19/TXD1/JTAG_TDO
DIO17/CTS1/IP_SEL/DAI_SCK/
JTAG_TCK
DIO18/RTS1/IP_INT/DAI_SDOUT/
JTAG_TMS
Digital
Baseband
Radio
Programmable
Interrupt
Controller
Timer0
2-wire
Interf ace
Timer1
SPICLK
DIO10/TIM0OUT/32KXTALOUT
SPIMOSI
SPIMISO
SPISEL0
DIO0/SPISEL1
DIO3/SPISEL4/RFTX
DIO2/SPISEL3/RFRX
DIO1/SPISEL2/PC0
DIO9/TIM0CAP/32KXTALIN/32KIN
DIO8/TIM0CK_GT/PC1
DIO13/TIM1OUT/ADE/DAI_SDIN
DIO11/TIM1CK_GT/TIM2OUT
DIO12/TIM1CAP/ADO/DAI_WS
DIO14/SIF_CLK/IP_CLK
DIO15/SIF_D/IP_DO
DIO16/RXD1/IP_DI/JTAG_TDI
From Peripherals
RESETN
Wireless
Transceiv er
32MHz Clock
Generator
XTAL_IN
XTAL_OUT
RF_IN
VCOTUNE
Tick Timer
Voltage
Regulators 1.8V VDD1
VDD2
Intelligent
Peripheral
IBAIS
VB_XX
Clock Divider
Multiplier
Timer2
SPISEL1
SPISEL2
SPISEL3
SPISEL4
TXD0
RXD0
RTS0
CTS0
TXD1
RXD1
RTS1
CTS1
TIM0CK_GT
TIM0CAP
TIM0OUT
TIM1CK_GT
TIM1CAP
TIM1OUT
TIM2OUT
SIF_D
SIF_CLK
IP_DO
IP_DI
IP_INT
IP_CLK
IP_SEL
4-wire
Digital
Audio
Interf ace
I2S_OUT
I2S_DIN
I2S_CLK
I2S_SYNC
Pulse
Counters
PC0
PC1
JTAG
Debug
JTAG_TDI
JTAG_TMS
JTAG_TCK
JTAG_TDO
RAM
128kB
ROM
128kB
OTP
eFuse
32kHz
RC
Osc
32kHz Clock
Select 32KIN
32kHz
Clock
Gen
32KXTALIN
32KXTALOUT
Antenna
Div ersity
ADO
ADE
Time
Of
Flight
Sample
FIFO
DIO20/RXD1/JTAG_TDI
24MHz
RC Osc
Comparator2 COMP2P
COMP2M
COMP1P/ Comparator1
EXT_PA_C
COMP1M/
EXT_PA_B
DAC1
DAC2
DAC1
DAC2
ADC
M
U ADC4 X
ADC1
ADC2
ADC3
Temperature
Sensor
Supply Monitor
CPU and 16MHz
System Clock
Watchdog
Timer
Brown-out
Detect
Figure 1: JN5148 Block Diagram
DIO 16/IP_DI© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 9
2 Pin Configurations
DIO16/RXD 1/IP_DI/JTAG_TDI
DIO17/CTS1/IP_SEL/DAI_SC K/JTAG_TCK
VSS3
DIO18/RTS1/IP_INT/DAI_SDOUT/JTAG_TMS
DIO19/TXD1/JTAG_TDO
VSS2
VSSS
XTAL_OUT
XTAL_IN
VB_SYNTH
VCOTUNE
VB_VCO
VDD1
IBIAS
VREF
VB_RF2
RF_IN
VB_RF
COMP1M
COMP1P
ADC1
ADC2
ADC3
ADC4
COMP2M
COMP2P
VB_A
NC
DAC1
DAC2
DIO20/RXD 1/JTAG_TDI
VSS1
SPICLK
SPIMISO
VB_RAM
SPIMOSI
SPISEL0
DIO0/SPISEL1
RESETN
VB_DIG
DIO1/SPISEL2/PC0
DIO2/SPISEL3/RFRX
DIO15/SIF_D/IP_DO
DIO14/SIF_C LK/IP_CLK
DIO13/T IM1OUT/ADE/DAI_SDIN
DIO12/T IM1CAP/ADO/DAI_WS
DIO11/T IM1CK_GT /TIM2OUT
DIO10/T IM0OUT/32KXT ALOUT
DIO9/TIM0CAP/32KXT ALIN/32KIN
VDD2
DIO8/TIM0CK_GT/PC 1
DIO7/RXD0/JT AG_TDI
DIO6/TXD0/JTAG_TDO
DIO5/RTS0/JTAG_TMS
DIO4/CTS0/JTAG_TCK
DIO3/SPISEL4/RFTX
VSSA
(Paddl e)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28 29
30
31
32
33
34
35
36
37
38
39
40
41
42
56
55
54
53
52
51
50
49
48
47
46
45
44
43
Figure 2: 56-pin QFN Configuration (top view)
Note: Please refer to Appendix B.4 JN5148 Module Reference
Design for important applications information regarding the
connection of the PADDLE to the PCB.
DIO 16/IP_DI10 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
2.1 Pin Assignment
Pin No Power supplies Signal
Type
Description
10, 12, 16, 18, 27,
35, 40
VB_SYNTH, VB_VCO, VB_RF2, VB_RF, VB_A, VB_RAM,
VB_DIG
1.8V Regulated supply voltage
13, 49 VDD1, VDD2 3.3V Supplies: VDD1 for analogue,
VDD2 for digital
32, 6, 3, 7, Paddle VSS1, VSS2, VSS3, VSSS, VSSA 0V Grounds (see appendix A.2 for
paddle details)
28 NC No connect
General
39 RESETN CMOS Reset input
8, 9 XTAL_OUT, XTAL_IN 1.8V System crystal oscillator
Radio
11 VCOTUNE 1.8V VCO tuning RC network
14 IBIAS 1.8V Bias current control
17 RF_IN 1.8V RF antenna
Analogue Peripheral I/O
21, 22, 23, 24 ADC1, ADC2, ADC3, ADC4 3.3V ADC inputs
15 VREF 1.8V Analogue peripheral reference
voltage
29, 30 DAC1, DAC2 3.3V DAC outputs
19, 20 COMP1M/EXT_PA_B, COMP1P/EXT_PA_C 3.3V Comparator 1 inputs and
external PA control
25, 26 COMP2M, COMP2P 3.3V Comparator 2 inputs
Digital Peripheral I/O
Primary Alternate Functions
33 SPICLK CMOS SPI Clock Output
36 SPIMOSI CMOS SPI Master Out Slave In Output
34 SPIMISO CMOS SPI Master In Slave Out Input
37 SPISEL0 CMOS SPI Slave Select Output 0
38 DIO0 SPISEL1 CMOS DIO0 or SPI Slave Select Output
1
41 DIO1 SPISEL2 PC0 CMOS DIO1, SPI Slave Select Output 2
or Pulse Counter0 Input
42 DIO2 SPISEL3 RFRX CMOS DIO2, SPI Slave Select Output 3
or Radio Receive Control Output
43 DIO3 SPISEL4 RFTX CMOS DIO3, SPI Slave Select Output 4
or Radio Transmit Control Output
44 DIO4 CTS0 JTAG_TCK CMOS DIO4, UART 0 Clear To Send
Input or JTAG CLK
45 DIO5 RTS0 JTAG_TMS CMOS DIO5, UART 0 Request To Send
Output or JTAG Mode Select
46 DIO6 TXD0 JTAG_TDO CMOS DIO6, UART 0 Transmit Data
Output or JTAG Data Output
47 DIO7 RXD0 JTAG_TDI CMOS DIO7, UART 0 Receive Data
Input or JTAG Data Input
48 DIO8 TIM0CK_GT PC1 CMOS DIO8, Timer0 Clock/Gate Input
or Pulse Counter1 Input
50 DIO9 TIM0CAP 32KXTALIN 32KIN CMOS DIO9, Timer0 Capture Input, 32K
External Crystal Input or 32K
Clock Input© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 11
Pin
No
Digital Peripheral I/O Signal
Type
Description
Primary Alternate Functions
51 DIO10 TIM0OUT 32KXTALOUT CMOS DIO10, Timer0 PWM Output or
32K External Crystal Output
52 DIO11 TIM1CK_GT TIM2OUT CMOS DIO11, Timer1 Clock/Gate
Input or Timer2 PWM Output
53 DIO12 TIM1CAP ADO DAI_WS CMOS DIO12, Timer1 Capture Input,
Antenna Diversity or Digital
Audio Word Select
54 DIO13 TIM1OUT ADE DAI_SDIN CMOS DIO13, Timer1 PWM Output,
Antenna Diversity or Digital
Audio Data Input
55 DIO14 SIF_CLK IP_CLK CMOS DIO14, Serial Interface Clock
or Intelligent Peripheral Clock
Input
56 DIO15 SIF_D IP_DO CMOS DIO15, Serial Interface Data or
Intelligent Peripheral Data Out
1 DIO16 IP_DI CMOS DIO16 or Intelligent Peripheral
Data In
2 DIO17 CTS1 IP_SEL DAI_SCK JTAG_TCK CMOS DIO17, UART 1 Clear To Send
Input, Intelligent Peripheral
Device Select Input or Digital
Audio Clock or JTAG CLK
4 DIO18 RTS1 IP_INT DAI_SDOUT JTAG_TMS CMOS DIO18, UART 1 Request To
Send Output, Intelligent
Peripheral Interrupt Output or
Digital Audio Data Output or
JTAG Mode Select
5 DIO19 TXD1 JTAG_TDO CMOS DIO19 or UART 1 Transmit
Data Output or JTAG Data Out
31 DIO 20 RXD1 JTAG_TDI CMOS DIO 20, UART 1 Receive Data
Input or JTAG data In
The PCB schematic and layout rules detailed in Appendix B.4
must be followed. Failure to do so will likely result in the
JN5148 failing to meet the performance specification detailed
herein and worst case may result in device not functioning in
the end application.12 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
2.2 Pin Descriptions
2.2.1 Power Supplies
The device is powered from the VDD1 and VDD2 pins, each being decoupled with a 100nF ceramic capacitor. VDD1
is the power supply to the analogue circuitry; it should be decoupled to ground. VDD2 is the power supply for the
digital circuitry; and should also be decoupled to ground. A 10uF tantalum capacitor is required. Decoupling pins for
the internal 1.8V regulators are provided which require a 100nF capacitor located as close to the device as practical.
VB_RF, VB_A and VB_SYNTH should be decoupled with an additional 47pF capacitor, while VB_RAM and VB_DIG
require only 100nF. VB_RF and VB_RF2 should be connected together as close to the device as practical, and only
require one 100nF capacitor and one 47pF capacitor. The pin VB_VCO requires a 10nF capacitor in parallel with a
47pF capacitor. Refer to B.4.1 for schematic diagram.
VSSA, VSSS, VSS1, VSS2, VSS3 are the ground pins.
Users are strongly discouraged from connecting their own circuits to the 1.8v regulated supply pins, as the regulators
have been optimised to supply only enough current for the internal circuits.
2.2.2 Reset
RESETN is a bi-directional active low reset pin that is connected to a 40kΩ internal pull-up resistor. It may be pulled
low by an external circuit, or can be driven low by the JN5148 if an internal reset is generated. Typically, it will be
used to provide a system reset signal. Refer to section 6.2, External Reset, for more details.
2.2.3 32MHz Oscillator
A crystal is connected between XTALIN and XTALOUT to form the reference oscillator, which drives the system
clock. A capacitor to analogue ground is required on each of these pins. Refer to section 5.1 16MHz System Clock
for more details. The 32MHz reference frequency is divided down to 16MHz and this is used as the system clock
throughout the device.
2.2.4 Radio
The radio is a single ended design, requiring a capacitor and just two inductors to match to 50Ω microstrip line to the
RF_IN pin.
An external resistor (43kΩ) is required between IBIAS and analogue ground to set various bias currents and
references within the radio.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 13
2.2.5 Analogue Peripherals
Several of the analogue peripherals require a reference voltage to use as part of their operations. They can use
either an internal reference voltage or an external reference connected to VREF. This voltage is referenced to
analogue ground and the performance of the analogue peripherals is dependant on the quality of this reference.
There are four ADC inputs, two pairs of comparator inputs and two DAC outputs. The analogue I/O pins on the
JN5148 can have signals applied up to 0.3v higher than VDD1. A schematic view of the analogue I/O cell is shown in
Figure 3: Analogue I/O Cell
In reset and deep sleep, the analogue peripherals are all off and the DAC outputs are in a high impedance state.
In sleep, the ADC and DACs are off, with the DAC outputs in high impedance state. The comparators may optionally
be used as a wakeup source.
Unused ADC and comparator inputs should be left unconnected.
VDD1
Analogue
I/O Pin
VSSA
Analogue
Peripheral
Figure 3: Analogue I/O Cell
2.2.6 Digital Input/Output
Digital I/O pins on the JN5148 can have signals applied up to 2V higher than VDD2 (with the exception of pins DIO9
and DIO10 that are 3V tolerant) and are therefore TTL-compatible with VDD2 > 3V. For other DC properties of these
pins see section 22.2.3 I/O Characteristics.
When used in their primary function all Digital Input/Output pins are bi-directional and are connected to weak internal
pull up resistors (40kΩ nominal) that can be disabled. When used in their secondary function (selected when the
appropriate peripheral block is enabled through software library calls) then their direction is fixed by the function. The
pull up resistor is enabled or disabled independently of the function and direction; the default state from reset is
enabled.
A schematic view of the digital I/O cell is in Figure 4: DIO Pin Equivalent Schematic.14 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
I
O
IE
VDD2
VSS
Pu
RPU
RPROT
OE
DIO[x] Pin
Figure 4: DIO Pin Equivalent Schematic
In reset, the digital peripherals are all off and the DIO pins are set as high-impedance inputs. During sleep and deep
sleep, the DIO pins retain both their input/output state and output level that was set as sleep commences. If the DIO
pins were enabled as inputs and the interrupts were enabled then these pins may be used to wake up the JN5148
from sleep.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 15
3 CPU
The CPU of the JN5148 is a 32-bit load and store RISC processor. It has been architected for three key
requirements:
• Low power consumption for battery powered applications
• High performance to implement a wireless protocol at the same time as complex applications
• Efficient coding of high-level languages such as C provided with the NXP Software Developer’s Kit
It features a linear 32-bit logical address space with unified memory architecture, accessing both code and data in the
same address space. Registers for peripheral units, such as the timers, UARTs and the baseband processor are
also mapped into this space.
The CPU has access to a block of 15 32-bit General-Purpose (GP) registers together with a small number of special
purpose registers which are used to store processor state and control interrupt handling. The contents of any GP
register can be loaded from or stored to memory, while arithmetic and logical operations, shift and rotate operations,
and signed and unsigned comparisons can be performed either between two registers and stored in a third, or
between registers and a constant carried in the instruction. Operations between general or special-purpose registers
execute in one cycle while those that access memory require a further cycle to allow the memory to respond.
The instruction set manipulates 8, 16 and 32-bit data; this means that programs can use objects of these sizes very
efficiently. Manipulation of 32-bit quantities is particularly useful for protocols and high-end applications allowing
algorithms to be implemented in fewer instructions than on smaller word-size processors, and to execute in fewer
clock cycles. In addition, the CPU supports hardware Multiply that can be used to efficiently implement algorithms
needed by Digital Signal Processing applications.
The instruction set is designed for the efficient implementation of high-level languages such as C. Access to fields in
complex data structures is very efficient due to the provision of several addressing modes, together with the ability to
be able to use any of the GP registers to contain the address of objects. Subroutine parameter passing is also made
more efficient by using GP registers rather than pushing objects onto the stack. The recommended programming
method for the JN5148 is by using C, which is supported by a software developer kit comprising a C compiler, linker
and debugger.
The CPU architecture also contains features that make the processor suitable for embedded, real-time applications.
In some applications, it may be necessary to use a real-time operating system to allow multiple tasks to run on the
processor. To provide protection for device-wide resources being altered by one task and affecting another, the
processor can run in either supervisor or user mode, the former allowing access to all processor registers, while the
latter only allows the GP registers to be manipulated. Supervisor mode is entered on reset or interrupt; tasks starting
up would normally run in user mode in a RTOS environment.
Embedded applications require efficient handling of external hardware events. When using JenOS, prioritised
interrupts are supported, with 15 priority levels, and can be configured as required by the application.
To improve power consumption a number of power-saving modes are implemented in the JN5148, described more
fully in section 21 - Power Management and Sleep Modes. One of these modes is the CPU doze mode; under
software control, the processor can be shut down and on an interrupt it will wake up to service the request.
Additionally, it is possible under software control, to set the speed of the CPU to 4, 8, 16 or 32MHz. This feature can
be used to trade-off processing power against current consumption.16 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
4 Memory Organisation
This section describes the different memories found within the JN5148. The device contains ROM, RAM, OTP eFuse
memory, the wireless transceiver and peripherals all within the same linear address space.
0x00000000
0x00020000
RAM
(128kB)
0xF0000000
0xFFFFFFFF
Unpopulated
ROM
(128kB)
0xF0020000
RAM Echo
0x04000000
Peripherals
0x02000000
Figure 5: JN5148 Memory Map
4.1 ROM
The ROM is 128k bytes in size, and can be accessed by the processor in a single CPU clock cycle. The ROM
contents include bootloader to allow external Flash memory contents to be bootloaded into RAM at runtime, a default
interrupt vector table, an interrupt manager, IEEE802.15.4 MAC and APIs for interfacing on-chip peripherals. The
operation of the boot loader is described in detail in Application Note [7]. The interrupt manager routes interrupt calls
to the application’s soft interrupt vector table contained within RAM. Section 7 contains further information regarding
the handling of interrupts. ROM contents are shown in Figure 6.
Interrupt Vectors
Interrupt Manager
Boot Loader
IEEE802.15.4
Stack
0x00000000
0x00020000
APIs
Spare
Figure 6: Typical ROM contents© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 17
4.2 RAM
The JN5148 contains 128kBytes of high speed RAM. It can be used for both code and data storage and is accessed
by the CPU in a single clock cycle. At reset, a boot loader controls the loading of segments of code and data from an
external memory connected to the SPI port, into RAM. Software can control the power supply to the RAM allowing
the contents to be maintained during a sleep period when other parts of the device are un-powered. Typical RAM
contents are shown in Figure 7.
MAC Data
Interrupt Vector Table
Application
CPU Stack
(Grows Down)
0x04000000
0x04020000
MAC Address
Figure 7: Typical RAM Contents
4.3 OTP eFuse Memory
The JN5148 contains a total of 32bytes of eFuse memory; this is a One Time Programmable (OTP) memory that can
be used to support on chip 64-bit MAC ID and a 128-bit AES security key. A limited number of bits are available for
customer use for storage of configuration information; configuration of these is made through use of software APIs.
For further information on how to program and use the eFuse memory, please contact technical support via the online
tech-support system.
Alternatively, NXP can provide an eFuse programming service for customers that wish to use the eFuse but do not
wish to undertake this for themselves. For further details of this service, please contact your local NXP sales office.
4.4 External Memory
An external memory with an SPI interface may be used to provide storage for program code and data for the device
when external power is removed. The memory is connected to the SPI interface using select line SPISEL0; this
select line is dedicated to the external memory interface and is not available for use with other external devices. See
Figure 8 for connection details.
JN5148 Serial
Memory
SPISEL0
SPIMISO
SPIMOSI
SPICLK
SS
SDO
SDI
CLK
Figure 8: Connecting External Serial Memory18 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
At reset, the contents of this memory are copied into RAM by the software boot loader. The Flash memory devices
that are supported as standard through the JN5148 bootloader are given in Table 1. NXP recommends that where
possible one of these devices should be selected.
Manufacturer Device Number
SST (Silicon Storage Technology) 25VF010A (1Mbit device)
Numonyx M25P10-A (1Mbit device),
M25P40 (4Mbit device)
Table 1: Supported Flash Memories
Applications wishing to use an alternate Flash memory device should refer to application note [2] JN-AN-1038
Programming Flash devices not supported by the JN51xx ROM-based bootloader. This application note provides
guidance on developing an interface to an alternate device.
4.4.1 External Memory Encryption
The contents of the external serial memory may be encrypted. The AES security processor combined with a user
programmable 128-bit encryption key is used to encrypt the contents of the external memory. The encryption key is
stored in eFuse.
When bootloading program code from external serial memory, the JN5148 automatically accesses the encryption key
to execute the decryption process. User program code does not need to handle any of the decryption process; it is
transparent.
With encryption enabled, the time taken to boot code from external flash is increased.
4.5 Peripherals
All peripherals have their registers mapped into the memory space. Access to these registers requires 3 clock
cycles. Applications have access to the peripherals through the software libraries that present a high-level view of
the peripheral’s functions through a series of dedicated software routines. These routines provide both a tested
method for using the peripherals and allow bug-free application code to be developed more rapidly. For details, see
the JN51xx Integrated Peripherals API User Guide (JN-UG-3066)[5].
4.6 Unused Memory Addresses
Any attempt to access an unpopulated memory area will result in a bus error exception (interrupt) being generated.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 19
5 System Clocks
Two system clocks are used to provide timing references into the on-chip subsystems of the JN5148. A 16MHz clock,
generated by a crystal-controlled 32MHz oscillator, is used by the transceiver, processor, memory and digital and
analogue peripherals. A 32kHz clock is used by the sleep timer and during the startup phase of the chip.
5.1 16MHz System Clock
The 16MHz system clock is used by the digital and analogue peripherals and the transceiver. A scaled version
(4,8,16 or 32MHz) of this clock is also used by the processor and memories. For most operations it is necessary to
source this clock from the 32MHz oscillator.
Crystal oscillators are generally slow to start. Hence to provide a faster start-up following a sleep cycle a fast RC
oscillator is provided that can be used as the source for the 16MHz system clock. The oscillator starts very quickly
and is typically 24MHz causing the system clock to run at 12MHz. Using a clock of this speed scales down the speed
of the processor and any peripherals in use. For the SPI interface this causes no functional issues as the generated
SPI clock is slightly slower and is used to clock the external SPI slave. Use of the radio is not possible when using the
24MHz RC oscillator. Additionally, timers and UARTs should not be used as the exact frequency will not be known.
The JN5148 device can be configured to wake up from sleep using the fast RC oscillator and automatically switch
over to use the 32MHz xtal as the clock source, when it has started up. This could allow application code to be
downloaded from the flash before the xtal is ready, typically improving start-up time by 550usec. Alternatively, the
switch over can be controlled by software, or the system could always use the 32MHz oscillator as the clock source.
5.1.1 32MHz Oscillator
The JN5148 contains the necessary on chip components to build a 32MHz reference oscillator with the addition of an
external crystal resonator and two tuning capacitors. The schematic of these components are shown in Figure 9.
The two capacitors, C1 and C2, should typically be 15pF and use a COG dielectric. Due to the small size of these
capacitors, it is important to keep the traces to the external components as short as possible. The on chip
transconductance amplifier is compensated for temperature variation, and is self-biasing by means of the internal
resistor R1. The electrical specification of the oscillator can be found in section 22.3.13. Please refer to Appendix B
for development support with the crystal oscillator circuit.
XTALOUT
C1 C2
R1 XTALIN
JN5148
Figure 9: 32MHz Crystal Oscillator Connections
5.1.2 24MHz RC Oscillator
An on-chip 24MHz RC oscillator is provided. No external components are required for this oscillator. The electrical
specification of the oscillator can be found in section 22.3.14.20 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
5.2 32kHz System Clock
The 32kHz system clock is used for timing the length of a sleep period (see section 21 Power Management and
Sleep Modes) and also to generate the system clock used internally during reset. The clock can be selected from
one of three sources through the application software:
• 32kHz RC Oscillator
• 32kHz Crystal Oscillator
• 32kHz External Clock
Upon a chip reset or power-up the JN5148 defaults to using the internal 32kHz RC Oscillator. If another clock source
is selected then it will remain in use for all 32kHz timing until a chip reset is performed.
5.2.1 32kHz RC Oscillator
The internal 32kHz RC oscillator requires no external components. The internal timing components of the oscillator
have a wide tolerance due to manufacturing process variation and so the oscillator runs nominally at 32kHz ±30%. To
make this useful as a timing source for accurate wakeup from sleep, a frequency calibration factor derived from the
more accurate 16MHz clock may be applied. The calibration factor is derived through software, details can be found
in section 11.3.1. For detailed electrical specifications, see section 22.3.11.
5.2.2 32kHz Crystal Oscillator
In order to obtain more accurate sleep periods, the JN5148 contains the necessary on-chip components to build a
32kHz oscillator with the addition of an external 32.768kHz crystal and two tuning capacitors. The crystal should be
connected between 32KXTALIN and 32KXTALOUT (DIO9 and DIO10), with two equal capacitors to ground, one on
each pin. Due to the small size of the capacitors, it is important to keep the traces to the external components as
short as possible.
The electrical specification of the oscillator can be found in section 22.3.12. The oscillator cell is flexible and can
operate with a range of commonly available 32.768kHz crystals with load capacitances from 6 to 12.5pF. However,
the maximum ESR of the crystal and the supply current are both functions of the actual crystal used, see appendix
B.1 for more details.
32KXTALIN 32KXTALOUT
JN5148
Figure 10: 32kHz crystal oscillator connections
5.2.3 32kHz External Clock
An externally supplied 32kHz reference clock on the 32KIN input (DIO9) may be provided to the JN5148. This would
allow the 32kHz system clock to be sourced from a very stable external oscillator module, allowing more accurate
sleep cycle timings compared to the internal RC oscillator. (See section 22.2.3 I/O Characteristics, DIO9 is a 3V
tolerant input)© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 21
6 Reset
A system reset initialises the device to a pre-defined state and forces the CPU to start program execution from the
reset vector. The reset process that the JN5148 goes through is as follows.
When power is applied, the 32kHz RC oscillator starts up and stabilises, which takes approximately 100µsec. At this
point, the 32MHz crystal oscillator is enabled and power is applied to the processor and peripheral logic. The logic
blocks are held in reset until the 32MHz crystal oscillator stabilises, typically this takes 0.75ms. Then the internal
reset is removed from the CPU and peripheral logic and the CPU starts to run code beginning at the reset vector,
consisting of initialisation code and the resident boot loader. [7] Section 22.3.1 provides detailed electrical data and
timing.
The JN5148 has five sources of reset:
• Internal Power-on Reset
• External Reset
• Software Reset
• Watchdog timer
• Brown-out detect
Note: When the device exits a reset condition, device operating
parameters (voltage, frequency, temperature, etc.) must be met to ensure
operation. If these conditions are not met, then the device must be held in
reset until the operating conditions are met. (See section 22.3)
6.1 Internal Power-on Reset
For the majority of applications the internal power-on reset is capable of generating the required reset signal. When
power is applied to the device, the power-on reset circuit monitors the rise of the VDD supply. When the VDD
reaches the specified threshold, the reset signal is generated and can be observed as a rising edge on the RESETN
pin. This signal is held internally until the power supply and oscillator stabilisation time has elapsed, when the internal
reset signal is then removed and the CPU is allowed to run.
RESETN Pin
Internal RESET
VDD
Figure 11: Internal Power-on Reset
When the supply drops below the power on reset ‘falling’ threshold, it will re-trigger the reset. Use of the external
reset circuit show in Figure 12 is suggested. 22 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
RESETN
C1
R1
JN5148
VDD
18k
470nF
Figure 12: External Reset Generation
The external resistor and capacitor provide a simple reset operation when connected to the RESETN pin.
6.2 External Reset
An external reset is generated by a low level on the RESETN pin. Reset pulses longer than the minimum pulse width
will generate a reset during active or sleep modes. Shorter pulses are not guaranteed to generate a reset. The
JN5148 is held in reset while the RESETN pin is low. When the applied signal reaches the Reset Threshold Voltage
(VRST) on its positive edge, the internal reset process starts.
Multiple devices may connect to the RESETN pin in an open-collector mode. The JN5148 has an internal pull-up
resistor connect to the RESETN pin. The pin is an input for an external reset, an output during the power-on reset
and may optionally be an output during a software reset. No devices should drive the RESETN pin high.
Internal Reset
RESETN pin
Reset
Figure 13: External Reset
6.3 Software Reset
A system reset can be triggered at any time through software control, causing a full chip reset and invalidating the
RAM contents. For example this can be executed within a user’s application upon detection of a system failure. When
performing the reset, the RESETN pin is driven low for 1µsec; depending on the external components this may or
may not be visible on the pin.
In addition, the RESETN line can be driven low by the JN5148 to provide a reset to other devices in the system (e.g.
external sensors) without resetting itself. When the RESETN line is not driven it will pull back high through either the
internal pull-up resistor or any external circuitry. It is essential to ensure that the RESETN line pulls back high within
100µsec after the JN5148 stops driving the line; otherwise a system reset will occur. Due to this, careful consideration
should be taken of any capacitance on this line. For instance, the RC values recommended in section 6.1 may need
to be replaced with a suitable reset IC© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 23
6.4 Brown-out Detect
An internal brown-out detect module is used to monitor the supply voltage to the JN5148; this can be used whilst the
device is awake or is in CPU doze mode. Dips in the supply voltage below a variable threshold can be detected and
can be used to cause the JN5148 to perform a chip reset. Equally, dips in the supply voltage can be detected and
used to cause an interrupt to the processor, when the voltage either drops below the threshold or rises above it.
The brown-out detect is enabled by default from power-up and can extend the reset during power-up. This will keep
the CPU in reset until the voltage exceeds the brown-out threshold voltage. The threshold voltage is configurable to
2.0V, 2.3V, 2.7V and 3.0V and is controllable by software. From power-up the threshold is set by eFuse settings and
the default chip configuration is for the 2.3V threshold. It is recommended that the threshold is set so that, as a
minimum, the chip is held in reset until the voltage reaches the level required by the external memory device on the
SPI interface.
6.5 Watchdog Timer
A watchdog timer is provided to guard against software lockups. It operates by counting cycles of the 32kHz system
clock. A pre-scaler is provided to allow the expiry period to be set between typically 8ms and 16.4 seconds. Failure
to restart the watchdog timer within the pre-configured timer period will cause a chip reset to be performed. A status
bit is set if the watchdog was triggered so that the software can differentiate watchdog initiated resets from other
resets, and can perform any required recovery once it restarts. If the source of the 32kHz system clock is the 32kHz
RC oscillator then the watchdog expiry periods are subject to the variation in period of the RC oscillator.
After power up, reset, start from deep sleep or start from sleep, the watchdog is always enabled with the largest
timeout period and will commence counting as if it had just been restarted. Under software control the watchdog can
be disabled. If it is enabled, the user must regularly restart the watchdog timer to stop it from expiring and causing a
reset. The watchdog runs continuously, even during doze, however the watchdog does not operate during sleep or
deep sleep, or when the hardware debugger has taken control of the CPU. It will recommence automatically if
enabled once the debugger un-stalls the CPU. 24 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
7 Interrupt System
The interrupt system on the JN5148 is a hardware-vectored interrupt system. The JN5148 provides several interrupt
sources, some associated with CPU operations (CPU exceptions) and others which are used by hardware in the
device. When an interrupt occurs, the CPU stops executing the current program and loads its program counter with a
fixed hardware address specific to that interrupt. The interrupt handler or interrupt service routine is stored at this
location and is run on the next CPU cycle. Execution of interrupt service routines is always performed in supervisor
mode. Interrupt sources and their vector locations are listed in Table 2 below:
Interrupt Source Vector Location Interrupt Definition
Bus error 0x08 Typically cause by an attempt to access an invalid address or a
disabled peripheral
Tick timer 0x0e Tick timer interrupt asserted
Alignment error 0x14 Load/store address to non-naturally-aligned location
Illegal instruction 0x1a Attempt to execute an unrecognised instruction
Hardware interrupt 0x20 interrupt asserted
System call 0x26 System call initiated by b.sys instruction
Trap 0x2c caused by the b.trap instruction or the debug unit
Reset 0x38 Caused by software or hardware reset.
Stack Overflow 0x3e Stack overflow
Table 2: Interrupt Vectors
7.1 System Calls
The b.trap and b.sys instructions allow processor exceptions to be generated by software.
A system call exception will be generated when the b.sys instruction is executed. This exception can, for example, be
used to enable a task to switch the processor into supervisor mode when a real time operating system is in use. (See
section 3 for further details.)
The b.trap instruction is commonly used for trapping errors and for debugging.
7.2 Processor Exceptions
7.2.1 Bus Error
A bus error exception is generated when software attempts to access a memory address that does not exist, or is not
populated with memory or peripheral registers or when writing to ROM.
7.2.2 Alignment
Alignment exceptions are generated when software attempts to access objects that are not aligned to natural word
boundaries. 16-bit objects must be stored on even byte boundaries, while 32-bit objects must be stored on quad byte
boundaries. For instance, attempting to read a 16-bit object from address 0xFFF1 will trigger an alignment exception
as will a read of a 32-bit object from 0xFFF1, 0xFFF2 or 0xFFF3. Examples of legal 32-bit object addresses are
0xFFF0, 0xFFF4, 0xFFF8 etc.
7.2.3 Illegal Instruction
If the CPU reads an unrecognised instruction from memory as part of its instruction fetch, it will cause an illegal
instruction exception.
7.2.4 Stack Overflow
When enabled, a stack overflow exception occurs if the stack pointer reaches a programmable location.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 25
7.3 Hardware Interrupts
Hardware interrupts generated from the transceiver, analogue or digital peripherals and DIO pins are individually
masked using the Programmable Interrupt Controller (PIC). Management of interrupts is provided in the peripherals
library [5]. For details of the interrupts generated from each peripheral see the respective section in this datasheet.
Interrupts can be used to wake the JN5148 from sleep. The peripherals, baseband controller, security coprocessor
and PIC are powered down during sleep but the DIO interrupts and optionally the pulse counters, wake-up timers and
analogue comparator interrupts remain powered to bring the JN5148 out of sleep.
Prioritised external interrupt handling (i.e., interrupts from hardware peripherals) is provided to enable an application
to control an events priority to provide for deterministic program execution.
The priority Interrupt controller provides 15 levels of prioritised interrupts. The priority level of all interrupts can be set,
with value 0 being used to indicate that the source can never produce an external interrupt, 1 for the lowest priority
source(s) and 15 for the highest priority source(s). Note that multiple interrupt sources can be assigned the same
priority level if desired.
If while processing an interrupt, a new event occurs at the same or lower priority level, a new external interrupt will
not be triggered. However, if a new higher priority event occurs, the external interrupt will again be asserted,
interrupting the current interrupt service routine.
Once the interrupt service routine is complete, lower priority events can be serviced. 26 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
8 Wireless Transceiver
The wireless transceiver comprises a 2.45GHz radio, modem, a baseband processor, a security coprocessor and
PHY controller. These blocks, with protocol software provided as a library, implement an IEEE802.15.4 standardsbased
wireless transceiver that transmits and receives data over the air in the unlicensed 2.4GHz band.
8.1 Radio
Figure 14 shows the single ended radio architecture.
LNA
synth
PA
ADC Reference
& Bias
Switch
Radio
Calibration
Lim1
Lim2
Lim3
Lim4
sigma
delta
D-Type
Figure 14: Radio Architecture
The radio comprises a low-IF receive path and a direct modulation transmit path, which converge at the TX/RX
switch. The switch connects to the external single ended matching network, which consists of two inductors and a
capacitor, this arrangement creates a 50Ω port and removes the need for a balun. A 50Ω single ended antenna can
be connected directly to this port.
The 32MHz crystal oscillator feeds a divider, which provides the frequency synthesiser with a reference frequency.
The synthesiser contains programmable feedback dividers, phase detector, charge pump and internal Voltage
Controlled Oscillator (VCO). The VCO has no external components, and includes calibration circuitry to compensate
for differences in internal component values due to process and temperature variations. The VCO is controlled by a
Phase Locked Loop (PLL) that has an internal loop filter. A programmable charge pump is also used to tune the loop
characteristic.
The receiver chain starts with the low noise amplifier / mixer combination whose outputs are passed to a lowpass
filter, which provides the channel definition. The signal is then passed to a series of amplifier blocks forming a limiting
strip. The signal is converted to a digital signal before being passed to the Modem. The gain control for the RX path
is derived in the automatic gain control (AGC) block within the Modem, which samples the signal level at various
points down the RX chain. To improve the performance and reduce current consumption, automatic calibration is
applied to various blocks in the RX path.
In the transmit direction, the digital stream from the Modem is passed to a digital sigma-delta modulator which
controls the feedback dividers in the synthesiser, (dual point modulation). The VCO frequency now tracks the applied
modulation. The 2.4 GHz signal from the VCO is then passed to the RF Power Amplifier (PA), whose power control
can be selected from one of three settings. The output of the PA drives the antenna via the RX/TX switch© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 27
8.1.1 Radio External Components
In order to realise the full performance of the radio it is essential that the reference PCB layout and BOM are carefully
followed. See Appendix B.4.
The radio is powered from a number of internal 1.8V regulators fed from the analogue supply VDD1, in order to
provide good noise isolation between the digital logic of the JN5148 and the analogue blocks. These regulators are
also controlled by the baseband controller and protocol software to minimise power consumption. Decoupling for
internal regulators is required as described in section 2.2.1, Power Supplies
For single ended antennas or connectors, a balun is not required, however a matching network is needed.
The RF matching network requires three external components and the IBIAS pin requires one external component as
shown in schematic in B.4.1. These components are critical and should be placed close to the JN5148 pins and
analogue ground as defined in Table 8: JN5148 Printed Antenna Reference Module Components and PCB Layout
Constraints. Specifically, the output of the network comprising L2, C1 and L1 is designed to present an accurate
match to a 50 ohm resistive network as well as provide a DC path to the final output stage or antenna. Users wishing
to match to other active devices such as amplifiers should design their networks to match to 50 ohms at the output of
L1
R1 43K
IBIAS
C20 100nF
L2 2.7nH
VB_RF
VREF
VB_RF2
RF_IN C12 47pF
C3 100nF
VB_RF1
C1 47pF L1 5.6nH
To Coaxial Socket
or Integrated Antenna
VB_RF
Figure 15 External Radio Components
8.1.2 Antenna Diversity
Support is provided for antenna diversity. Antenna diversity is a technique that maximises the performance of an
antenna system. It allows the radio to switch between two antennas that have very low correlation between their
received signals. Typically, this is achieved by spacing two antennas around 0.25 wavelengths apart or by using two
orthogonal polarisations. So, if a packet is transmitted and no acknowledgement is received, the radio system can
switch to the other antenna for the retry, with a different probability of success.
The JN5148 provides an output (ADO) on DIO12 that is asserted on odd numbered retries and optionally its
complement (ADE) on DIO13, that can be used to control an antenna switch; this enables antenna diversity to be
implemented easily (see Figure 16 and Figure 17).28 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
Antenna A Antenna B
A B
COM
SEL
SELB
ADO (DIO[12])
ADE (DIO[13])
Device RF Port
RF Switch: Single-Pole, Double-Throw (SPDT)
Figure 16 Simple Antenna Diversity Implementation using External RF Switch
ADO (DIO[12])
TX Active
RX Active
ADE (DIO[13])
1st TX-RX Cycle 2nd TX-RX Cycle (1st Retry)
Figure 17 Antenna Diversity ADO Signal for TX with Acknowledgement
If two DIO pins cannot be spared, DIO13 can be configured to be a normal DIO pin, and the inverse of ADO
generated with an inverter on the PCB. © NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 29
8.2 Modem
The modem performs all the necessary modulation and spreading functions required for digital transmission and
reception of data at 250kbps in the 2450MHz radio frequency band in compliance with the IEEE802.15.4 standard. It
also provides a high data rate modes at 500 and 667kbps.
AGC Demodulation
Symbol
Detection
(Despreading)
Modulation Spreading
TX
RX
TX Data
Interface
RX Data
Interface
VCO
Sigma-Delta
Modulator
IF Signal
Gain
Figure 18 Modem Architecture
Features provided to support network channel selection algorithms include Energy Detection (ED), Link Quality
Indication (LQI) and fully programmable Clear Channel Assessment (CCA).
The Modem provides a digital Receive Signal Strength Indication (RSSI) that facilitates the implementation of the
IEEE 802.15.4 ED function and LQI function.
The ED and LQI are both related to receiver power in the same way, as shown in Fig19. LQI is associated with a
received packet, whereas ED is an indication of signal power on air at a particular moment.
The CCA capability of the Modem supports all modes of operation defined in the IEEE 802.15.4 standard, namely
Energy above ED threshold, Carrier Sense and Carrier Sense and/or energy above ED threshold.
Figure 19 Energy Detect Value vs Receive Power Level30 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
8.3 Baseband Processor
The baseband processor provides all time-critical functions of the IEEE802.15.4 MAC layer. Dedicated hardware
guarantees air interface timing is precise. The MAC layer hardware/software partitioning, enables software to
implement the sequencing of events required by the protocol and to schedule timed events with millisecond
resolution, and the hardware to implement specific events with microsecond timing resolution. The protocol software
layer performs the higher-layer aspects of the protocol, sending management and data messages between endpoint
and coordinator nodes, using the services provided by the baseband processor.
Append
Checksum
Verify
Checksum
CSMA CCA Backoff
Control
Deserialiser
Serialiser
Tx/Rx
Frame
Buffer
Tx
Bitstream
Rx
Bitstream
Protocol Timing Engine
Supervisor
Radio
Status
Control
Processor
Bus
Protocol
Timers
Security Coprocessor
Decrypt
Port
Encrypt
Port
AES
Codec
Figure 20: Baseband Processor
8.3.1 Transmit
A transmission is performed by software writing the data to be transferred into the Tx/Rx Frame Buffer, together with
parameters such as the destination address and the number of retries allowed, and programming one of the protocol
timers to indicate the time at which the frame is to be sent. This time will be determined by the software tracking the
higher-layer aspects of the protocol such as superframe timing and slot boundaries. Once the packet is prepared and
protocol timer set, the supervisor block controls the transmission. When the scheduled time arrives, the supervisor
controls the sequencing of the radio and modem to perform the type of transmission required. It can perform all the
algorithms required by IEEE802.15.4 such as CSMA/CA, GTS without processor intervention including retries and
random backoffs.
When the transmission begins, the header of the frame is constructed from the parameters programmed by the
software and sent with the frame data through the serialiser to the Modem. At the same time, the radio is prepared
for transmission. During the passage of the bitstream to the modem, it passes through a CRC checksum generator
that calculates the checksum on-the-fly, and appends it to the end of the frame.
If using slotted access, it is possible for a transmission to overrun the time in its allocated slot; the Baseband
Processor handles this situation autonomously and notifies the protocol software via interrupt, rather than requiring it
to handle the overrun explicitly.
8.3.2 Reception
During reception, the radio is set to receive on a particular channel. On receipt of data from the modem, the frame is
directed into the Tx/Rx Frame Buffer where both header and frame data can be read by the protocol software. An
interrupt may be provided on receipt of the frame header. As the frame data is being received from the modem it is
passed through a checksum generator; at the end of the reception the checksum result is compared with the
checksum at the end of the message to ensure that the data has been received correctly. An interrupt may be © NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 31
provided to indicate successful packet reception. During reception, the modem determines the Link Quality, which is
made available at the end of the reception as part of the requirements of IEEE802.15.4.
8.3.3 Auto Acknowledge
Part of the protocol allows for transmitted frames to be acknowledged by the destination sending an acknowledge
packet within a very short window after the transmitted frame has been received. The JN5148 baseband processor
can automatically construct and send the acknowledgement packet without processor intervention and hence avoid
the protocol software being involved in time-critical processing within the acknowledge sequence. The JN5148
baseband processor can also request an acknowledge for packets being transmitted and handle the reception of
acknowledged packets without processor intervention.
8.3.4 Beacon Generation
In beaconing networks, the baseband processor can automatically generate and send beacon frames; the repetition
rate of the beacons is programmed by the CPU, and the baseband then constructs the beacon contents from data
delivered by the CPU. The baseband processor schedules the beacons and transmits them without CPU
intervention.
8.3.5 Security
The transmission and reception of secured frames using the Advanced Encryption Standard (AES) algorithm is
handled by the security coprocessor and the stack software. The application software must provide the appropriate
encrypt/decrypt keys for the transmission or reception. On transmission, the key can be programmed at the same
time as the rest of the frame data and setup information.
8.4 Security Coprocessor
The security coprocessor is available to the application software to perform encryption/decryption operations. A
hardware implementation of the encryption engine significantly speeds up the processing of the encrypted packets
over a pure software implementation. The AES library for the JN5148 provides operations that utilise the encryption
engine in the device and allow the contents of memory buffers to be transformed. Information such as the type of
security operation to be performed and the encrypt/decrypt key to be used must also be provided.
Processor
Interface
AES
Block
Encrpytion
Controller
AES Encoder
Key Generation
Figure 21: Security Coprocessor Architecture
8.5 Location Awareness
The JN5148 provides the ability for an application to obtain the Time Of Flight (TOF) between two network nodes.
The TOF information is an alternative metric to that of the existing Energy Detect value (RSSI) that has been typically
used for calculating the relative inter-nodal separation, for subsequent use in a location awareness system.
For short ranges RSSI will typically give a better accuracy than TOF, however for distances above 5 to 10 meters
TOF will offer significant improvements in accuracy compared to RSSI. In general, the RSSI error scales with
distance, such that if the distance doubles then the error doubles.32 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
8.6 Higher Data Rates
To support the demands of applications that require high data throughputs such as in audio or data streaming
applications, the JN5148 supports higher data rate modes that offer 500kbps or 667kbps on air transmission rates.
The switching between standard and higher data rates is controlled via software, When operating in a higher data
rate mode standard IEEE802.15.4 features, such as clear channel assessment, can still be used. This allows the
JN5148 in a higher data rate mode to co-exist in an IEEE802.15.4 based network (adhering to the correct bit rates
and frame timing etc.) whilst at the same time providing the benefit of the higher data rate where required.
When operating in a higher data rate mode, the receive sensitivity will be degraded by at least 3dB.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 33
9 Digital Input/Output
There are 21 Digital I/O (DIO) pins, which can be configured as either an input or an output, and each has a
selectable internal pull-up resistor. Most DIO pins are multiplexed with alternate peripheral features of the device,
see section 2.1. Once a peripheral is enabled it takes precedence over the device pins. Refer to the individual
module sections for a full description of the alternate peripherals functions. Following a reset (and whilst the reset
input is held low), all peripherals are off and the DIO pins are configured as inputs with the internals pull-ups turned
on.
When a peripheral is not enabled, the DIO pins associated with it can be used as digital inputs or outputs. Each pin
can be controlled individually by setting the direction and then reading or writing to the pin.
The individual pull-up resistors, RPU, can also be enabled or disabled as needed and the setting is held through sleep
cycles. The pull-ups are generally configured once after reset depending on the external components and
functionality. For instance, outputs should generally have the pull-ups disabled. An input that is always driven should
also have the pull-up disabled.
When configured as an input each pin can be used to generate an interrupt upon a change of state (selectable
transition either from low to high or high to low); the interrupt can be enabled or disabled. When the device is
sleeping, these interrupts become events that can be used to wake the device up. Equally the status of the interrupt
may be read. See section 21 Power Management and Sleep Modes for further details on sleep and wakeup.
The state of all DIO pins can be read, irrespective of whether the DIO is configured as an input or an output.
Throughout a sleep cycle the direction of the DIO, and the state of the outputs, is held. This is based on the resultant
of the GPIO Data/ Direction registers and the effect of any enabled peripherals at the point of entering sleep.
Following a wake-up these directions and output values are maintained under control of the GPIO data / direction
registers. Any peripherals enabled before the sleep cycle are not automatically re-enabled, this must be done through
software after the wake-up.
For example, if DIO0 is configured to be SPISEL1 then it becomes an output. The output value is controlled by the
SPI functional block. If the device then enters a sleep cycle, the DIO will remain an output and hold the value being
output when entering sleep. After wake-up the DIO will still be an output with the same value but controlled from the
GPIO Data/Direction registers. It can be altered with the software functions that adjust the DIO, or the application may
re-configure it to be SPISEL1.
Unused DIO pins are recommended to be set as inputs with the pull-up enabled.
Two DIO pins can optionally be used to provide control signals for RF circuitry (eg switches and PA) in high power
range extenders.
DIO3 / RFTX is asserted when the radio is in the transmit state and similarly, DIO2 / RFRX is asserted when the radio
is in the receiver state.34 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
4-wire
Digital Audio
Interface
Antenna
Diversity
JTAG
Debug
Pulse
Counters
Intelligent
Peripheral
MUX
2-wire
Interface
Timer2
Timer1
Timer0
UART1
UART0
SPI
Master SPISEL1
SPISEL2
SPISEL3
SPISEL4
TXD0
RXD0
RTS0
CTS0
TXD1
RXD1
RTS1
CTS1
TIM0CK_GT
TIM0OUT
TIM0CAP
TIM1CK_GT
TIM1OUT
TIM1CAP
TIM2OUT
SIF_D
SIF_CLK
IP_DO
IP_DI
IP_INT
IP_CLK
IP_SEL
PC0
PC1
JTAG_TDI
JTAG_TMS
JTAG_TCK
JTAG_TDO
ADO
ADE
I2S_OUT
I2S_DIN
I2S_CLK
I2S_SYNC
SPICLK
SPIMOSI
SPIMISO
SPISEL0
DIO0/SPISEL1
DIO1/SPISEL2/PC0
DIO2/SPISEL3/RFRX
DIO3/SPISEL4/RFTX
DIO4/CTS0/JTAG_TCK
DIO5/RTS0/JTAG_TMS
DIO6/TXD0/JTAG_TDO
DIO7/RXD0/JTAG_TDI
DIO8/TIM0CK_GT/PC1
DIO9/TIM0CAP/32KXTALIN/32KIN
DIO10/TIM0OUT/32KXTALOUT
DIO11/TIM1CK_GT/TIM2OUT
DIO12/TIM1CAP/ADO/DAI_WS
DIO13/TIM1OUT/ADE/DAI_SDN
DIO14/SIF_CLK/IP_CLK
DIO15/SIF_D/IP_DO
DIO16/IP_DI
DIO17/CTS1/IP_SEL/DAI_SCK/
JTAG_TCK
DIO18/RTS1/IP_INT/DAI_SDOUT/
JTAG_TMS
DIO19/TXD1/JTAG_TDO
DIO20/RXD1/JTAG_TDI
Figure 22 DIO Block Diagram© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 35
10 Serial Peripheral Interface
The Serial Peripheral Interface (SPI) allows high-speed synchronous data transfer between the JN5148 and
peripheral devices. The JN5148 operates as a master on the SPI bus and all other devices connected to the SPI are
expected to be slave devices under the control of the JN5148 CPU. The SPI includes the following features:
• Full-duplex, three-wire synchronous data transfer
• Programmable bit rates (up to 16Mbit/s)
• Programmable transaction size up to 32-bits
• Standard SPI modes 0,1,2 and 3
• Manual or Automatic slave select generation (up to 5 slaves)
• Maskable transaction complete interrupt
• LSB First or MSB First Data Transfer
• Supports delayed read edges
Clock
Divider
SPI Bus
Cycle
Controller
Data Buffer
DIV
Clock Edge
Select
Data
CHAR_LEN
LSB
SPIMISO
SPIMOSI
SPICLK
Select
Latch
SPISEL [4..0]
16 MHz
Figure 23: SPI Block Diagram
The SPI bus employs a simple shift register data transfer scheme. Data is clocked out of and into the active devices
in a first-in, first-out fashion allowing SPI devices to transmit and receive data simultaneously.
There are three dedicated pins SPICLK, SPIMOSI, SPIMISO that are shared across all devices on the bus. MasterOut-Slave-In
or Master-In-Slave-Out data transfer is relative to the clock signal SPICLK generated by the JN5148.
The JN5148 provides five slave selects, SPISEL0 to SPISEL4 to allow five SPI peripherals on the bus. SPISEL0 is a
dedicated pin; this is generally connected to a serial Flash/ EEPROM memory holding application code that is
downloaded to internal RAM via software from reset. SPISEL1 to 4, are alternate functions of pins DIO0 to 3
respectively.
The interface can transfer from 1 to 32-bits without software intervention and can keep the slave select lines asserted
between transfers when required, to enable longer transfers to be performed.
When the device reset is active, the three outputs SPISEL, SPICLK and SPI_MOSI are tri-stated and SPI_MISO is
set to be an input. The pull-up resistors associated with all four pins will be active at this time. 36 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013 SI
C
SO
SS
Slave 0
Flash/
EEPROM
Memory
JN5148
37
38
41
42
43
36
33
34
SI
C
SO
SS
Slave 1
User
Defined
SI
C
SO
SS
Slave 2
User
Defined
SI
C
SO
SS
Slave 3
User
Defined
SI
C
SO
SS
Slave 4
User
Defined
SPIMISO
SPIMOSI
SPICLK
SPISEL4
SPISEL2
SPISEL3
SPISEL1
SPISEL0
Figure 24: Typical JN5148 SPI Peripheral Connection
The data transfer rate on the SPI bus is determined by the SPICLK signal. The JN5148 supports transfers at
selectable data rates from 16MHz to 125kHz selected by a clock divider. Both SPICLK clock phase and polarity are
configurable. The clock phase determines which edge of SPICLK is used by the JN5148 to present new data on the
SPIMOSI line; the opposite edge will be used to read data from the SPIMISO line. The interface should be configured
appropriately for the SPI slave being accessed.
SPICLK
Mode Description
Polarity
(CPOL)
Phase
(CPHA)
0 0 0 SPICLK is low when idle – the first edge is positive.
Valid data is output on SPIMOSI before the first clock and changes every
negative edge. SPIMISO is sampled every positive edge.
0 1 1 SPICLK is low when idle – the first edge is positive.
Valid data is output on SPIMOSI every positive edge. SPIMISO is sampled every
negative edge.
1 0 2 SPICLK is high when idle – the first edge is negative.
Valid data is output on SPIMOSI before the first clock edge and is changed
every positive edge. SPIMISO is sampled every negative edge.
1 1 3 SPICLK is high when idle – the first edge is negative.
Valid data is output on SPIMOSI every negative edge. SPIMISO is sampled
every positive edge.
Table 3 SPI Configurations
If more than one SPISEL line is to be used in a system they must be used in numerical order starting from SPISEL0.
For instance if 3 SPI select lines are to be used, they must be SPISEL0, 1 and 2. A SPISEL line can be automatically
deasserted between transactions if required, or it may stay asserted over a number of transactions. For devices such
as memories where a large amount of data can be received by the master by continually providing SPICLK
transitions, the ability for the select line to stay asserted is an advantage since it keeps the slave enabled over the
whole of the transfer.
A transaction commences with the SPI bus being set to the correct configuration, and then the slave device is
selected. Upon commencement of transmission (1 to 32 bits) data is placed in the FIFO data buffer and clocked out,
at the same time generating the corresponding SPICLK transitions. Since the transfer is full-duplex, the same
number of data bits is being received from the slave as it transmits. The data that is received during this transmission
can be read (1 to 32 bits). If the master simply needs to provide a number of SPICLK transitions to allow data to be © NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 37
sent from a slave, it should perform transmit using dummy data. An interrupt can be generated when the transaction
has completed or alternatively the interface can be polled.
If a slave device wishes to signal the JN5148 indicating that it has data to provide, it may be connected to one of the
DIO pins that can be enabled as an interrupt.
Figure 25 shows a complex SPI transfer, reading data from a FLASH device, that can be achieved using the SPI
master interface. The slave select line must stay low for many separate SPI accesses, and therefore manual slave
select mode must be used. The required slave select can then be asserted (active low) at the start of the transfer. A
sequence 8 and 32 bit transfers can be used to issue the command and address to the FLASH device and then to
read data back. Finally, the slave select can be deselected to end the transaction.
0 1 2 3 4 5 6 7
Instruction (0x03)
23 22 21 3 2 1 0
8 9 10 28 29 30 31
24-bit Address
MSB
Instruction Transaction
7 6 5 4 3 2 1 0
MSB
0 1 2 3 4 5 7 8N-1
3 2 1 0
LSB
Read Data Bytes Transaction(s) 1-N
SPISEL
SPICLK
SPIMOSI
SPIMISO
SPISEL
SPICLK
SPIMOSI
SPIMISO
8 9 10
7 6 5
MSB
Byte 1 Byte 2 Byte N
value unused by peripherals
6
Figure 25: Example SPI Waveforms – Reading from FLASH device using Mode 038 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
11 Timers
11.1 Peripheral Timer/Counters
Three general-purpose timer/counter units are available that can be independently configured to operate in one of
five possible modes. Timer 0 and 1 support all 5 modes of operation and Timer 2 supports PWM and Delta-Sigma
modes only. The timers have the following:
• 5-bit prescaler, divides system clock by 2 prescale value as the clock to the timer (prescaler range is 0 to 16)
• Clocked from internal system clock (16MHz)
• 16-bit counter, 16-bit Rise and Fall (period) registers
• Timer: can generate interrupts off Rise and Fall counts. Can be gated by external signal
• Counter: counts number of transitions on external event signal. Can use low-high, high-low or both
transitions
• PWM/Single pulse: outputs repeating Pulse Width Modulation signal or a single pulse. Can set period and
mark-space ratio
• Capture: measures times between transitions of an applied signal
• Delta-Sigma: Return-To-Zero (RTZ) and Non-Return-to-Zero (NRZ) modes
• Timer usage of external IO can be controlled on a pin by pin basis
Interrupt
Generator
Rise
Fall
Delta-Sigma
Counter
Reset Generator
=
Prescaler
INT
Int Enable
SYSCLK
S/w
Reset
System
Reset
Single
Shot
=
S
R
OE
Gate
Gate
Edge
Select
Reset
PWM/DeltaSigma
Capture
Generator
Capture
Enable
PWM/∆−Σ
PWM/∆−Σ
TIMxCK_GT
TIMxOUT
TIMxCAP
Figure 26: Timer Unit Block Diagram© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 39
The clock source for the timer unit is fed from the 16MHz system clock. This clock passes to a 5-bit prescaler where a
value of 0 leaves the clock unmodified and other values divide it by 2 prescale value. For example, a prescale value of
2 applied to the 16MHz system clock source results in a timer clock of 4MHz.
The counter is optionally gated by a signal on the clock/gate input (TIMxCK_GT). If the gate function is selected,
then the counter is frozen when the clock/gate input is high.
An interrupt can be generated whenever the counter is equal to the value in either of the High or Low registers.
The internal Output Enable (OE) signal enables or disables the timer output.
The Timer 0 signals CK_GT, CAP and OUT are alternate functions of pins DIO8, 9 and 10 respectively and Timer 1
signals CK_GT, CAP and OUT are alternate functions of pins DIO11, 12, and 13 respectively. Timer 2 OUT is an
alternate function of DIO11 If operating in timer mode it is not necessary to use any of the DIO pins, allowing the
standard DIO functionality to be available to the application.
Note, timer 0 may only be used as an internal timer or in counter mode (counting events) if an external 32kHz crystal
is used. If timer 2 is used in PWM or Delta-Sigma mode then timer 1 does not have access to its clock/gate pin.
Therefore, it can not operate in counter mode (counting events) or use the gate function.
11.1.1 Pulse Width Modulation Mode
Pulse Width Modulation (PWM) mode allows the user to specify an overall cycle time and pulse length within the
cycle. The pulse can be generated either as a single shot or as a train of pulses with a repetition rate determined by
the cycle time.
In this mode, the cycle time and low periods of the PWM output signal can be set by the values of two independent
16-bit registers (Fall and Rise). The counter increments and its output is compared to the 16-bit Rise and Fall
registers. When the counter is equal to the Rise register, the PWM output is set to high; when the counter reaches
the Fall value, the output returns to low. In continuous mode, when the counter reaches the Fall value, it will reset
and the cycle repeats. The PWM waveform is available on TIMxOUT when the output driver is enabled.
Rise
Fall
Figure 27: PWM Output Timings
11.1.2 Capture Mode
The capture mode can be used to measure the time between transitions of a signal applied to the capture input
(TIMxCAP). When the capture is started, on the next low-to-high transition of the captured signal, the count value is
stored in the Rise register, and on the following high-to-low transition, the counter value is stored in the Fall register.
The pulse width is the difference in counts in the two registers multiplied by the period of the prescaled clock. Upon
reading the capture registers the counter is stopped. The values in the High and Low registers will be updated
whenever there is a corresponding transition on the capture input, and the value stored will be relative to when the
mode was started. Therefore, if multiple pulses are seen on TIMxCAP before the counter is stopped only the last
pulse width will be stored.40 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
CLK
CAPT
x 9 3
x 14
t
RISE t
RISE
t
FALL t
FALL
Rise
Fall
9 5 3 4
7
Capture Mode Enabled
Figure 28: Capture Mode
11.1.3 Counter/Timer Mode
The counter/timer can be used to generate interrupts, based on the timers or event counting, for software to use. As
a timer the clock source is from the system clock, prescaled if required. The timer period is programmed into the Fall
register and the Fall register match interrupt enabled. The timer is started as either a single-shot or a repeating timer,
and generates an interrupt when the counter reaches the Fall register value.
When used to count external events on TIMxCK_GT the clock source is selected from the input pin and the number
of events programmed into the Fall register. The Fall register match interrupt is enabled and the counter started,
usually in single shot mode. An interrupt is generated when the programmed number of transitions is seen on the
input pin. The transitions counted can configured to be rising, falling or both rising and falling edges.
Edges on the event signal must be at least 100nsec apart, i.e. pulses must be wider than 100nsec.
11.1.4 Delta-Sigma Mode
A separate delta-sigma mode is available, allowing a low speed delta-sigma DAC to be implemented with up to 16-bit
resolution. This requires that a resistor-capacitor network is placed between the output DIO pin and digital ground. A
stream of pulses with digital voltage levels is generated which is integrated by the RC network to give an analogue
voltage. A conversion time is defined in terms of a number of clock cycles. The width of the pulses generated is the
period of a clock cycle. The number of pulses output in the cycle, together with the integrator RC values, will
determine the resulting analogue voltage. For example, generating approximately half the number of pulses that
make up a complete conversion period will produce a voltage on the RC output of VDD1/2, provided the RC time
constant is chosen correctly. During a conversion, the pulses will be pseudo-randomly dispersed throughout the
cycle in order to produce a steady voltage on the output of the RC network.
The output signal is asserted for the number of clock periods defined in the High register, with the total period being
216 cycles. For the same value in the High register, the pattern of pulses on subsequent cycles is different, due to the
pseudo-random distribution.
The delta-sigma convertor output can operate in a Return-To-Zero (RTZ) or a Non-Return-to-Zero (NRZ) mode. The
NRZ mode will allow several pulses to be output next to each other. The RTZ mode ensures that each pulse is
separated from the next by at least one period. This improves linearity if the rise and fall times of the output are
different to one another. Essentially, the output signal is low on every other output clock period, and the conversion
cycle time is twice the NRZ cycle time ie 217 clocks. The integrated output will only reach half VDD2 in RTZ mode,
since even at full scale only half the cycle contains pulses. Figure 29 and Figure 30 illustrate the difference between
RTZ and NRZ for the same programmed number of pulses.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 41
1 2 3 1 2 N
Conversion cycle 1
217
N
Conversion cycle 2
3
Figure 29: Return To Zero Mode in Operation
1 2 3 1 2 N
Conversion cycle 1
N 3
216 Conversion cycle 2
Figure 30: Non-Return to Zero Mode
11.1.5 Example Timer / Counter Application
Figure 31 shows an application of the JN5148 timers to provide closed loop speed control. Timer 0 is configured in
PWM mode to provide a variable mark-space ratio switching waveform to the gate of the NFET. This in turn controls
the power in the DC motor.
Timer 1 is configured to count the rising edge events on the clk/gate pin over a constant period. This converts the
tacho pulse stream output into a count proportional to the motor speed. This value is then used by the application
software executing the control algorithm.
If required for other functionality, then the unused IO associated with the timers could be used as general purpose
DIO.
JN5148
Timer 0
Timer 1
CLK/GATE
CLK/GATE
CAPTURE
CAPTURE
PWM
PWM
M Tacho
48
50
52
53
54
1N4007
+12V
IRF521 51
1 pulse/rev
Figure 31: Closed Loop PWM Speed Control Using JN5148 Timers
11.2 Tick Timer
The JN5148 contains a hardware timer that can be used for generating timing interrupts to software. It may be used
to implement regular events such as ticks for software timers or an operating system, as a high-precision timing
reference or can be used to implement system monitor timeouts as used in a watchdog timer. Features include:
• 32-bit counter42 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
• 28-bit match value
• Maskable timer interrupt
• Single-shot, Restartable or Continuous modes of operation
Match Value
Counter
=
Mode
Control
&
&
SysClk
Run
Match
Int
Enable
Tick Timer
Interrupt
Reset
Mode
Figure 32: Tick Timer
The Tick Timer is clocked from a continuous 16MHz clock, which is fed to a 32-bit wide resettable up-counter, gated
by a signal from the mode control block. A match register allows comparison between the counter and a
programmed value. The match value, measured in 16MHz clock cycles is programmed through software, in the
range 0 to 0x0FFFFFFF. The output of the comparison can be used to generate an interrupt if the interrupt is
enabled and used in controlling the counter in the different modes. Upon configuring the timer mode, the counter is
also reset.
If the mode is programmed as single shot, the counter begins to count from zero until the match value is reached.
The match signal will be generated which will cause an interrupt if enabled, and the counter will stop counting. The
counter is restarted by reprogramming the mode.
If the mode is programmed as restartable, the operation of the counter is the same as for the single shot mode,
except that when the match value is reached the counter is reset and begins counting from zero. An interrupt will be
generated when the match value is reached if it is enabled.
Continuous mode operation is similar to restartable, except that when the match value is reached, the counter is not
reset but continues to count. An interrupt will be generated when the match value is reached if enabled.
11.3 Wakeup Timers
Two 32-bit wakeup timers are available in the JN5148 driven from the 32kHz internal clock. They may run during
sleep periods when the majority of the rest of the device is powered down, to time sleep periods or other long period
timings that may be required by the application. The wakeup timers do not run during deep sleep and may optionally
be disabled in sleep mode through software control. When a wakeup timer expires it typically generates an interrupt,
if the device is asleep then the interrupt may be used as an event to end the sleep period. See Section 21 for further
details on how they are used during sleep periods. Features include:
• 35-bit down-counter
• Optionally runs during sleep periods
• Clocked by 32kHz system clock; either 32kHz RC oscillator, 32kHz XTAL oscillator or 32kHz clock input© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 43
A wakeup timer consists of a 35-bit down counter clocked from the selected 32 kHz clock. An interrupt or wakeup
event can be generated when the counter reaches zero. On reaching zero the counter will continue to count down
until stopped, which allows the latency in responding to the interrupt to be measured. If an interrupt or wakeup event
is required, the timer interrupt should be enabled before loading the count value for the period. Once the count value
is loaded and counter started, the counter begins to count down; the counter can be stopped at any time through
software control. The counter will remain at the value it contained when the timer was stopped and no interrupt will
be generated. The status of the timers can be read to indicate if the timers are running and/or have expired; this is
useful when the timer interrupts are masked. This operation will reset any expired status flags.
11.3.1 RC Oscillator Calibration
The RC oscillator that can be used to time sleep periods is designed to require very little power to operate and be
self-contained, requiring no external timing components and hence is lower cost. As a consequence of using on-chip
resistors and capacitors, the inherent absolute accuracy and temperature coefficient is lower than that of a crystal
oscillator, but once calibrated the accuracy approaches that of a crystal oscillator. Sleep time periods should be as
close to the desired time as possible in order to allow the device to wake up in time for important events, for example
beacon transmissions in the IEEE802.15.4 protocol. If the sleep time is accurate, the device can be programmed to
wake up very close to the calculated time of the event and so keep current consumption to a minimum. If the sleep
time is less accurate, it will be necessary to wake up earlier in order to be certain the event will be captured. If the
device wakes earlier, it will be awake for longer and so reduce battery life.
In order to allow sleep time periods to be as close to the desired length as possible, the true frequency of the RC
oscillator needs to be determined to better than the initial 30% accuracy. The calibration factor can then be used to
calculate the true number of nominal 32kHz periods needed to make up a particular sleep time. A calibration
reference counter, clocked from the 16MHz system clock, is provided to allow comparisons to be made between the
32kHz RC clock and the 16MHz system clock when the JN5148 is awake.
Wakeup timer0 counts for a set number of 32kHz clock periods during which time the reference counter runs. When
the wakeup timer reaches zero the reference counter is stopped, allowing software to read the number of 16MHz
clock ticks generated during the time represented by the number of 32kHz ticks programmed in the wakeup timer.
The true period of the 32kHz clock can thus be determined and used when programming a wakeup timer to achieve a
better accuracy and hence more accurate sleep periods
For a RC oscillator running at exactly 32,000Hz the value returned by the calibration procedure should be 10000, for
a calibration period of twenty 32,000Hz clock periods. If the oscillator is running faster than 32,000Hz the count will
be less than 10000, if running slower the value will be higher. For a calibration count of 9000, indicating that the RC
oscillator period is running at approximately 35kHz, to time for a period of 2 seconds the timer should be loaded with
71,111 ((10000/9000) x (32000 x 2)) rather than 64000.44 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
12 Pulse Counters
Two 16-bit counters are provided that can increment during all modes of operation (including sleep), based on pulses
received on 2 dedicated DIO inputs; DIO1 and DIO8. The pulses can be de-bounced using the 32kHz clock to guard
against false counting on slow or noisy edges. Increments occur from a configurable rising or falling edge on the
respective DIO input.
Each counter has an associated 16-bit reference that is loaded by the user. An interrupt (and wakeup event if
asleep) may be generated when a counter reaches its pre-configured reference value. The two counters may
optionally be cascaded together to provide a single 32-bit counter, linked to DIO1. The counters do not saturate at
65535, but naturally roll-over to 0. Additionally, the pulse counting continues when the reference value is reached
without software interaction so that pulses are not missed even if there is a long delay before an interrupt is serviced
or during the wakeup process.
The system can work with signals up to 100kHz, with no debounce, or from 5.3kHz to 1.7kHz with debounce. When
using debounce the 32kHz clock must be active, so for minimum sleep currents the debounce mode should not be
used.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 45
13 Serial Communications
The JN5148 has two independent Universal Asynchronous Receiver/Transmitter (UART) serial communication
interfaces. These provide similar operating features to the industry standard 16550A device operating in FIFO mode.
Each interface performs serial-to-parallel conversion on incoming serial data and parallel-to-serial conversion on
outgoing data from the CPU to external devices. In both directions, a 16-byte deep FIFO buffer allows the CPU to
read and write multiple characters on each transaction. This means that the CPU is freed from handling data on a
character-by-character basis, with the associated high processor overhead. The UARTs have the following features:
• Emulates behaviour of industry standard NS16450 and NS16550A UARTs
• 16 byte transmit and receive FIFO buffers reduce interrupts to CPU, with direct access to fill levels of each
• Adds / deletes standard start, stop and parity communication bits to or from the serial data
• Independently controlled transmit, receive, status and data sent interrupts
• Optional modem flow control signals CTS and RTS
• Fully programmable data formats: baud rate, start, stop and parity settings
• False start bit detection, parity, framing and FIFO overrun error detect and break indication
• Internal diagnostic capabilities: loop-back controls for communications link fault isolation
• Flow control by software or automatically by hardware Processor Bus
Divisor
Latch
Registers
Line
Status
Register
Line
Control
Register
FIFO
Control
Register
Receiver FIFO
Transmitter FIFO
Baud Generator
Logic
Transmitter Shift
Register
Receiver Shift
Register
Transmitter
Logic
Receiver
Logic
RXD
TXD
Modem
Control
Register
Modem
Status
Register Modem
Signals
Logic
RTS
CTS
Interrupt
ID
Register
Interrupt
Enable
Register
Interrupt
Logic
Internal
Interrupt
Figure 33: UART Block Diagram
The serial interface contains programmable fields that can be used to set number of data bits (5, 6,7 or 8), even, odd,
set-at-1, set-at-0 or no-parity detection and generation of single or multiple stop bit, (for 5 bit data, multiple is 1.5 stop
bits; for 6, 7 or 8 data bits, multiple is 2 bits).
The baud rate is programmable up to 1Mbps, standard baud rates such as 4800, 9600, 19.2k, 38.4k etc. can be
configured.
For applications requiring hardware flow control, two control signals are provided: Clear-To-Send (CTS) and RequestTo-Send
(RTS). CTS is an indication sent by an external device to the UART that it is ready to receive data. RTS is
an indication sent by the UART to the external device that it is ready to receive data. RTS is controlled from software,
while the value of CTS can be read. Monitoring and control of CTS and RTS is a software activity, normally
performed as part of interrupt processing. The signals do not control parts of the UART hardware, but simply indicate
to software the state of the UART external interface. Alternatively, the Automatic Flow Control mode can be set 46 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
where the hardware controls the value of the generated RTS (negated if the receive FIFO fill level is greater than a
programmable threshold of 8, 11, 13 or 15 bytes), and only transmits data when the incoming CTS is asserted.
Software can read characters, one byte at a time, from the Receive FIFO and can also write to the Transmit FIFO,
one byte at a time. The Transmit and Receive FIFOs can be cleared and reset independently of each other. The
status of the transmitter can be checked to see if it is empty, and if there is a character being transmitted. The status
of the receiver can also be checked, indicating if conditions such as parity error, framing error or break indication
have occurred. It also shows if an overrun error occurred (receive buffer full and another character arrives) and if
there is data held in the receive FIFO.
UART 0 signals CTS, RTS, TXD and RXD are alternate functions of pins DIO4, 5, 6 and 7 respectively and UART 1
signals CTS, RTS, TXD and RXD are alternate functions of pins DIO17, 18, 19 and 20 respectively. If CTS and RTS
are not required on the devices external pins, then they may be disabled, this allows the DIOx function to be used for
other purposes.
Note: With the automatic flow control threshold set to 15, the hardware flow control within the UART block negates
RTS when the receive FIFO is about to become full. In some instances it has been observed that remote devices that
are transmitting data do not respond quickly enough to the de-asserted CTS and continue to transmit data. In these
instances the data will be lost in a receive FIFO overflow.
13.1 Interrupts
Interrupt generation can be controlled for the UART block, and is divided into four categories:
• Received Data Available: Is set when data in the Rx FIFO queue reaches a particular level (the trigger level can
be configured as 1, 4, 8 or 14) or if no character has been received for 4 character times.
• Transmit FIFO Empty: set when the last character from the Tx FIFO is read and starts to be transmitted.
• Receiver Line Status: set when one of the following occur (1) Parity Error - the character at the head of the
receive FIFO has been received with a parity error, (2) Overrun Error - the Rx FIFO is full and another character
has been received at the Receiver shift register, (3) Framing Error - the character at the head of the receive
FIFO does not have a valid stop bit and (4) Break Interrupt – occurs when the RxD line has been held low for an
entire character.
• Modem Status: Generated when the CTS (Clear To Send) input control line changes.
13.2 UART Application
The following example shows the UART connected to a 9-pin connector compatible with a PC. As the JN5148
device pins do not provide the RS232 line voltage, a level shifter is used.
JN5148
RTS
CTS
TXD
UART0 RXD
RS232
Lev el
Shif ter
1
2
3
4
5
6
7
8
9
CD
RD
TD
DTR
SG
DSR
RTS
CTS
RI
PC COM Port
1 5 Pin Signal
6 9
46
47
45
44
Figure 34: JN5148 Serial Communication Link© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 47
14 JTAG Debug Interface
The JN5148 includes an IEEE1149.1 compliant JTAG port for the sole purpose of software code debug with NXP's
Software Developer’s Kit. The JTAG interface is disabled by default and is enabled under software control.
Therefore, debugging is only possible if enabled by the application. Once enabled, the application executes as
normal until the external debugger controller initiates debug activity.
The Debugger supports breakpoints and watchpoints based on four comparisons between any of program counter,
load/store effective address and load/store data. There is the ability to chain the comparisons together. There is also
the ability, under debugger control to perform the following commands: go, stop, reset, step over/into/out/next, run to
cursor and breakpoints. In addition, under control of the debugger, it is possible to:
• Read and write registers on the wishbone bus
• Read ROM and RAM, and write to RAM
• Read and write CPU internal registers
The Debugger interface is accessed, depending upon the configuration, through the pins used for UART0 or UART1.
This is enabled under software control and is dealt with in JN-AN-1118 JN5148 Application Debugging [4]. The
following table details which DIO are used for the JTAG interface depending upon the configuration.
Signal DIO Assignment
UART0 pins UART1 pins
clock (TCK) 4 17
control (TMS) 5 18
data out (TDO) 6 19
data in (TDI) 7 20
Table 4 Hardware Debugger IO
If doze mode is active when debugging is started, the processor will be woken and then respond to debugger
commands. It is not possible to wake the device from sleep using the debug interface and debugging is not available
while the device is sleeping.
When using the debug interface, program execution is halted, and control of the CPU is handed to the debugger. The
watchdog, tick timer and the three timers described in section 11 are stalled while the debugger is in control of the
CPU.
When control is handed from the CPU to the debugger or back a small number of CPU clock cycles are taken
flushing or reloading the CPU pipeline. Because of this, when a program is halted by the debugger and then restarted
again, a small number of tick timer cycles will elapse.
It is possible to prevent all hardware debugging by blowing the relevant Efuse bit.
The JTAG interface does not support boundary scan testing. It is recommended that the JN5148 is not connected as
part of the board scan chain.48 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
15 Two-Wire Serial Interface
The JN5148 includes industry standard two-wire synchronous Serial Interface operates as a Master (MSIF) or Slave
(SSIF) that provides a simple and efficient method of data exchange between devices. The system uses a serial data
line (SIF_D) and a serial clock line (SIF_CLK) to perform bi-directional data transfers and includes the following
features:
Common to both master and slave:
• Compatible with both I2
C and SMbus peripherals
• Support for 7 and 10-bit addressing modes
• Optional pulse suppression on signal inputs
Master only:
• Multi-master operation
• Software programmable clock frequency
• Clock stretching and wait state generation
• Software programmable acknowledge bit
• Interrupt or bit-polling driven byte-by-byte data-transfers
• Bus busy detection
Slave only:
• Programmable slave address
• Simple byte level transfer protocol
• Write data flow control with optional clock stretching or acknowledge mechanism
• Read data preloaded or provided as required
15.1 Connecting Devices
The clock and data lines, SIF_D and SIF_CLK, are alternate functions of DIO15 and DIO14 respectively. The serial
interface function of these pins is selected when the interface is enabled. They are both bi-directional lines,
connected internally to the positive supply voltage via weak (45kΩ) programmable pull-up resistors. However, it is
recommended that external 4.7kΩ pull-ups be used for reliable operation at high bus speeds, as shown in Figure 35.
When the bus is free, both lines are HIGH. The output stages of devices connected to the bus must have an opendrain
or open-collector in order to perform the wired-AND function. The number of devices connected to the bus is
solely dependent on the bus capacitance limit of 400pF.
SIF_CLK
SIF_D
VDD
D1_OUT
D1_IN CLK1_IN
CLK1_OUT
D2_IN CLK2_IN
CLK2_OUT
DEVICE 1 DEVICE 2
RP RP Pullup
Resistors
D2_OUT
JN5148
SIF
DIO14
DIO15
Figure 35: Connection Details© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 49
15.2 Clock Stretching
Slave devices can use clock stretching to slow down the transfer bit rate. After the master has driven SIF_CLK low,
the slave can drive SIF_CLK low for the required period and then release it. If the slave’s SIF_CLK low period is
greater than the master’s low period the resulting SIF_CLK bus signal low period is stretched thus inserting wait
states.
SIF_CLK
SIF_CLK
SIF_CLK
Master SIF_CLK
Slave SIF_CLK
Wired-AND SIF_CLK
Clock held low
by Slave
Figure 36: Clock Stretching
15.3 Master Two-wire Serial Interface
When operating as a master device, it provides the clock signal and a prescale register determines the clock rate,
allowing operation up to 400kbit/s.
Data transfer is controlled from the processor bus interface at a byte level, with the processor responsible for
indicating when start, stop, read, write and acknowledge control should be generated. Write data written into a
transmit buffer will be written out across the two-wire interface when indicated, and read data received on the
interface is made available in a receive buffer. Indication of when a particular transfer has completed may be
indicated by means of an interrupt or by polling a status bit.
The first byte of data transferred by the device after a start bit is the slave address. The JN5148 supports both 7-bit
and 10-bit slave addresses by generating either one or two address transfers. Only the slave with a matching address
will respond by returning an acknowledge bit.
The master interface provides a true multi-master bus including collision detection and arbitration that prevents data
corruption. If two or more masters simultaneously try to control the bus, a clock synchronization procedure
determines the bus clock. Because of the wired-AND connection of the interface, a high-to-low transition on the bus
affects all connected devices. This means a high-to-low transition on the SIF_CLK line causes all concerned devices
to count off their low period. Once the clock input of a device has gone low, it will hold the SIF_CLK line in that state
until the clock high state is reached when it releases the SIF_CLK line. Due to the wired-AND connection, the
SIF_CLK line will therefore be held low by the device with the longest low period, and held high by the device with the
shortest high period.
SIF_CLK1
SIF_CLK2
SIF_CLK
Master1 SIF_CLK
Master2 SIF_CLK
Wired-AND SIF_CLK
Start counting
low period
Start counting
high period
Wait
State
Figure 37: Multi-Master Clock Synchronisation
After each transfer has completed, the status of the device must be checked to ensure that the data has been
acknowledged correctly, and that there has been no loss of arbitration. (N.B. Loss of arbitration may occur at any
point during the transfer, including data cycles). An interrupt will be generated when arbitration has been lost.50 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
15.4 Slave Two-wire Serial Interface
When operating as a slave device, the interface does not provide a clock signal, although it may drive the clock signal
low if it is required to apply clock stretching.
Only transfers whose address matches the value programmed into the interface’s address register are accepted. The
interface allows both 7 and 10 bit addresses to be programmed, but only responds with an acknowledge to a single
address. Addresses defined as “reserved” will not be responded to, and should not be programmed into the address
register. A list of reserved addresses is shown in Table 5.
Address Name Behaviour
0000 000 General Call/Start Byte Ignored
0000 001 CBUS address Ignored
0000 010 Reserved Ignored
0000 011 Reserved Ignored
0000 1XX Hs-mode master code Ignored
1111 1XX Reserved Ignored
1111 0XX 10-bit address Only responded to if 10 bit address
set in address register
Table 5 : List of two-wire serial interface reserved addresses
Data transfer is controlled from the processor bus interface at a byte level, with the processor responsible for taking
write data from a receive buffer and providing read data to a transmit buffer when indicated. A series of interrupt
status bits are provided to control the flow of data.
For writes, in to the slave interface, it is important that data is taken from the receive buffer by the processor before
the next byte of data arrives. To enable this, the interface may be configured to work in two possible backoff modes:
• Not Acknowledge mode – where the interface returns a Not Acknowledge (NACK) to the master if more data
is received before the previous data has been taken. This will lead to the termination of the current data
transfer.
• Clock Stretching mode – where the interface holds the clock line low until the previous data has been taken.
This will occur after transfer of the next data but before issuing an acknowledge
For reads, from the slave interface, the data may be preloaded into the transmit buffer when it is empty (i.e. at the
start of day, or when the last data has been read), or fetched each time a read transfer is requested. When using data
preload, read data in the buffer must be replenished following a data write, as the transmit and received data is
contained in a shared buffer. The interface will hold the bus using clock stretching when the transmit buffer is empty.
Interrupts may be triggered when:
• Data Buffer read data is required – a byte of data to be read should be provided to avoid the interface from
clock stretching
• Data Buffer read data has been taken – this indicates when the next data may be preloaded into the data
buffer
• Data Buffer write data is available – a byte of data should be taken from the data buffer to avoid data backoff
as defined above
• The last data in a transfer has completed – i.e. the end of a burst of data, when a Stop or Restart is seen
• A protocol error has been spotted on the interface© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 51
16 Four-Wire Digital Audio Interface
The JN5148 includes a four-wire digital audio interface that can be used for interfacing to audio CODECs. The
following features are supported:
• Compatible with the industry standard I²S interface
• Option to support I²S, left justified and right justified modes
• Optional support for connection to mono sample FIFO with data transferred on the left or right channel
• Master only
• Transmit on falling edge and receive on rising edge
• Up to 8MHz maximum clock range
• Maximum system size of 32-bits, allowing up to 16-bits per channel (left or right channels)
• Option for pad bit insertion, allowing length of transfer per channel to be anything from 16 to 32 bits
• Data Transfer size range of 1 to 16-bits per channel
• Option to invert WS (normally 0 for left, but allow 1 for left instead)
• Continuous clock output option to support CODECs which use it as a clock source
• Separate input and output data lines
• Option to invert idle state of WS (to indicate left or right)
The Word Select (WS), Data In (SDIN), Clock (SCK) and Data Out (SDOUT) lines are alternate functions of DIO
lines 12,13,17 and 18 respectively.
Data transfer is always bidirectional. Data placed in the Data Buffer before a transfer command is issued will be
transmitted on SDOUT whilst the data received on SDIN will be placed in the Data Buffer at the end of the transfer.
Indication that a transfer has completed is by means of an interrupt or by polling a status bit.
Left channel data is always sent first, with MSB first on each channel. The interface will always transfer both left and
right channel data. For mono data transfer, the user should pad out the unused channel with 0’s, and ignore any data
returned on the unused channel.
The length of a data transfer is derived as follows:
• When padding is disabled – Data Transfer Length = 2 x Data Transfer Size
• When padding is enabled – Data Transfer Length = 2 x (16 + Extra Pad Length)
Timing of the 3 main modes is shown in Figure 38, Figure 39 and Figure 40. The Data Buffer shows how the data is
stored and how it will be transferred onto the interface. SD Max Size indicates how the maximum transfer size (16
with no additional padding) will transfer, whilst SD 3-bits indicates how 3 bits of data will be aligned when padding is
enabled. Received data in the Data Buffer will always be padded out with 0’s if the Data Transfer Size is less than 16-
bits, and any bits received beyond 16-bits when extra padding is used, will be discarded. In the examples, the polarity
of WS is shown with Left channel = 0, and the idle state is Right Channel. 52 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
Data Buffer Right R2 R1 R0 Left L2 L1 L0
SCK
WS
SD Max Size
SD 3-bits
MSB LSB MSB LSB
Left Right
L2 L1 L0 0 R2 R1 R0
MSB-1 MSB-2 MSB-1 MSB-2
0 0 0
Figure 38: I²S Mode
Data Buffer Right R2 R1 R0 Left L2 L1 L0
SCK
WS
SD Max Size
SD 3-bits
MSB LSB MSB LSB
Left Right
L2 L1 L0 0 R2 R1 R0
MSB-1 MSB-2 MSB-1 MSB-2
0 0 0
Figure 39: Left Justified Mode
Data Buffer Right R2 R1 R0 Left L2 L1 L0
SCK
WS
SD Max Size
SD 3-bits
MSB LSB MSB LSB
Left Right
0 L2 L1 L0 R2 R1 R0
MSB-1 MSB-1
0 0 0
Figure 40: Right Justified Mode© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 53
17 Random Number Generator
A random number generator is provided which creates a 16-bit random number each time it is invoked. Consecutive
calls can be made to build up any length of random number required. Each call takes approximately 0.25msec to
complete. Alternatively, continuous generation mode can be used where a new number is generated approximately
every 0.25msec. In either mode of operation an interrupt can be generated to indicate when the number is available,
or a status bit can be polled.
The random bits are generated by sampling the state of the 32MHz clock every 32kHz system clock edge. As these
clocks are asynchronous to each other, each sampled bit is unpredictable and hence random.54 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
18 Sample FIFO
A 10 deep FIFO is provided to buffer data between the CPU and either the four-wire digital audio interface or the
DAC/ ADC. It supports single channel input and output data, up to 16 bits wide. When used it can reduce the rate at
which the processor has to generate/process data, and this may allow more efficient operation. Interrupts can be
generated based on fill levels and also FIFO empty and full conditions. Normal configuration of the digital audio
interface or the DAC/ ADC is still required when accessing the data via the FIFO.
When used with the DAC / ADC functions a timing signal is generated by the DAC/ ADC functions to control the
transfer of data to and from the FIFO and the analogue peripherals. The transfers will occur at the sample rate
configured within the DAC / ADC functions.
When the FIFO is linked to the four-wire digital audio interface, timer 2 must be used to generate an internal timing
signal to control the flow of data across the interface. The timer does not require any external pins to be enabled. The
timer should be set up to produce a PWM output with a rising edge generated every time a digital audio transfer is
required. The transfer rate is typically configured to be the audio sample rate, e.g. 8kHz. If the transfer rate is too fast
or slow data will be transferred correctly between the FIFO and the digital audio block.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 55
19 Intelligent Peripheral Interface
The Intelligent Peripheral (IP) Interface is provided for systems that are more complex, where there is a processor
that requires a wireless peripheral. As an example, the JN5148 may provide a complete JenNet or ZigBee PRO
wireless network interface to a phone, computer, PDA, set-top box or games console. No resources are required from
the main processor compared to a transceiver as the complete wireless protocol may be run on the internal JN5148
CPU. The wireless peripheral may be controlled via one of the UARTs but the IP interface is intended to provide a
high-speed, low-processor-overhead interface.
The intelligent peripheral interface is a SPI slave interface and uses pins shared with other DIO signals. The
interface is designed to allow message passing and data transfer. Data received and transmitted on the IP interface
is copied directly to and from a dedicated area of memory without intervention from the CPU. This memory area, the
intelligent peripheral memory block, contains 64 32-bit word receive and transmit buffers.
JN5148
Intelligent
Peripheral
Interface SPI
MASTER
System Processor
(e.g. in cellphone, computer)
CPU
IP_DO SPIMISO
IP_INT SPIINT
IP_DI SPIMOSI
IP_SEL SPISEL
IP_CLK SPICLK
Figure 41: Intelligent Peripheral Connection
The interface functions as a SPI slave. It is possible to select the clock edge of IP_CLK on which data on the IP_DIN
line of the interface is sampled, and the state of data output IP_DOUT is changed. The order of transmission is MSB
first. The IP_DO data output is tri-stated when the device is inactive, i.e. the device is not selected via IP_SEL. An
interrupt output line IP_INT is available so that the JN5148 can indicate to an external master that it has data to
transfer. The interface can be clocked at up to 8MHz
The IP interface signals IP_CLK, IP_DO, IP_DI, IP_SEL, IP_INT are alternate functions of pins DIO14 to 18
respectively.
19.1 Data Transfer Format
Transfers are started by the remote processor asserting the IP_SEL line and terminated by the remote processor deasserting
IP_SEL.
Data transfers are bi-directional and traffic in both directions has a format of status byte, data length byte (of the
number of 32-bit words to transfer) and data packet (from the receive and transmit buffers), as shown in Figure 42
The first byte transferred into the JN5148 is a status byte with the format shown in Table 6. This is followed by a
padding byte that should be set to zero. The first byte output by the JN5148 is a padding byte, that should be ignored,
followed by a status byte with the format shown in Table 6
Bit Field Description
7:2 RSVD Reserved, set to 0
1 TXQ 1: Data queued for transmission
0 RXRDY 1: Buffer ready to receive data
Table 6: IP Status Byte Format56 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
If data is queued for transmission and the recipient has indicated that they are ready for it (RXRDY in incoming status
byte was 1), the next byte to be transmitted is the data length in words (N). If either the JN5148 or the remote
processor has no data to transfer, then the data length should be set to zero. The transaction can be terminated by
the master after the status and padding bytes have been sent if it is not possible to send data in either direction. This
may be because neither party has data to send or because the receiver does not have a buffer available. If the data
length is non-zero, the data in the JN5148 transmit memory buffer is sent, beginning at the start of the buffer. At the
same time that data bytes are being sent from the transmit buffer, the JN5148 receive buffer is being filled with
incoming data, beginning from the start of the buffer.
The remote processor, acting as the master, must determine the larger of its incoming or outgoing data transfers and
deassert IP_SEL when all of the transmit and receive data has been transferred. The data is transferred into or out of
the buffers starting from the lowest address in the buffer, and each word is assembled with the MSB first on the serial
data lines. Following a transaction, IP_SEL must be high (deasserted) for at least 400nsec before a further
transaction can begin.
IP_SEL
IP_CLK
IP_DI Status (8-bit) N words of data
IP_DO
data length or 0s (8-bit)
padding (8-bit) Status (8-bit) data length or 0s (8-bit) N words of data
padding (8-bit)
Figure 42: Intelligent Peripheral Data Transfer Waveforms
The N words of data transferred on the interface are also formatted. The first three bytes, of the first word, must be
zero. These are followed by a one byte length field that must be one less than the data length shown in the data
length field in Figure 42, i.e. N-1. Following this are the (N-1) words of data.
The application running on the JN5148 has high level software functions for sending and receiving data on this
interface. The function of generating and interpreting the individual bytes on the interface is handled by hardware
within the device. The remote processor must generate, and interpret, the signals in the interface. For instance, this
may be done with a configurable SPI master interface.
19.2 JN5148 (Slave) Initiated Data Transfer
To send data, the data is written into either buffer 0 or 1 of the intelligent peripheral memory area. Then the buffer
number is written together with the data length. If the call is successful, the interrupt line IP_INT will signal to the
remote processor that there is a message ready to be sent from the JN5148. When a remote processor starts a
transfer to the JN5148 by deasserting IP_SEL, then IP_INT is deasserted. If the transfer is unsuccessful and the
data is not output then IP_INT is reasserted after the transfer to indicate that data is still waiting to be sent.
The interface can be configured to generate an internal interrupt whenever a transaction completes (for example
IP_SEL becomes inactive after a transfer starts). It is also possible to mask the interrupt. The end of the
transmission can be signalled by an interrupt, or the interface can be polled.
To receive data the interface must be firstly initialised and when this is done, the bit RXRDY sent in the status byte
from the IP block will show that data can be received by the JN5148. Successful data arrival can be indicated by an
interrupt, or the interface can be polled. IP_INT is asserted if the JN5148 is configured to be able to receive, and the
remote processor has previously attempted to send data but the RXRDY indicated that it could not be sent.
To send and receive at the same time, the transmit and receive buffers must be set to be different.
19.3 Remote (Master) Processor Initiated Data Transfer
The remote processor (master) must initiate a transfer to send data to the JN5148 (slave) by asserting the slave
select pin, IP_SEL, and generating its status byte on IP_DI with TXRDY set. After receiving the status byte from the
JN5148, the master should check that the JN5148 has a buffer ready by reading the RXRDY bit of the received
status byte. If the RXRDY bit is 0 indicating that the JN5148 cannot accept data, it must terminate the transfer by
deasserting IP_SEL unless it is receiving data from the JN5148. If the RXRDY bit is 1, indicating that the JN5148 can
accept data, then the master should generate a further 8 clocks on IP_CLK in order to transfer its own message
length on IP_DI. The master must continue clocking the interface until sufficient clocks have been generated to send © NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 57
all the data specified in the length field to the JN5148. The master must then deassert IP_SEL to show the transfer
is complete.
The master may initiate a transfer to read data from the JN5148 by asserting the slave select pin, IP_SEL, and
generating its status byte on IP_DI with RXRDY set. After receiving the status byte from the JN5148, it should check
that the JN5148 has a buffer ready by reading the TXRDY bit of the received status byte. If the TXRDY bit is 0,
indicating that the JN5148 does not have data to send, it must terminate the transfer by deasserting IP_SEL unless it
is transmitting data to the JN5148. If the TXRDY bit is 1, indicating that the JN5148 can send data, then the master
must generate a further 8 clocks on IP_CLK in order to receive the message length on IP_DO. The master must
continue clocking the interface until sufficient clocks have been generated to receive all the data specified in the
length field from the JN5148. The master should then deassert IP_SEL to show the transfer is complete.
Data can be sent in both directions at once and the master must ensure both transfers have completed before
deasserting IP_SEL.58 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
20 Analogue Peripherals
The JN5148 contains a number of analogue peripherals allowing the direct connection of a wide range of external
sensors, switches and actuators.
ADC
DAC1
DAC2
VREF
Chip
Boundary
Internal Reference
Processor Bus
Supply Voltage
(VDD1)
Vref select
Temp
Sensor
Comparator 2
Comparator 1
COMP2M
COMP1M
COMP1P
COMP2P
DAC1
DAC2
ADC1
ADC2
ADC3
ADC4
Vref
Figure 43: Analogue Peripherals
In order to provide good isolation from digital noise, the analogue peripherals are powered by a separate regulator,
supplied from the analogue supply VDD1 and referenced to analogue ground VSSA.
A common reference Vref for the ADC and DAC can be selected between an internal bandgap reference or an
external voltage reference supplied to the VREF pin. Gain settings for the ADC and DAC are independent of each
other.
The ADC and DAC are clocked from a common clock source derived from the 16MHz clock© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 59
20.1 Analogue to Digital Converter
The 12-bit analogue to digital converter (ADC) uses a successive approximation design to perform high accuracy
conversions as typically required in wireless sensor network applications. It has six multiplexed single-ended input
channels: four available externally, one connected to an internal temperature sensor, and one connected to an
internal supply monitoring circuit.
20.1.1 Operation
The input range of the ADC can be set between 0V to either the reference voltage or twice the reference voltage.
The reference can be either taken from the internal voltage reference or from the external voltage applied to the
VREF pin. For example, an external reference of 1.2V supplied to VREF may be used to set the ADC range between
0V and 2.4V.
VREF Gain Setting Maximum Input Range Supply Voltage Range (VDD)
1.2V
1.6V
1.2V
1.6V
0
0
1
1
1.2V
1.6V
2.4V
3.2V
2.2V - 3.6V
2.2V - 3.6V
2.6V - 3.6V
3.4V - 3.6V
Table 7 ADC/DAC Maximum Input Range
The input clock to the ADC is 16MHz and can be divided down to 2MHz, 1MHz, 500kHz and 250kHz. During an ADC
conversion the selected input channel is sampled for a fixed period and then held. This sampling period is defined as
a number of ADC clock periods and can be programmed to 2, 4, 6 or 8. The conversion rate is ((3 x Sample period)
+ 14) clock periods. For example for 500kHz conversion with sample period of 2 will be (3 x 2) + 14 = 20 clock
periods, 40usecs or 25kHz. . The ADC can be operated in either a single conversion mode or alternatively a new
conversion can be started as soon as the previous one has completed, to give continuous conversions.
If the source resistance of the input voltage is 1kΩ or less, then the default sampling time of 2 clocks should be used.
The input to the ADC can be modelled as a resistor of 5kΩ(typ) and 10kΩ (max) to represent the on-resistance of the
switches and the sampling capacitor 8pF. The sampling time required can then be calculated, by adding the sensor
source resistance to the switch resistance, multiplying by the capacitance giving a time constant. Assuming normal
exponential RC charging, the number of time constants required to give an acceptable error can be calculated, 7 time
constants gives an error of 0.1%, so for 12-bit accuracy 10 time constants should be the target. For a source with
zero resistance, 10 time constants is 800 nsecs, hence the smallest sampling window of 2 clock periods can be used.
ADC
pin
5 K
8 pF
Sample
Switch
ADC
front
end
Figure 44 ADC Input Equivalent Circuit
The ADC sampling period, input range and mode (single shot or continuous) are controlled through software.
When the ADC conversion is complete, an interrupt is generated. Alternatively the conversion status can be polled.
When operating in continuous mode, it is recommended that the interrupt is used to signal the end of a conversion,
since conversion times may range from 10 to 152 µsecs. Polling over this period would be wasteful of processor
bandwidth.
To facilitate averaging of the ADC values, which is a common practice in microcontrollers, a dedicated accumulator
has been added, the user can define the accumulation to occur over 2,4,8 or 16 samples. The end of conversion 60 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
interrupt can be modified to occur at the end of the chosen accumulation period, alternatively polling can still be used.
Software can then be used to apply the appropriate rounding and shifting to generate the average value, as well as
setting up the accumulation function.
For detailed electrical specifications, see section 22.3.8.
20.1.2 Supply Monitor
The internal supply monitor allows the voltage on the analogue supply pin VDD1 to be measured. This is achieved
with a potential divider that reduces the voltage by a factor of 0.666, allowing it to fall inside the input range of the
ADC when set with an input range twice the internal voltage reference. The resistor chain that performs the voltage
reduction is disabled until the measurement is made to avoid a continuous drain on the supply.
20.1.3 Temperature Sensor
The on chip temperature sensor can be used either to provide an absolute measure of the device temperature or to
detect changes in the ambient temperature. In common with most on chip temperature sensors, it is not trimmed and
so the absolute accuracy variation is large; the user may wish to calibrate the sensor prior to use. The sensor forces
a constant current through a forward biased diode to provide a voltage output proportional to the chip die temperature
which can then be measured using the ADC. The measured voltage has a linear relationship to temperature as
described in section 22.3.15.
Because this sensor is on chip, any measurements taken must account for the thermal time constants. For example,
if the device just came out of sleep mode the user application should wait until the temperature has stabilised before
taking a measurement.
20.2 Digital to Analogue Converter
The Digital to Analogue Converter (DAC) provides two output channels and is capable of producing voltages of 0 to
Vref or 0 to 2Vref where Vref is selected between the internal reference and the VREF pin, with a resolution of 12-bits
and a minimum conversion time of 10µsecs (2MHz clock).
20.2.1 Operation
The output range of each DAC can be set independently to swing between 0V to either the reference voltage or twice
the reference voltage. The reference voltage is selected from the internal reference or the VREF pin. For example,
an external reference of 0.8V supplied to VREF may be used to set DAC1 maximum output of 0.8V and DAC2
maximum output of 1.6V.
The DAC output amplifier is capable of driving a capacitive load up to that specified in section 22.3.9
Programmable clock periods allow a trade-off between conversion speed and resolution. The full 12-bit resolution is
achieved with the 250kHz clock rate. See section 22.3.9 electrical characteristics, for more details.
The conversion period of the DACs are given by the same formula as the ADC conversion time and so can vary
between 10 and 152uS. The DAC values may be updated at the same time as the ADC is active.
The clock divider ratio, interrupt enable and reference voltage select are all controlled through software, options
common to both the ADC and DAC. The DAC output range and initial value can be set and the subsequent updates
provided by updating only the DAC value. Polling is available to determine if a DAC channel is busy performing a
conversion. The DAC can be disabled which will power down the DAC cell.
Simultaneous conversions with DAC1 and DAC2 are possible. To use both DACs at the same time it is only
necessary to enable them and supply the digital values via the software. The DACs should not be used in single shot
mode, but continuous conversion mode only, in order to maintain a steady output voltage. © NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 61
20.3 Comparators
The JN5148 contains two analogue comparators COMP1 and COMP2 that are designed to have true rail-to-rail
inputs and operate over the full voltage range of the analogue supply VDD1. The hysteresis level (common to both
comparators) can be set to a nominal value of 0mV, 10mV, 20mV or 40mV. In addition, the source of the negative
input signal for each comparator (COMP1M and COMP2M) can be set to the internal voltage reference, the output of
DAC1 or DAC2 (COMP1 or COMP2 respectively) or the appropriate external pin. The comparator outputs are routed
to internal registers and can be polled, or can be used to generate interrupts. The comparators can be disabled to
reduce power consumption.
The comparators have a low power mode where the response time of the comparator is slower than normal and is
specified in section 22.3.10. This mode may be used during non-sleep operation however it is particularly useful in
sleep mode to wake up the JN5148 from sleep where low current consumption is important. The wakeup action and
the configuration for which edge of the comparator output will be active are controlled through software. In sleep
mode the negative input signal source, must be configured to be driven from the external pins.62 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
21 Power Management and Sleep Modes
21.1 Operating Modes
Three operating modes are provided in the JN5148 that enable the system power consumption to be controlled
carefully to maximise battery life.
• Active Processing Mode
• Sleep Mode
• Deep Sleep Mode
The variation in power consumption of the three modes is a result of having a series of power domains within the chip
that may be controllably powered on or off.
21.1.1 Power Domains
The JN5148 has the following power domains:
• VDD Supply Domain: supplies the wake-up timers and controller, DIO blocks, Comparators, 32kHz RC and
crystal oscillators. This domain is driven from the external supply (battery) and is always powered. The wake-up
timers and controller, and the 32kHz RC and crystal oscillators may be powered on or off in sleep mode through
software control.
• Digital Logic Domain: supplies the digital peripherals, CPU, ROM, Baseband controller, Modem and Encryption
processor. It is powered off during sleep mode.
• Analogue Domain: supplies the ADC, DACs and the temperature sensor. It is powered off during sleep mode
and may be powered on or off in active processing mode through software control.
• RAM Domain: supplies the RAM during sleep mode to retain the memory contents. It may be powered on or off
for sleep mode through software control.
• Radio Domain: supplies the radio interface. It is powered during transmit and receive and controlled by the
baseband processor. It is powered off during sleep mode.
The current consumption figures for the different modes of operation of the device is given in section 22.2.2.
21.2 Active Processing Mode
Active processing mode in the JN5148 is where all of the application processing takes place. By default, the CPU will
execute at the selected clock speed executing application firmware. All of the peripherals are available to the
application, as are options to actively enable or disable them to control power consumption; see specific peripheral
sections for details.
Whilst in Active processing mode there is the option to doze the CPU but keep the rest of the chip active; this is
particularly useful for radio transmit and receive operations, where the CPU operation is not required therefore saving
power.
21.2.1 CPU Doze
Whilst in doze mode, CPU operation is stopped but the chip remains powered and the digital peripherals continue to
run. Doze mode is entered through software and is terminated by any interrupt request. Once the interrupt service
routine has been executed, normal program execution resumes. Doze mode uses more power than sleep and deep
sleep modes but requires less time to restart and can therefore be used as a low power alternative to an idle loop.
Whilst in CPU doze the current associated with the CPU is not consumed, therefore the basic device current is
reduced as shown in the figures in section 22.2.2.1.
21.3 Sleep Mode
The JN5148 enters sleep mode through software control. In this mode most of the internal chip functions are
shutdown to save power, however the state of DIO pins are retained, including the output values and pull-up enables, © NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 63
and this therefore preserves any interface to the outside world. The DAC outputs are placed into a high impedance
state.
When entering into sleep mode, there is an option to retain the RAM contents throughout the sleep period. If the
wakeup timers are not to be used for a wakeup event and the application does not require them to run continually,
then power can be saved by switching off the 32kHz oscillator if selected as the system clock through software
control. The oscillator will be restarted when a wakeup event occurs.
Whilst in sleep mode one of four possible events can cause a wakeup to occur: transitions on DIO inputs, expiry of
wakeup timers, pulse counters maturing or comparator events. If any of these events occur, and the relevant
interrupt is enabled, then an interrupt is generated that will cause a wakeup from sleep. It is possible for multiple
wakeup sources to trigger an event at the same instant and only one of them will be accountable for the wakeup
period. It is therefore necessary in software to remove all other pending wakeup events prior to requesting entry back
into sleep mode; otherwise, the device will re-awaken immediately.
When wakeup occurs, a similar sequence of events to the reset process described in section 6.1 happens, including
the checking of the supply voltage by the Brown Out Detector 6.4. The 32MHz oscillator is started up, once stable
the power to CPU system is enabled and the reset is removed. Software determines that this is a reset from sleep
and so commences with the wakeup process. If RAM contents were held through sleep, wakeup is quicker as the
application program does not have to be reloaded from Flash memory. See section 22.3.6 for wake-up timings.
21.3.1 Wakeup Timer Event
The JN5148 contains two 35-bit wakeup timers that are counters clocked from the 32kHz oscillator, and can be
programmed to generate a wake-up event. Following a wakeup event, the timers continue to run. These timers are
described in section 11.3.
Timer events can be generated from both of the two timers; one is intended for use by the 802.15.4 protocol, the
other being available for use by the Application running on the CPU. These timers are available to run at any time,
even during sleep mode.
21.3.2 DIO Event
Any DIO pin when used as an input has the capability, by detecting a transition, to generate a wake-up event. Once
this feature has been enabled the type of transition can be specified (rising or falling edge). Even when groups of
DIO lines are configured as alternative functions such as the UARTs or Timers etc, any input line in the group can still
be used to provide a wakeup event. This means that an external device communicating over the UART can wakeup
a sleeping device by asserting its RTS signal pin (which is the CTS input of the JN5148).
21.3.3 Comparator Event
The comparator can generate a wakeup interrupt when a change in the relative levels of the positive and negative
inputs occurs. The ability to wakeup when continuously monitoring analogue signals is useful in ultra-low power
applications. For example, the JN5148 can remain in sleep mode until the voltage drops below a threshold and then
be woken up to deal with the alarm condition.
21.3.4 Pulse Counter
The JN5148 contains two 16 bit pulse counters that can be programmed to generate a wake-up event. Following the
wakeup event the counters will continue to operate and therefore no pulse will be missed during the wake-up
process. These counters are described in section 12.
To minimise sleep current it is possible to disable the 32K RC oscillator and still use the pulse counters to cause a
wake-up event, provided debounce mode is not required.
21.4 Deep Sleep Mode
Deep sleep mode gives the lowest power consumption. All switchable power domains are off and certain functions in
the VDD supply power domain, including the 32kHz oscillator are stopped. This mode can be exited by a power
down, a hardware reset on the RESETN pin, or a DIO event. The DIO event in this mode causes a chip reset to
occur.64 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
22 Electrical Characteristics
22.1 Maximum Ratings
Exceeding these conditions may result in damage to the device.
Parameter Min Max
Device supply voltage VDD1, VDD2 -0.3V 3.6V
Supply voltage at voltage regulator bypass pins
VB_xxx
-0.3V 1.98V
Voltage on analogue pins XTALOUT, XTALIN,
VCOTUNE, RF_IN.
-0.3V VB_xxx + 0.3V
Voltage on analogue pins VREF, ADC1-4, DAC1-2,
COMP1M, COMP1P, COMP2M, COMP2P, IBIAS
-0.3V VDD1 + 0.3V
Voltage on 5v tolerant digital pins SPICLK,
SPIMOSI, SPIMISO, SPISEL0, DIO0-8 & DIO11-20,
RESETN
-0.3V Lower of (VDD2 + 2V)
and 5.5V
Voltage on 3v tolerant digital pins DIO9, DIO10 -0.3V VDD2 + 0.3V
Storage temperature -40ºC 150ºC
Reflow soldering temperature according to
IPC/JEDEC J-STD-020C
260ºC
ESD rating 4 Human Body Model 1 2.0kV
Charged Device Model 2 500V
1) Testing for Human Body Model discharge is performed as specified in JEDEC Standard JESD22-A114.
2) Testing for Charged Device Model discharge is performed as specified in JEDEC Standard JESD22-C101.
22.2 DC Electrical Characteristics
22.2.1 Operating Conditions
Supply Min Max
VDD1, VDD2 2.0V 3.6V
Ambient temperature range -40ºC 85ºC© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 65
22.2.2 DC Current Consumption
VDD = 2.0 to 3.6V, -40 to +85º C
22.2.2.1 Active Processing
Mode: Min Typ Max Unit Notes
CPU processing
32,16,8 or 4MHz
1600 +
280/MHz
µA SPI, GPIOs enabled. When in
CPU doze the current related to
CPU speed is not consumed.
Radio transmit 15.0 mA CPU in software doze – radio
transmitting
Radio receive 17.5 mA CPU in software doze – radio in
receive mode
The following current figures should be added to those above if the feature is being used
ADC 655 µA Temperature sensor and battery
measurements require ADC
DAC 215 / 235 µA One / both
Comparator 73 / 0.8 µA Normal / low-power
UART 90 µA For each UART
Timer 30 µA For each Timer
2-wire serial interface 70 µA
22.2.2.2 Sleep Mode
Mode: Min Typ Max Unit Notes
Sleep mode with I/O wakeup 0.12 µA Waiting on I/O event
Sleep mode with I/O and RC
Oscillator timer wakeup –
measured at 25ºC
1.25 µA As above, but also waiting on timer
event. If both wakeup timers are
enabled then add another 0.05µA
32kHz crystal oscillator 1.5 µA As alternative sleep timer
The following current figures should be added to those above if the feature is being used
RAM retention– measured at
25ºC
2.2 µA For full 128kB retained
Comparator (low-power mode) 0.8 µA Reduced response time
22.2.2.3 Deep Sleep Mode
Mode: Min Typ Max Unit Notes
Deep sleep mode– measured
at 25ºC
100 nA Waiting on chip RESET or I/O
event66 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
22.2.3 I/O Characteristics
VDD = 2.0 to 3.6V, -40 to +85º C
Parameter Min Typ Max Unit Notes
Internal DIO pullup
resistors
22
24
31
35
34
40
56
63
53
63
92
104
kΩ VDD2 = 3.6V, 25C
VDD2 = 3.0V, 25C
VDD2 = 2.2V, 25C
VDD2 = 2.0V, 25C
Digital I/O High Input
(except DIO9, DIO10)
VDD2 x 0.7 Lower of (VDD2 + 2V)
and 5.5V
V 5V Tolerant I/O only
Digital I/O High Input
( DIO9, DIO10)
VDD2 x 0.7 VDD2 V
Digital I/O low Input -0.3 VDD2 x 0.27 V
Digital I/O input hysteresis 140 230 310 mV
DIO High O/P (2.7-3.6V) VDD2 x 0.8 VDD2 V With 4mA load
DIO Low O/P (2.7-3.6V) 0 0.4 V With 4mA load
DIO High O/P (2.2-2.7V) VDD2 x 0.8 VDD2 V With 3mA load
DIO Low O/P (2.2-2.7V) 0 0.4 V With 3mA load
DIO High O/P (2.0-2.2V) VDD2 x 0.8 VDD2 V With 2.5mA load
DIO Low O/P (2.0-2.2V) 0 0.4 V With 2.5mA load
Current sink/source
capability
4
3
2.5
mA VDD2 = 2.7V to 3.6V
VDD2 = 2.2V to 2.7V
VDD2 = 2.0V to 2.2V
IIL - Input Leakage Current 50 nA Vcc = 3.6V, pin low
IIH - Input Leakage Current 50 nA Vcc = 3.6V, pin high
22.3 AC Characteristics
22.3.1 Reset and Voltage Brown-Out
RESETN
Internal RESET
VDD
VPOT
t
STAB
Figure 45: Internal Power-on Reset without showing Brown-Out© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 67
Internal RESET
RESETN VRST
t
STAB
t
RST
Figure 46: Externally Applied Reset
VDD = 2.0 to 3.6V, -40 to +85º C
Parameter Min Typ Max Unit Notes
External Reset pulse width
to initiate reset sequence
(tRST)
1 µs Assumes internal pullup
resistor value of 100K
worst case and ~5pF
external capacitance
External Reset threshold
voltage (VRST)
VDD2 x 0.7 V Minimum voltage to
avoid being reset
Internal Power-on Reset
threshold voltage (VPOT)
1.47
1.42
V Rising
Falling
Reset stabilisation time
(tSTAB)
0.84 ms Note 1
Brown-out Threshold
Voltage (VTH)
1.87
2.16
2.54
2.83
1.95
2.25
2.65
2.95
2.01
2.32
2.73
3.04
V Configurable threshold
with 4 levels
Brown-out Hysteresis
(VHYS)
45
60
85
100
mV Corresponding to the 4
threshold levels
1 Time from release of reset to start of executing ROM code. Loading program from Flash occurs in addition to this.
VTH + VHYS
VTH
DVDD
Internal POR
Internal BOReset
VPOT
Figure 47: Power on Reset followed by Brown-out Detect68 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
22.3.2 SPI MasterTiming
t t SSH SSS
t
CK
t
SI
t
HI
MOSI
(mode=1,3)
SS
MOSI
(mode=0,2)
MISO
(mode=0,2)
MISO
(mode=1,3)
t
VO
t
VO
CLK
(mode=0,1)
t
SI
t
HI
CLK
(mode=2,3)
Figure 48: SPI Timing (Master)
Parameter Symbol Min Max Unit
Clock period tCK 62.5 - ns
Data setup time tSI 16.7 @ 3.3V
18.2 @ 2.7V
21.0 @ 2.0V
- ns
Data hold time tHI 0 ns
Data invalid period tVO - 15 ns
Select set-up period tSSS 60 - ns
Select hold period tSSH 30 (SPICLK = 16MHz)
0 (SPICLK<16MHz, mode=0 or 2)
60 (SPICLK<16MHz, mode=1 or 3)
- ns
22.3.3 Intelligent Peripheral (SPI Slave) Timing
IP_SEL
IP_CLK
IP_DI
IP_DO
t
si t
hi
t
vo
t
sss
t t ssh ck
t
lz t
hz
Figure 49: Intelligent Peripheral (SPI Slave) Timing© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 69
Parameter Symbol Min Max Unit
Clock period tck 125.0 - ns
Data setup time tsi 15 - ns
Data hold time thi 15 ns
Data invalid period tvo - 40 ns
Select set-up period tsss 15 - ns
Select hold period tssh 15 - ns
Select asserted to output data driven tlz 20 ns
Select negated to data output tri-stated thz 20 ns
22.3.4 Two-wire Serial Interface
t
BUF
S Sr P S
t
LOW
t
HD;STA
t
F t
R
t
HD;DAT
t
HIGH
t
SU;DAT
t
SU;STA
t
HD;STA
t
SU;STO
t
SP t
R
t
F
SIF_D
SIF_CLK
Figure 50: Two-wire Serial Interface Timing
Parameter Symbol
Standard Mode Fast Mode
Unit
Min Max Min Max
SIF_CLK clock frequency fSCL 0 100 0 400 kHz
Hold time (repeated) START condition.
After this period, the first clock pulse is
generated
tHD:STA 4 - 0.6 - µs
LOW period of the SIF_CLK clock tLOW 4.7 - 1.3 - µs
HIGH period of the SIF_CLK clock tHIGH 4 - 0.6 - µs
Set-up time for repeated START condition tSU:STA 4.7 - 0.6 - µs
Data setup time SIF_D tSU:DAT 0.25 - 0.1 - µs
Rise Time SIF_D and SIF_CLK tR - 1000 20+0.1Cb 300 ns
Fall Time SIF_D and SIF_CLK tF - 300 20+0.1Cb 300 ns
Set-up time for STOP condition tSU:STO 4 - 0.6 - µs
Bus free time between a STOP and START
condition
tBUF 4.7 - 1.3 - µs
Pulse width of spikes that will be
suppressed by input filters (Note 1)
tSP - 60 - 60 ns
Capacitive load for each bus line Cb - 400 - 400 pF
Noise margin at the LOW level for each
connected device (including hysteresis)
Vnl 0.1VDD - 0.1VDD - V
Noise margin at the HIGH level for each
connected device (including hysteresis)
Vnh 0.2VDD - 0.2VDD - V
Note 1: This figure indicates the pulse width that is guaranteed to be suppressed. Pulse with widths up to 125nsec
may alos get suppressed.70 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
22.3.5 Four-Wire Digital Audio Interface
SCK
WS/SDOUT
SDIN
t
ck
t
dtr
t
sr t
hr
t
hc t
lc
Parameter Symbol
Maximum
Frequency (8MHz) Generic
Unit
Min Max Min Max
DAI_SCK clock period tck 125 - 125 - ns
LOW period of the DAI_SCK clock tlc 43 - 0.35tck - ns
HIGH period of the DAI_SCK clock thc 43 - 0.35tck - ns
Transmit delay time tdtr - 50 - 0.4tck ns
Receive set-up time tsr 25 - 0.2tck - ns
Receive hold time thr 0 - 0 - ns
22.3.6 Wakeup and Boot Load Timings
Parameter Min Typ Max Unit Notes
Time for crystal to stabilise
ready for Boot Load
0.84 ms Reached oscillator
amplitude threshold
Time for crystal to stabilise
ready for radio activity
1.0 ms
Wake up from Deep Sleep
or from Sleep (memory not
held)
0.84 + 0.5*
program size in
kBytes
ms Assumes SPI clock to
external Flash is
16MHz
Wake up from Sleep
(memory held)
0.84 ms
Wake up from CPU Doze
mode
0.2 µs
Wake up from Sleep using
24MHz RC oscillator
(memory held)
0.29 ms© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 71
22.3.7 Bandgap Reference
VDD = 2.0 to 3.6V, -40 to +85ºC
Parameter Min Typ Max Unit Notes
Voltage 1.156 1.192 1.216 V
DC power supply rejection 58 dB at 25ºC
Temperature coefficient -35
+30
ppm/ºC 20 to 85ºC
-40ºC to 20ºC
Point of inflexion +25 ºC
22.3.8 Analogue to Digital Converters
VDD = 3.0V, VREF = 1.2V, -40 to +85ºC
Parameter Min Typ Max Unit Notes
Resolution 12 bits 500kHz Clock
Current consumption 655 µA
Integral nonlinearity ± 5 LSB 0 to Vref range
Differential nonlinearity -1 +2 LSB Guaranteed monotonic
Offset error + 10 mV
Gain error - 20 mV
Internal clock 500 kHz 16MHz input clock, ÷32
No. internal clock periods
to sample input
2, 4, 6 or 8 Programmable
Conversion time 40 µs 500kHz Clock with
sample period of 2
Input voltage range 0.04 Vref
or 2*Vref
V Switchable. Refer to
20.1.1
Vref (Internal) See Section 22.3.7 Bandgap Reference
Vref (External) 1.15 1.2 1.6 V Allowable range into
VREF pin
Input capacitance 8 pF In series with 5K ohms72 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
22.3.9 Digital to Analogue Converters
VDD = 3.0V, VREF = 1.2V, -40 to +85ºC
Parameter Min Typ Max Unit Notes
Resolution 12 bits
Current consumption 215 (single)
235 (both)
µA
Integral nonlinearity ± 2 LSB
Differential nonlinearity -1 +1 LSB Guaranteed monotonic
Offset error ± 10 mV
Gain error ± 10 mV
Internal clock 2MHz,
1MHz,
500kHz,
250kHz
16MHz input clock,
programmable
prescaler
Output settling time to
0.5LSB
5 µs With 10k ohms & 20pF
load
Minimum Update time 10 µs 2MHz Clock with
sample period of 2
Output voltage swing 0 Lower of Vdd-1.2 and Vref V Output voltage swing
Gain =0
Output voltage swing 0 Lower of 2x(Vdd-1.2 ) and
Vdd-0.2 and 2xVref
V Output voltage swing
Gain =1
Vref (Internal) See Section 22.3.7 Bandgap Reference
VREF (External) 0.8 1.2 1.6 V Allowable range into
VREF pin
Resistive load 10 kΩ To ground
Capacitive load 20 pF
Digital input coding Binary© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 73
22.3.10 Comparators
VDD = 2.0 to 3.6V -40 to +85ºC
Parameter Min Typ Max Unit Notes
Analogue response time
(normal)
80 125 ns +/- 250mV overdrive
10pF load
Total response time
(normal) including delay to
Interrupt controller
105 + 125 ns Digital delay can be
up to a max. of two
16MHz clock periods
Analogue response time
(low power)
2.4 µs +/- 250mV overdrive
No digital delay
Hysteresis 4
12
28
10
20
40
16
26
50
mV Programmable in 3
steps and zero
Vref (Internal) See Section 22.3.7 Bandgap Reference V
Common Mode input range 0 Vdd V
Current (normal mode) 54 73 102 µA
Current (low power mode) 0.8 µA
22.3.11 32kHz RC Oscillator
VDD = 2.0 to 3.6V, -40 to +85 ºC
Parameter Min Typ Max Unit Notes
Current consumption of cell
and counter logic
1.45
1.25
1.05
µA 3.6V
3.0V
2.0V
32kHz clock native
accuracy
-30% 32kHz +30% Typical is at 3.0V 25°C
Calibrated 32kHz accuracy ±250 ppm For a 1 second sleep
period calibrating over
20 x 32kHz clock
periods
Variation with temperature -0.010 %/°C
Variation with VDD2 -1.1 %/V74 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
22.3.12 32kHz Crystal Oscillator
VDD = 2.0 to 3.6V, -40 to +85ºC
Parameter Min Typ Max Unit Notes
Current consumption of cell
and counter logic
1.5 µA This is sensitive to the ESR
of the crystal,Vdd and total
capacitance at each pin
Start – up time 0.8 s Assuming xtal with ESR of
less than 40kohms and
CL= 9pF External caps =
15pF
(Vdd/2mV pk-pk) see
Appendix B
Input capacitance 1.4 pF Bondpad and package
Transconductance 17 uA/V
External Capacitors
(CL=9pF)
15 pF Total external capacitance
needs to be 2*CL, allowing
for stray capacitance from
chip, package and PCB
Amplitude at Xout Vdd-0.2 Vp-p
22.3.13 32MHz Crystal Oscillator
VDD = 2.0 to 3.6V, -40 to +85ºC
Parameter Min Typ Max Unit Notes
Current consumption 300 375 450 µA Excluding bandgap ref.
Start – up time 0.84 ms Assuming xtal with ESR of
less than 40ohms and CL=
9pF External caps = 15pF
see Appendix B
Input capacitance 1.4 pF Bondpad and package
Transconductance 3.65 4.30 5.16 mA/V
DC voltages, XTALIN /
XTALOUT
390/425 425/465 470/520 mV
External Capacitors
(CL=9pF)
15 pF Total external capacitance
needs to be 2*CL, allowing
for stray capacitance from
chip, package and PCB
Amplitude detect threshold 320 mVp-p Threshold detection
accessible via API© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 75
22.3.14 24MHz RC Oscillator
VDD = 2.0 to 3.6V, -40 to +85ºC
Parameter Min Typ Max Unit Notes
Current consumption of cell 160 µA
Clock native accuracy -22% 24MHz +28%
Calibrated centre frequency
accuracy
-7% 24MHz +7%
Variation with temperature -0.015 %/°C
Variation with VDD2 0.15 %/V
Startup time 1 us
22.3.15 Temperature Sensor
VDD = 2.0 to 3.6V, -40 to +85ºC
Parameter Min Typ Max Unit Notes
Operating Range -40 - 85 °C
Sensor Gain -1.44 -1.55 -1.66 mV/°C
Accuracy - - ±10 °C
Non-linearity - - 2.5 °C
Output Voltage 630 855 mV Includes absolute variation
due to manufacturing & temp
Typical Voltage 745 mV Typical at 3.0V 25°C
Resolution 0.154 0.182 0.209 °C/LSB 0 to Vref ADC I/P Range76 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
22.3.16 Radio Transceiver
This JN5148 meets all the requirements of the IEEE802.15.4 standard over 2.0 - 3.6V and offers the following
improved RF characteristics. All RF characteristics are measured single ended.
This part also meets the following regulatory body approvals, when used with NXP’s Module Reference Designs.
Compliant with FCC part 15, rules, IC Canada, ETSI ETS 300-328 and Japan ARIB STD-T66
The PCB schematic and layout rules detailed in Appendix
B.4 must be followed. Failure to do so will likely result in the
JN5148 failing to meet the performance specification detailed
herein and worst case may result in device not functioning in the
end application.
Parameter Min Typical Max Notes
RF Port Characteristics
Type Single Ended
Impedance 1 50ohm 2.4-2.5GHz
Frequency range 2.400 GHz 2.485GHz
ESD levels (pin 17) TDB
1) With external matching inductors and assuming PCB layout as in Appendix B.4.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 77
Radio Parameters: 2.0-3.6V, +25ºC
Parameter Min Typical Max Unit Notes
Receiver Characteristics
Receive sensitivity -92 -95 dBm Nominal for 1% PER, as per
802.15.4 section 6.5.3.3
Maximum input signal +5 dBm For 1% PER, measured as
sensitivity
Adjacent channel
rejection (-1/+1 ch)
[CW Interferer]
19/34
[27/49]
dBc For 1% PER, with wanted signal
3dB, above sensitivity. (Note1,2)
(modulated interferer)
Alternate channel
rejection (-2 / +2 ch)
[CW Interferer]
40/45
[54/54]
dBc For 1% PER, with wanted signal
3dB, above sensitivity. (Note1,2)
(modulated interferer)
Other in band rejection
2.4 to 2.4835 GHz,
excluding adj channels
48 dBc For 1% PER with wanted signal
3dB above sensitivity. (Note1)
Out of band rejection 52 dBc For 1% PER with wanted signal
3dB above sensitivity. All
frequencies except wanted/2 which
is 8dB lower. (Note1)
Spurious emissions
(RX)
-61
<-70
-58
dBm Measured conducted into 50ohms
30MHz to 1GHz
1GHz to 12GHz
Intermodulation
protection
40 dB For 1% PER at with wanted signal
3dB above sensitivity. Modulated
Interferers at 2 & 4 channel
separation (Note1)
RSSI linearity -4 +4 dB -95 to -10dBm.
Available through Hardware API
Transmitter Characteristics
Transmit power +0.5 +2.5 dBm
Output power control
range
-35 dB In three 12dB steps (Note3)
Spurious emissions
(TX)
-40
<-70
<-70
dBm Measured conducted into 50ohms
30MHz to 1GHz,
1GHz to12.5GHz,
The following exceptions apply
1.8 to 1.9GHz & 5.15 to 5.3GHz
EVM [Offset] 10 [2.0] 15 % At maximum output power
Transmit Power
Spectral Density
-38 -20 dBc At greater than 3.5MHz offset, as
per 802.15.4, section 6.5.3.178 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
Radio Parameters: 2.0-3.6V, -40ºC
Parameter Min Typical Max Unit Notes
Receiver Characteristics
Receive sensitivity -93.5 -96.5 dBm Nominal for 1% PER, as per
802.15.4 section 6.5.3.3
Maximum input signal +9 dBm For 1% PER, measured as
sensitivity
Adjacent channel
rejection (-1/+1 ch)
[CW Interferer]
19/34
[TBC]
dBc For 1% PER, with wanted signal
3dB, above sensitivity. (Note1,2)
(modulated interferer)
Alternate channel
rejection (-2 / +2 ch)
[CW Interferer]
40/45
[TBC]
dBc For 1% PER, with wanted signal
3dB, above sensitivity. (Note1,2)
(modulated interferer)
Other in band rejection
2.4 to 2.4835 GHz,
excluding adj channels
47 dBc For 1% PER with wanted signal
3dB above sensitivity. (Note1)
Out of band rejection 49 dBc For 1% PER with wanted signal
3dB above sensitivity. All
frequencies except wanted/2 which
is 8dB lower. (Note1)
Spurious emissions
(RX)
-60
<-70
-57
dBm Measured conducted into 50ohms
30MHz to 1GHz
1GHz to 12GHz
Intermodulation
protection
39 dB For 1% PER at with wanted signal
3dB above sensitivity. Modulated
Interferers at 2 & 4 channel
separation (Note1)
RSSI linearity -4 +4 dB -95 to -10dBm.
Available through Hardware API
Transmitter Characteristics
Transmit power +0.75 +2.75 dBm
Output power control
range
-35 dB In three 12dB steps (Note3)
Spurious emissions
(TX)
-38
<-70
<-70
dBm Measured conducted into 50ohms
30MHz to 1GHz,
1GHz to12.5GHz,
The following exceptions apply
1.8 to 1.9GHz & 5.15 to 5.3GHz
EVM [Offset] 9 [2.0] 15 % At maximum output power
Transmit Power
Spectral Density
-38 -20 dBc At greater than 3.5MHz offset, as
per 802.15.4, section 6.5.3.1© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 79
Radio Parameters: 2.0-3.6V, +85ºC
Parameter Min Typical Max Unit Notes
Receiver Characteristics
Receive sensitivity -90 -93 dBm Nominal for 1% PER, as per
802.15.4 section 6.5.3.3
Maximum input signal +3 dBm For 1% PER, measured as
sensitivity
Adjacent channel
rejection (-1/+1 ch)
[CW Interferer]
19/34
[TBC]
dBc For 1% PER, with wanted signal
3dB, above sensitivity. (Note1,2)
(modulated interferer)
Alternate channel
rejection (-2 / +2 ch)
[CW Interferer]
40/45
[TBC]
dBc For 1% PER, with wanted signal
3dB, above sensitivity. (Note1,2)
(modulated interferer)
Other in band rejection
2.4 to 2.4835 GHz,
excluding adj channels
49 dBc For 1% PER with wanted signal
3dB above sensitivity. (Note1)
Out of band rejection 53 dBc For 1% PER with wanted signal
3dB above sensitivity. All
frequencies except wanted/2 which
is 8dB lower. (Note1)
Spurious emissions
(RX)
-62
<-70
-59
dBm Measured conducted into 50ohms
30MHz to 1GHz
1GHz to 12GHz
Intermodulation
protection
41 dB For 1% PER at with wanted signal
3dB above sensitivity. Modulated
Interferers at 2 & 4 channel
separation (Note1)
RSSI linearity -4 +4 dB -95 to -10dBm.
Available through Hardware API
Transmitter Characteristics
Transmit power -0.2 +1.8 dBm
Output power control
range
-35 dB In three 12dB steps (Note3)
Spurious emissions
(TX)
-42
<-70
<-70
dBm Measured conducted into 50ohms
30MHz to 1GHz,
1GHz to12.5GHz,
The following exceptions apply
1.8 to 1.9GHz & 5.15 to 5.3GHz
EVM [Offset] 10 [2.0] 15 % At maximum output power
Transmit Power
Spectral Density
-38 -20 dBc At greater than 3.5MHz offset, as
per 802.15.4, section 6.5.3.180 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
Note1: Blocker rejection is defined as the value, when 1% PER is seen with the wanted signal 3dB above sensitivity,
as per 802.15.4 section 6.5.3.4
Note2: Channels 11,17,24 low/high values reversed.
Note3: Up to an extra 2.5dB of attenuation is available if required.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 81
Appendix A Mechanical and Ordering Information
A.1 56-pin QFN Package Drawing
Figure 51: 56-pin QFN Package Drawings
Controlling Dimension: mm
Symbol
millimetres
Min. Nom. Max.
A ------ ------ 0.9
A1 0.00 0.01 0.05
A2 ------ 0.65 0.7
A3 0.20 Ref.
b 0.2 0.25 0.3
D 8.00 bsc
D1 7.75 bsc
D2 6.20 6.40 6.60
E 8.00 bsc
E1 7.75 bsc
E2 6.20 6.40 6.60
L 0.30 0.40 0.50
e 0.50 bsc
υ1 0° ------ 12°
R 0.09 ------ ------
Tolerances of Form and Position
aaa 0.10
bbb 0.10
ccc 0.0582 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
A.2 PCB Decal
The following PCB decal is recommended; all dimensions are in millimetres (mm).
Figure 52: PCB Decal
The PCB schematic and layout rules detailed in Appendix B.4 must
be followed. Failure to do so will likely result in the JN5148 failing
to meet the performance specification detailed herein and worst
case may result in device not functioning in the end application.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 83
A.3 Ordering Information
The standard qualification for the JN5148 is Industrial temperature range: -40ºC to +85ºC, packaged in a 56-pin QFN
package.
Ordering Code Format:
JN5148/XXX
XXX: ROM Variant
001 Supports all available networking stacks
Ordering Codes:
Part Number Ordering Code Description
JN5148-001 JN5148/001 JN5148 microcontroller
The chip is available in three different reel quantities:
• 500 on 180mm reel
• 1000 on 180mm reel
• 2500 on 330mm reel
Where this Data Sheet is denoted as “Advanced” or “Preliminary”, devices will be either Engineering Samples or
Prototypes. Devices of this status are marked with an Rx suffix after the ROM identifier to identify the revision of
silicon during these product phases - for example JN5148-001R1-T.
The Standard Supply Multiple (SSM) for Engineering Samples or Prototypes is 50 units with a maximum of 250 units.
If the quantity of Engineering Samples or Prototypes ordered is less than a reel quantity, then these will be shipped in
tape form only, with no reel and will not be dry packaged in a moisture sensitive environment.
The SSM for Production status devices is one reel, all reels are dry packaged in a moisture sensitive bag see A.5.3.84 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
A.4 Device Package Marking
The diagram below shows the package markings for JN5148. The package on the left along with the legend
information below it, shows the general format of package marking. The package on the right shows the specific
markings for a JN5148-001 device, that came from assembly build number 1000135 and was manufactured week 12
of 2008.
Jennic
JNXXXX-SSS
FFFFFFF
YYWW
Jennic
JN5148-001
0812
1000135
Figure 53: Device Package Marking
Legend:
JN Jennic
XXXX 4 digit part number
SSS 3 digit software ROM identifier
FFFFFFF 7 digit assembly build number
YY 2 digit year number
WW 2 digit week number
Where this Data Sheet is denoted as “Advanced” or “Preliminary”, devices will be either Engineering Samples or
Prototypes. Devices of this status have an Rx suffix after the software ROM identifier, for example JN5148-001R1.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 85
A.5 Tape and Reel Information
A.5.1 Tape Orientation and Dimensions
The general orientation of the 56QFN package in the tape is as shown in Figure 54.
Figure 54: Tape and Reel Orientation
Figure 55 shows the detailed dimensions of the tape used for 8x8mm 56QFN devices.
ALL DIMENSIONS IN MILLIMETRES UNLESS OTHERWISE STATED
Reference Dimensions (mm)
Ao 8.30 ±0.10
Bo 8.30 ±0.10
Ko 1.10 ±0.10
F 7.50 ±0.10
P1 12.00 ±0.10
W 16.00 ±0.30
(I) Measured from centreline of sprocket hole to centreline of pocket
(II) Cumulative tolerance of 10 sprocket holes is ±0.20mm
(III) Measured from centreline of sprocket hole to centreline of pocket
(IV) Other material available
Figure 55: Tape Dimensions86 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
A.5.2 Reel Information: 180mm Reel
Surface Resistivity Between 10e9 – 10e11 Ohms Square
Material High Impact Polystyrene, environmentally friendly, recyclable
All dimensions and tolerances are fully compliant with EIA-481-B and are specified in millimetres.
6 window design with one window on each side blanked to allow adequate labelling space.
Figure 56: 180mm Reel Dimensions© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 87
A.5.3 Reel Information: 330mm Reel
Surface Resistivity Between 10e9 – 10e11 Ohms Square
Material High Impact Polystyrene with Antistatic Additive
All dimensions and tolerances are fully compliant with EIA-481-B and are specified in millimetres.
3 window design to allow adequate labelling space.
Figure 57: 330mm Reel Dimensions
A.5.4 Dry Pack Requirement for Moisture Sensitive Material
Moisture sensitive material, as classified by JEDEC standard J-STD-033, must be dry packed. The 56 lead QFN
package is MSL2A/260°
C, and is dried before sealing in a moisture barrier bag (MBB) with desiccant bag weighing at
67.5 grams of activated clay and a humidity indicator card (HIC) meeting MIL-L-8835 specification. The MBB has a
moisture-sensitivity caution label to indicate the moisture-sensitive classification of the enclosed devices.88 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
Appendix B Development Support
B.1 Crystal Oscillators
This section covers some of the general background to crystal oscillators, to help the user make informed decisions
concerning the choice of crystal and the associated capacitors.
B.1.1 Crystal Equivalent Circuit
Cs
Lm Rm Cm
C1 C2
Where Cm is the motional capacitance
Lm is the motional inductance. This together with Cm defines the oscillation frequency (series)
Rm is the equivalent series resistance ( ESR ).
CS is the shunt or package capacitance and this is a parasitic
B.1.2 Crystal Load Capacitance
The crystal load capacitance is the total capacitance seen at the crystal pins, from all sources. As the load
capacitance (CL) affects the oscillation frequency by a process known as ‘pulling’, crystal manufacturers specify the
frequency for a given load capacitance only. A typical pulling coefficient is 15ppm/pF, to put this into context the
maximum frequency error in the IEEE802.15.4 specification is +/-40ppm for the transmitted signal. Therefore, it is
important for resonance at 32MHz exactly, that the specified load capacitance is provided.
The load capacitance can be calculated using:
CL =
1 2
1 2
T T
T T
C C
C C
+
×
Total capacitance CT1 = C1 + C1P + C1in
Where C1 is the capacitor component
C1P is the PCB parasitic capacitance. With the recommended layout this is about 1.6pF
C1in is the on-chip parasitic capacitance and is about 1.4pF typically.
Similarly for CT 2
Hence for a 9pF load capacitance, and a tight layout the external capacitors should be 15pF© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 89
B.1.3 Crystal ESR and Required Transconductance
The resistor in the crystal equivalent circuit represents the energy lost. To maintain oscillation, power must be
supplied by the amplifier, but how much? Firstly, the Pi connected capacitors C1 and C2 with CS from the crystal,
apply an impedance transformation to Rm, when viewed from the amplifier. This new value is given by:
2
ˆ
+ = L
S L m m
C
C C R R
The amplifier is a transconductance amplifier, which takes a voltage and produces an output current. The amplifier
together with the capacitors C1 and C2, form a circuit, which provides a negative resistance, when viewed from the
crystal. The value of which is given by:
2
1× 2 ×ω = T T
m
NEG
C C
g R
Where gm is the transconductance
ω is the frequency in rad/s
Derivations of these formulas can be easily found in textbooks.
In order to give quick and reliable oscillator start-up, a common rule of thumb is to set the amplifier negative
resistance to be a minimum of 4 times the effective crystal resistance. This gives
2
T1× T 2 ×ω
m
C C
g ≥
2
4
+
L
S L m
C
C C R
This can be used to give an equation for the required transconductance.
1 2
2 1 2 1 2 2 4 [ ( ) ]
T T
m S T T T T m C C
R C C C C C
g ×
× + + × ≥ ω
Example: Using typical 32MHz crystal parameters of Rm =40Ω, CS =1pF and CT1 =CT 2 =18pF ( for a load
capacitance of 9pF), the equation above gives the required transconductance ( gm ) as 2.59mA/V. The JN5148 has a
typical value for transconductance of 4.3mA/V
The example and equation illustrate the trade-off that exists between the load capacitance and crystal ESR. For
example, a crystal with a higher load capacitance can be used, but the value of max. ESR that can be tolerated is
reduced. Also note, that the circuit sensitivity to external capacitance [ C1 , C2 ] is a square law.
Meeting the criteria for start-up is only one aspect of the way these parameters affect performance, they also affect
the time taken during start-up to reach a given, (or full), amplitude. Unfortunately, there is no simple mathematical
model for this, but the trend is the same. Therefore, both a larger load capacitance and larger crystal ESR will give a
longer start-up time, which has the disadvantages of reduced battery life and increased latency. 90 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
B.2 32MHz Oscillator
The JN5148 contains the necessary on-chip components to build a 32 MHz reference oscillator with the addition of
an external crystal resonator, two tuning capacitors. The schematic of these components are shown in Figure 58.
The two capacitors, C1 and C2, will typically be 15pF ±5% and use a COG dielectric. For a detailed specification of
the crystal required and factors affecting C1 and C2 see Appendix B.1. As with all crystal oscillators the PCB layout is
especially important, both to keep parasitic capacitors to a minimum and to reduce the possibility of PCB noise being
coupled into the oscillator.
XTALOUT
C1 C2
XTALIN R1
JN5148
Figure 58: Crystal oscillator connections
The clock generated by this oscillator provides the reference for most of the JN5148 subsystems, including the
transceiver, processor, memory and digital and analogue peripherals.
32MHz Crystal Requirements
Parameter Min Typ Max Notes
Crystal Frequency 32MHz
Crystal Tolerance 40ppm Including temperature
and ageing
Crystal ESR Range (Rm) 10Ω 60Ω See below for more
details
Crystal Load Capacitance
Range (CL) 6pF 9pF 12pF See below for more
details
Not all Combinations of Crystal Load Capacitance and ESR are Valid
Recommended Crystal Load Capacitance 9pF and max ESR 40 Ω
External Capacitors (C1 & C2)
For recommended Crystal
15pF CL = 9pF, total external
capacitance needs to be
2*CL. , allowing for stray
capacitance from chip,
package and PCB © NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 91
As is stated above, not all combinations of crystal load capacitance and ESR are valid, and as explained in Appendix
B.1.3 there is a trade-off that exists between the load capacitance and crystal ESR to achieve reliable performance.
For this reason, we recommend that for a 9pF load capacitance crystals be specified with a maximum ESR of 40
ohms. For lower load capacitances the recommended maximum ESR rises, for example, CL=7pF the max ESR is 61
ohms. For the lower cost crystals in the large HC49 package, a load capacitance of 9 or 10pF is widely available and
the max ESR of 30 ohms specified by many manufacturers is acceptable. Also available in this package style, are
crystals with a load capacitance of 12pF, but in this case the max ESR required is 25 ohms or better.
Below is measurement data showing the variation of the crystal oscillator amplifier transconductance with
temperature and supply voltage, notice how small the variation is. Circuit techniques have been used to apply
compensation, such that the user need only design for nominal conditions.
32MHz Crystal Oscillator
4.1
4.15
4.2
4.25
4.3
4.35
-40 -20 0 20 40 60 80 100
Temperature (C)
Transconductance (mA/V)
32MHz Crystal Oscillator
4.28
4.29
4.3
4.31
2 2.2 2.4 2.6 2.8 3 3.2 3.4 3.6
Supply Voltage (VDD)
Transconductance (mA/V)92 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
B.3 32kHz Oscillator
In order to obtain more accurate sleep periods, the JN5148 contains the necessary on-chip components to build an
optional 32kHz oscillator with the addition of an external 32.768kHz crystal and two tuning capacitors. The crystal
should be connected between XTAL32K_IN and XTAL32K_OUT (DIO9 and DIO10), with two equal capacitors to
ground, one on each pin. The schematic of these components are shown in Figure 59. The two capacitors, C1 and
C2, will typically be in the range 10 to 22pF ±5% and use a COG dielectric. As with all crystal oscillators the PCB
layout is especially important, both to keep parasitic capacitors to a minimum and to reduce the possibility of PCB
noise being coupled into the oscillator.
XTAL32K_IN XTAL32K_OUT
JN5148
Figure 59: 32kHz crystal oscillator connections
The electrical specification of the oscillator can be found in 22.3.12. The oscillator cell is flexible and can operate with
a range of commonly available 32kHz crystals with load capacitances from 6 to 12.5p, and ESR up to 80KΩ. It
achieves this by using automatic gain control (AGC), which senses the signal swing. As explained in Appendix B.1.3
there is a trade-off that exists between the load capacitance and crystal ESR to achieve reliable performance. The
use of an AGC function allows a wider range of crystal load capacitors and ESR’s to be accommodated than would
otherwise be possible. However, this benefit does mean the supply current varies with the supply voltage (VDD),
value of the total capacitance at each pin, and the crystal ESR. This is described in the table and graphs below.
32kHz Crystal Requirements
Parameter Min Typ Max Notes
Crystal Frequency 32kHz
Supply Current 1.6uA Vdd=3v, temp=25 C, load
cap =9pF, Rm=25K
Supply Current Temp. Coeff. 0.1%/ C Vdd=3v
Crystal ESR Range (Rm) 10KΩ 25KΩ 80KΩ See below for more details
Crystal Load Capacitance
Range (CL)
6pF 9pF 12.5pF See below for more details
Not all Combinations of Crystal Load Capacitance and ESR are Valid © NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 93
Three examples of typical crystals are given, each with the value of external capacitors to use, plus the likely supply
current and start-up time that can be expected. Also given is the maximum recommended ESR based on the start-up
criteria given in Appendix B.1.3. The values of the external capacitors can be calculated using the equation in
Appendix B.1.2 .
Load Capacitance Ext Capacitors Current Start-up Time Max ESR
9pF 15pF 1.6uA 0.8Sec 70KΩ
6pF 9pF 1.4uA 0.6sec 80KΩ
12.5pF 22pF 2.4uA 1.1sec 35KΩ
Below is measurement data showing the variation of the crystal oscillator supply current with voltage and with crystal
ESR, for two load capacitances.
32KHz Crystal Oscillator Current
0.6
0.8
1
1.2
1.4
1.6
2.2 2.4 2.6 2.8 3 3.2 3.4 3.6
Supply Voltage (VDD)
Normalised Current (IDD)
32KHz Crystal Oscillator Current
0.6
0.8
1
1.2
1.4
1.6
10 20 30 40 50 60 70 80
Crystal ESR (K ohm)
Normalised Current (IDD)
9pF
12.5pF94 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
B.4 JN5148 Module Reference Designs
For customers wishing to integrate the JN5148 device directly into their system, NXP provide a range of Module
Reference Designs, covering standard and high-power modules fitted with different Antennae
To ensure the correct performance, it is strongly recommended that where possible the design details provided by the
reference designs, are used in their exact form for all end designs, this includes component values, pad dimensions,
track layouts etc. In order to minimise all risks, it is recommended that the entire layout of the appropriate reference
module, if possible, be replicated in the end design.
For full details, consult the Standard Module Reference Design JN-RD-6015 [6].
B.4.1 Schematic Diagram
A schematic diagram of the JN5148 PCB antenna reference module is shown in Figure 60. Details of component
values and PCB layout constraints can be found in Table 8.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15 16 17 18 19 20 21 22 23 24 25 26 27 28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
56 55 54 53 52 51 50 49 48 47 46 45 44 43
SPI Selects
Analogue IO
UART0/JTAG
Timers
Two Wire
Serial Port
RXD1
UART1/JTAG
DIO16
CTS1
VSS3
RTS1
TXD1
VSS2
VSSS
XTAL_OUT
XTAL_IN
VB_SYNTH
VCOTUNE (NC)
VB_VCOR1 43K
IBIAS
C16 100nF
VDD1
C14 100nF
VDD
C13 10uF
C24 47pF
C18 47pF
C2 10nF
C15 100nF
Y1
C11 15pF
C10 15pF
C20 100nF
L2 2.7nH
VB_RF
VREF
VB_RF2
RF_IN
VB_RF
C12 47pF
C3 100nF
VB_RF1
C1M
C1P
ADC1
ADC2
ADC3
ADC4
C2M
C2P
VB_A
C9 47pF
C8 100nF NC
VDD
VDD
RXD1
SPIMOSI
SPIMOSI
SPICLK SPICLK
C6 100nF
C7 100nF
SPISEL3
SPISEL2
VB_DIG
RESETN
SPISEL1
SPISEL0
VB_RAM
SPIMISO
VSS1
DAC2
DAC1
1
2
3
4
8
7
6
5
SS
SD0
WP
VSS SDI
CLK
HOLD
VCC
Serial
Flash
Memory
RXD0
TXD0
RTS0
CTS0
SPISEL4
VDD
SIF_D
SIF_CLK
TIM1OUT
TIM1CAP
TIM1CK_GT
TIM0OUT
TIM0CAP
VDD2
TIM0CK_GT
VSSA
JN5148
C1 47pF L1 5.6nH
To Coaxial Socket
Or Integrated Antenna
Figure 60: JN5148 Printed Antenna Reference Module Schematic Diagram© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 95
Component
Designator
Value/Type Function PCB Layout Constraints
C13 10uF Power source decoupling
C14 100nF Analogue Power decoupling Adjacent to U1 pin 13
C16 100nF Digital power decoupling Adjacent to U1 pin 49
C15 100nF VB Synth decoupling Less than 5mm from U1 pin 10
C18 47pF VB Synth decoupling Less than 5mm from U1 pin 10
C2 10nF VB VCO decoupling Less than 5mm from U1 pin 12
C24 47pF VB VCO decoupling Less than 5mm from U1 pin 12
C3 100nF VB RF decoupling Less than 5mm from U1 pin 16 and U1 pin 18
C12 47pF VB RF decoupling Less than 5mm from U1 pin 16 and U1 pin 18
C8 100nF VB A decoupling Less than 5mm from U1 pin 27
C9 47pF VB A decoupling Less than 5mm from U1 pin 27
C6 100nF VB RAM decoupling Less than 5mm from U1 pin 35
C7 100nF VB Dig decoupling Less than 5mm from U1 pin 40
R1 43k I Bias Resistor Less than 5mm from U1 pin 14
C20 100nF Vref decoupling Less than 5mm from U1 pin 15
U2 4Mbit Serial Flash Memory (Numonyx M25P40)
Y1 32MHz Crystal (AEL X32M000000S025) (CL = 9pF, Max ESR 40R)
C10 15pF +/-5% COG Crystal Load Capacitor Adjacent to pin 8 and Y1 pin 1
C11 15pF +/-5% COG Crystal Load Capacitor Adjacent to pin 9 and Y1 pin 3
R2 Not fitted
C1 47pF AC Coupling
Phycomp 2238-869-15479
Must be copied directly from the reference design.
L1 5.6nH RF Matching Inductor
MuRata LQP15MN5N6B02
L2 2.7nH Load Inductor
MuRata LQP15MN2N7B02
Table 8: JN5148 Printed Antenna Reference Module Components and PCB Layout Constraints
The paddle should be connected directly to ground. Any pads that requiring connection to ground should do so by
connecting directly to the paddle.96 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
B.4.2 PCB Design and Reflow Profile
PCB and land pattern designs are key to the reliability of any electronic circuit design.
The Institute for Interconnecting and Packaging Electronic Circuits (IPC) defines a number of standards for electronic
devices. One of these is the "Surface Mount Design and Land Pattern Standard" IPC-SM-782 [3], commonly referred
to as “IPC782". This specification defines the physical packaging characteristics and land patterns for a range of
surface mounted devices. IPC782 is also a useful reference document for general surface mount design techniques,
containing sections on design requirements, reliability and testability. NXP strongly recommends that this be referred
to when designing the PCB.
The suggested reflow profile is shown in Figure 61. The specific paste manufacturers guidelines on peak flow
temperature, soak times, time above liquidus and ramp rates should also be referenced.
Figure 61: Recommended Reflow Profile for Lead-free Solder Paste or PPF lead frame© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 97
Related Documents
[1] IEEE Std 802.15.4-2003 IEEE Standard for Information Technology – Part 15.4 Wireless Medium Access Control
(MAC) and Physical Layer (PHY) Specifications for Low-Rate Wireless Personal Area Networks (LR-WPANs).
[2] JN-AN-1038 Programming Flash devices not supported by the JN51xx ROM-based bootloader
[3] IPC-SM-782 Surface Mount Design and Land Pattern Standard
[4] JN-AN-1118 JN5148 Application Debugging
[5] JN-UG-3066 JN51xx Integrated Peripherals API User Guide
[6] JN-RD-6015 Standard Module Reference Design
[7] JN-AN-1003 Boot Loader Operation
RoHS Compliance
JN5148 devices meet the requirements of Directive 2002/95/EC of the European Parliament and of the Council on
the Restriction of Hazardous Substance (RoHS) and of the China RoHS (SJ/T11363 – 2006) requirements which
came into force on 1st March 2007.
Status Information
The status of this Data Sheet is. Production
NXP products progress according to the following format:
Advance
The Data Sheet shows the specification of a product in planning or in development.
The functionality and electrical performance specifications are target values of the design and may be used as a
guide to the final specification. Integrated circuits are identified with an Rx suffix, for example JN5148-001R1.
NXP reserves the right to make changes to the product specification at anytime without notice.
Preliminary
The Data Sheet shows the specification of a product that is commercially available, but is not yet fully qualified.
The functionality of the product is final. The electrical performance specifications are target values and may used as a
guide to the final specification. Integrated circuits are identified with an Rx suffix, for example JN5148-001R1.
NXP reserves the right to make changes to the product specification at anytime without notice.
Production
This is the production Data Sheet for the product.
All functional and electrical performance specifications, where included, including min and max values are derived
from detailed product characterization.
This Data Sheet supersedes all previous document versions.
NXP reserves the right to make changes to the product specification at anytime.98 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
Disclaimers
Limited warranty and liability — Information in this document is believed to be accurate and reliable. However, NXP Semiconductors does not give
any representations or warranties, expressed or implied, as to the accuracy or completeness of such information and shall have no liability for the
consequences of use of such information. NXP Semiconductors takes no responsibility for the content in this document if provided by an information
source outside of NXP Semiconductors.
In no event shall NXP Semiconductors be liable for any indirect, incidental, punitive, special or consequential damages (including - without limitation -
lost profits, lost savings, business interruption, costs related to the removal or replacement of any products or rework charges) whether or not such
damages are based on tort (including negligence), warranty, breach of contract or any other legal theory.
Notwithstanding any damages that customer might incur for any reason whatsoever, NXP Semiconductors’ aggregate and cumulative liability towards
customer for the products described herein shall be limited in accordance with the Terms and conditions of commercial sale of NXP Semiconductors.
Right to make changes — NXP Semiconductors reserves the right to make changes to information published in this document, including without
limitation specifications and product descriptions, at any time and without notice. This document supersedes and replaces all information supplied prior
to the publication hereof.
Suitability for use — NXP Semiconductors products are not designed, authorized or warranted to be suitable for use in life support, life-critical or
safety-critical systems or equipment, nor in applications where failure or malfunction of an NXP Semiconductors product can reasonably be expected to
result in personal injury, death or severe property or environmental damage. NXP Semiconductors and its suppliers accept no liability for inclusion
and/or use of NXP Semiconductors products in such equipment or applications and therefore such inclusion and/or use is at the customer’s own risk.
Applications — Applications that are described herein for any of these products are for illustrative purposes only. NXP Semiconductors makes no
representation or warranty that such applications will be suitable for the specified use without further testing or modification.
Customers are responsible for the design and operation of their applications and products using NXP Semiconductors products, and NXP
Semiconductors accepts no liability for any assistance with applications or customer product design. It is customer’s sole responsibility to determine
whether the NXP Semiconductors product is suitable and fit for the customer’s applications and products planned, as well as for the planned
application and use of customer’s third party customer(s). Customers should provide appropriate design and operating safeguards to minimize the risks
associated with their applications and products.
NXP Semiconductors does not accept any liability related to any default, damage, costs or problem which is based on any weakness or default in the
customer’s applications or products, or the application or use by customer’s third party customer(s). Customer is responsible for doing all necessary
testing for the customer’s applications and products using NXP Semiconductors products in order to avoid a default of the applications and the
products or of the application or use by customer’s third party customer(s). NXP does not accept any liability in this respect.
Export control — This document as well as the item(s) described herein may be subject to export control regulations. Export might require a prior
authorization from competent authorities.
Limiting values — Stress above one or more limiting values (as defined in the Absolute Maximum Ratings System of IEC 60134) will cause
permanent damage to the device. Limiting values are stress ratings only and (proper) operation of the device at these or any other conditions above
those given in the Operating Conditions section or the Electrical Characteristics sections of this document is not warranted. Constant or repeated
exposure to limiting values will permanently and irreversibly affect the quality and reliability of the device.
AEC unqualified products — This product has not been qualified to the appropriate Automotive Electronics Council (AEC) standard Q100 or Q101
and should not be used in automotive applications, including but not limited to applications where failure or malfunction of an NXP Semiconductors
product can reasonably be expected to result in personal injury, death or severe property or environmental damage. NXP Semiconductors accepts no
liability for inclusion and/or use of NXP Semiconductors products in such equipment or applications and therefore such inclusion and/or use is for the
customer’s own risk.
Product specification — The information and data provided in a Product data sheet shall define the specification of the product as agreed between
NXP Semiconductors and its customer, unless NXP Semiconductors and customer have explicitly agreed otherwise in writing. In no event however,
shall an agreement be valid in which the NXP Semiconductors product is deemed to offer functions and qualities beyond those described in the
Product data sheet
All products are sold subject to NXP Semiconductors’ terms and conditions of sale, supplied at the time of order acknowledgment and published at
http://www.nxp.com/profile/terms.
Trademarks
All trademarks are the property of their respective owners.© NXP Laboratories UK 2013 JN-DS-JN5148-001 1v9 99
Version Control
Version Notes
1.0 12th December 2008 – First issue, released as Advance Information
1.1 15th May 2009 – Major revision
1.2 15th July – Released as Preliminary and revised Electrical Parameters section
1.3 20th January 2010 – Revision to sections 1.1, 2.2.1 & 8.1 – 8.4 and figs 1,2,22 & 47. Also, the bill of
materials and reference design number have been updated.
1.4 2nd April 2010 – Released as Production with revised Electrical Parameters section
1.5 14th September 2010 – Logo updated and support for JenNet added
1.6 24th November 2010 – Ordering information changed
1.7 5th May 2011 – Tape and reel information updated
1.8 12th September 2012 – NXP branding applied
1.9 6th September 2013 – Modified description of interrupts within the CPU in Chapter 3100 JN-DS-JN5148-001 1v9 © NXP Laboratories UK 2013
Contact Details
NXP Laboratories UK Ltd
(Formerly Jennic Ltd)
Furnival Street
Sheffield
S1 4QT
United Kingdom
Tel: +44 (0)114 281 2655
Fax: +44 (0) 114 281 2951
For the contact details of your local NXP office or distributor, refer to the NXP web site:
www.nxp.com
Data Sheet: JN516x
IEEE802.15.4 Wireless Microcontroller
© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 1
Overview Features: Radio
• 2.4GHz IEEE802.15.4 compliant
• 128-bit AES security processor
• MAC accelerator with packet
formatting, CRCs, address check,
auto-acks, timers
• Integrated ultra low power sleep
oscillator – 0.6µA
• 2.0V to 3.6V battery operation
• Deep sleep current 0.12µA (Wake-up
from IO)
• <$0.15 external component cost
• RX current 17mA , TX 15mA
• Receiver sensitivity -95dBm
• Transmit power 2.5dBm
• Time of Flight engine for ranging
• Antenna Diversity (Auto RX)
Features: Microcontroller
• 32-bit RISC CPU, 1 to 32MHz clock
speed
• Variable instruction width for high
coding efficiency
• Multi-stage instruction pipeline
• JN5161: 64kB/8kB/4kB
• JN5164: 160kB/32kB/4kB
• JN5168: 256kB/32kB/4kB
(Flash/RAM/EEPROM)
• Data EEPROM with guaranteed 100k
write operations.
• RF4CE, JenNet-IP, ZigBee SE and
ZigBee Light Link stacks
• 2-wire I2C compatible serial interface.
Can operate as either master or slave
• 5xPWM (4x timer & 1 timer/counter)
• 2 low power sleep counters
• 2x UART
• SPI Master & Slave port, 3 selects
• Supply voltage monitor with 8
programmable thresholds
• 4-input 10-bit ADC, comparator
• Battery and temperature sensors
• Watchdog & Brown Out Reset
• Up to 20 Digital IO Pins (DIO)
• Infra-red remote control transmitter
Temp range (-40°C to +125°C)
6x6mm 40-lead
Lead-free and RoHS compliant
The JN516x series is a range of ultra low power, high performance wireless
microcontrollers supporting JenNet-IP, ZigBee PRO or RF4CE networking
stacks to facilitate the development of Home Automation, Smart Energy,
Light Link and Remote control applications. They feature an enhanced 32-
bit RISC processor with embedded Flash and EEPROM memory, offering
high coding efficiency through variable width instructions, a multi-stage
instruction pipeline and low power operation with programmable clock
speeds. They also include a 2.4GHz IEEE802.15.4 compliant transceiver
and a comprehensive mix of analogue and digital peripherals. Three
memory configurations are available to suit different applications. The best
in class operating current of 15mA, with a 0.6uA sleep timer mode, gives
excellent battery life allowing operation direct from a coin cell.
The peripherals support a wide range of applications. They include a 2-wire
I
2
C, and SPI ports which can operate as either master or slave, a four
channel ADC with battery and a temperature sensor. It can support a large
switch matrix of up to 100 elements, or alternatively a 20 key capacitive
touch pad.
Block Diagram
32-bit
RISC CPU 4xPWM + Timer
2xUART
10-bit ADC
Battery and
Temp Sensors
2-Wire Serial
(Master/Slave)
SPI
Master & Slave RAM
128-bit AES
Hardware
2.4GHz
Including
Diversity
Flash
Power
Management
XTAL
O-QPSK
Modem
4kB
EEPROM
20 DIO
Sleep Counter
Watchdog
Timer
Voltage Brownout
8/32K 64/160/256K
Radio
4-Channel
IEEE 802.15.4
Baseband
Processor
Encryption
Benefits
• Single chip device to run
stack and application
• Very low current solution for
long battery life – over 10 yrs
• Supports multiple network
stacks
• Highly featured 32-bit RISC
CPU for high performance
and low power
• System BOM is low in
component count and cost
• Flexible sensor interfacing
options
Applications
• Robust and secure low power
wireless applications
• RF4CE Remote Controls
• JenNet-IP networks
• ZigBee SE networks
• ZigBee Light Link networks
• Lighting & Home automation
• Toys and gaming peripherals
• Smart Energy
• Energy harvesting, for
example self powered light
switch2 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
Contents
Benefits 1
Applications 1
1 Introduction 6
1.1 Wireless Transceiver 6
1.2 RISC CPU and Memory 6
1.3 Peripherals 7
1.4 Block Diagram – JN516x 8
2 Pin Configurations 9
2.1 Pin Assignment 10
2.2 Pin Descriptions 12
2.2.1 Power Supplies 12
2.2.2 Reset 12
2.2.3 32MHz Oscillator 12
2.2.4 Radio 12
2.2.5 Analogue Peripherals 13
2.2.6 Digital Input/Output 13
3 CPU 15
4 Memory Organisation 16
4.1 FLASH 16
4.2 RAM 16
4.3 OTP Configuration Memory 16
4.4 EEPROM 17
4.5 External Memory 17
4.6 Peripherals 17
4.7 Unused Memory Addresses 17
5 System Clocks 18
5.1 High-Speed (32MHz) System Clock 18
5.1.1 32MHz Crystal Oscillator 18
5.1.2 High-Speed RC Oscillator 19
5.2 Low-speed (32kHz) System Clock 19
5.2.1 32kHz RC Oscillator 19
5.2.2 32kHz Crystal Oscillator 20
5.2.3 32kHz External Clock 20
6 Reset 21
6.1 Internal Power-On / Brown-out Reset (BOR) 21
6.2 External Reset 22
6.3 Software Reset 22
6.4 Supply Voltage Monitor (SVM) 22
6.5 Watchdog Timer 23
7 Interrupt System 24
7.1 System Calls 24
7.2 Processor Exceptions 24
7.2.1 Bus Error 24© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 3
7.2.2 Alignment 24
7.2.3 Illegal Instruction 24
7.2.4 Stack Overflow 24
7.3 Hardware Interrupts 25
8 Wireless Transceiver 26
8.1 Radio 26
8.1.1 Radio External Components 27
8.1.2 Antenna Diversity 27
8.2 Modem 29
8.3 Baseband Processor 30
8.3.1 Transmit 30
8.3.2 Reception 30
8.3.3 Auto Acknowledge 31
8.3.4 Beacon Generation 31
8.3.5 Security 31
8.4 Security Coprocessor 31
8.5 Time of Flight Engine 31
9 Digital Input/Output 32
10 Serial Peripheral Interface 34
10.1 Serial Peripheral Interface Master 34
10.2 Serial Peripheral Interface Slave 37
11 Timers 38
11.1 Peripheral Timer/Counters 38
11.1.1 Pulse Width Modulation Mode 39
11.1.2 Capture Mode 39
11.1.3 Counter/Timer Mode 40
11.1.4 Delta-Sigma Mode 40
11.1.5 Infra-Red Transmission Mode 41
11.1.6 Example Timer/Counter Application 41
11.2 Tick Timer 42
11.3 Wakeup Timers 42
11.3.1 32 KHZ RC Oscillator Calibration 43
12 Pulse Counters 44
13 Serial Communications 45
13.1 Interrupts 46
13.2 UART Application 46
14 JTAG Test Interface 48
15 Two-Wire Serial Interface (I2
C) 49
15.1 Connecting Devices 49
15.2 Clock Stretching 50
15.3 Master Two-wire Serial Interface 50
15.4 Slave Two-wire Serial Interface 52
16 Random Number Generator 534 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
17 Analogue Peripherals 54
17.1 Analogue to Digital Converter 54
17.1.1 Operation 55
17.1.2 Supply Monitor 56
17.1.3 Temperature Sensor 56
17.1.4 ADC Sample Buffer Mode 56
17.2 Comparator 56
18 Power Management and Sleep Modes 57
18.1 Operating Modes 57
18.1.1 Power Domains 57
18.2 Active Processing Mode 57
18.2.1 CPU Doze 57
18.3 Sleep Mode 57
18.3.1 Wakeup Timer Event 58
18.3.2 DIO Event 58
18.3.3 Comparator Event 58
18.3.4 Pulse Counter 58
18.4 Deep Sleep Mode 58
19 Electrical Characteristics 59
19.1 Maximum Ratings 59
19.2 DC Electrical Characteristics 59
19.2.1 Operating Conditions 59
19.2.2 DC Current Consumption 60
19.2.3 I/O Characteristics 61
19.3 AC Characteristics 61
19.3.1 Reset and Supply Voltage Monitor 61
19.3.2 SPI Master Timing 63
19.3.3 SPI Slave Timing 64
19.3.4 Two-wire Serial Interface 65
19.3.5 Wakeup Timings 65
19.3.6 Bandgap Reference 66
19.3.7 Analogue to Digital Converters 66
19.3.8 Comparator 67
19.3.9 32kHz RC Oscillator 67
19.3.10 32kHz Crystal Oscillator 68
19.3.11 32MHz Crystal Oscillator 68
19.3.12 High-Speed RC Oscillator 69
19.3.13 Temperature Sensor 69
19.3.14 Non-Volatile Memory 69
19.3.15 Radio Transceiver 70
Appendix A Mechanical and Ordering Information 76
A.1 SOT618-1 HVQFN40 40-pin QFN Package Drawing 76
A.2 Footprint Information 77
A.3 Ordering Information 78
A.4 Device Package Marking 79
A.5 Tape and Reel Information 80
A.5.1 Tape Orientation and Dimensions 80
A.5.2 Reel Information: 180mm Reel 81
A.5.3 Reel Information: 330mm Reel 82© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 5
A.5.4 Dry Pack Requirement for Moisture Sensitive Material 82
Appendix B Development Support 83
B.1 Crystal Oscillators 83
B.1.1 Crystal Equivalent Circuit 83
B.1.2 Crystal Load Capacitance 83
B.1.3 Crystal ESR and Required Transconductance 84
B.2 32MHz Oscillator 85
B.3 32kHz Oscillator 87
B.4 JN516x Module Reference Designs 89
B.4.1 Schematic Diagram 89
B.4.2 PCB Design and Reflow Profile 91
B.4.3 Moisture Sensitivity Level (MSL) 91
Related Documents 92
RoHS Compliance 92
Status Information 92
Disclaimers 93
Trademarks 93
Version Control 93
Contact Details 946 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
1 Introduction
The JN516x is an IEEE802.15.4 wireless microcontroller that provides a fully integrated solution for applications using
the IEEE802.15.4 standard in the 2.4 - 2.5GHz ISM frequency band [1], including Zigbee PRO, ZigBee Smart Energy,
ZigBee LightLink, RF4CE and JenNet-IP. There are 3 versions in the range, differing only by memory configuration
JN5161-001: 64kB Flash, 8kB RAM, 4 kB EEPROM, suitable for IEEE802.15.4 and RF4CE applications
JN5164-001: 160kB Flash, 32kB RAM, 4 kB EEPROM suitable for Jennet-IP, IEEE802.15.4 and RF4CE applications
JN5168-001: 256kB Flash, 32kB RAM, 4 kB EEPROM suitable for all applications
Applications that transfer data wirelessly tend to be more complex than wired ones. Wireless protocols make
stringent demands on frequencies, data formats, timing of data transfers, security and other issues. Application
development must consider the requirements of the wireless network in addition to the product functionality and user
interfaces. To minimise this complexity, NXP provides a series of software libraries and interfaces that control the
transceiver and peripherals of the JN516x. These libraries and interfaces remove the need for the developer to
understand wireless protocols and greatly simplifies the programming complexities of power modes, interrupts and
hardware functionality.
In view of the above, it is not necessary to provide the register details of the JN516x in the datasheet.
The device includes a Wireless Transceiver, RISC CPU, on chip memory and an extensive range of peripherals.
1.1 Wireless Transceiver
The Wireless Transceiver comprises a 2.45GHz radio, a modem, a baseband controller and a security coprocessor.
In addition, the radio also provides an output to control transmit-receive switching of external devices such as power
amplifiers allowing applications that require increased transmit power to be realised very easily. Appendix B.4,
describes a complete reference design including Printed Circuit Board (PCB) design and Bill Of Materials (BOM).
The security coprocessor provides hardware-based 128-bit AES-CCM* modes as specified by the IEEE802.15.4
2006 standard. Specifically this includes encryption and authentication covered by the MIC –32/-64/-128, ENC and
ENC-MIC –32/-64/-128 modes of operation.
The transceiver elements (radio, modem and baseband) work together to provide IEEE802.15.4 (2006) MAC and
PHY functionality under the control of a protocol stack. Applications incorporating IEEE802.15.4 functionality can be
developed rapidly by combining user-developed application software with a protocol stack library.
1.2 RISC CPU and Memory
A 32-bit RISC CPU allows software to be run on-chip, its processing power being shared between the IEEE802.15.4
MAC protocol, other higher layer protocols and the user application. The JN516x has a unified memory architecture,
code memory, data memory, peripheral devices and I/O ports are organised within the same linear address space.
The device contains up to 256kbytes of Flash, up to 32kbytes of RAM and 4kbytes EEPROM . © NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 7
1.3 Peripherals
The following peripherals are available on chip:
• Master SPI port with three select outputs
• Slave SPI port
• Two UART’s, one capable of hardware flow control (4-wire, includes RTS/CTS), and the other just 2-wire
(RX/TX)
• One programmable Timer/Counter which supports Pulse Width Modulation (PWM) and capture/compare, plus
four PWM timers which support PWM and Timer modes only.
• Two programmable Sleep Timers and a Tick Timer
• Two-wire serial interface (compatible with SMbus and I2
C) supporting master and slave operation
• Twenty digital I/O lines (multiplexed with peripherals such as timers, SPI and UARTs)
• Two digital outputs (multiplexed with SPI port)
• 10-bit, Analogue to Digital converter with up to four input channels. Autonomous multi-channel sampling
• Programmable analogue comparator
• Internal temperature sensor and battery monitor
• Two low power pulse counters
• Random number generator
• Watchdog Timer and Supply Voltage Monitor
• JTAG hardware debug port
• Infra-red remote control transmitter, supported by one of the PWM timers
• Transmit and receive antenna diversity with automatic receive switching based on received energy detection
• Time of Flight engine for ranging
User applications access the peripherals using the Integrated Peripherals API. This allows applications to use a
tested and easily understood view of the peripherals allowing rapid system development. 8 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
1.4 Block Diagram – JN516x
Wireless
Transceiver
32-bit RISC CPU
MUX
Security
Processor
Digital Baseband
Radio
Programmable
Interrupt
Controller
From Peripherals
RF_IN
VCOTUNE
Tick Timer
Voltage
Regulators 1.8V VDD1
VDD2
IBIAS
VB_XX
EEPROM
4KB
CPU and 16MHz
System Clock
32MHz Xtal
Clock
Generator
XTAL_IN
XTAL_OUT
Clock
Source &
Rate
Select
Highspeed
RC
Osc
Watchdog
Timer
Supply Voltage
Monitor
Reset
Wakeup
Timer1
Wakeup Timer0
RESETN
32kHz Clock
Select 32KIN
Comparator1
COMP1P
COMP1M
ADC
M
U
ADC4 X
ADC1
VREF/ADC2
ADC3
Temperature
Sensor
Supply Monitor
32kHz
RC
Osc
32kHz
Xtal
Osc
32KXTALIN
32KXTALOUT
SPI Slave
DIO0
DIO1
DIO2
DIO3
DIO4
DIO5
DIO6
DIO7
DIO8
DIO9
DIO10
DIO11
DIO12
DIO13
DIO14
DIO15
DIO16
DIO17
DIO18
DIO19
DO0
DO1
TXD0
SPI
Master
UART0
UART1
RXD0
RTS0
CTS0
TxD1
RxD1
TIM0CK_GT
TIM0OUT
TIM0CAP
PWM1
PWM2
PWM3
PWM4
SIF_D
SIF_CLK
PC0
PC1
JTAG_TDI
JTAG_TMS
JTAG_TCK
JTAG_TDO
ADO
ADE
Timer0
PWMs
2-wire
Interface
Pulse
Counters
JTAG
Debug
Antenna
Diversity
SPICLK
SPIMOSI
SPIMISO
SPISEL0
SPICLK
SPIMOSI
SPIMISO
SPISEL0
SPISEL1
SPISEL2
FLASH
256/160/64KB
RAM
32/32/8KB
Figure 1: JN516x Block Diagram© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 9
2 Pin Configurations
1
40 39 38 37 36 35 34 33 32 31
VSSA
2
3
4
5
6
7
8
9
10
30
29
28
27
26
25
24
23
22
21
11 12 13 14 15 16 17 18 19 20
DIO16
DIO17
RESETN
XTAL_OUT
XTAL_IN
VB_SYNTH
VCOTUNE
VB_VCO
VDD1
IBIAS
VREF/ADC2
VB_RF2
RF_IN
VB_RF1
ADC1
DIO0
DIO1
DIO2
DIO3
DO0
VSS1
DO1
DIO18
DIO19
VB_RAM
DIO4
DIO5
DIO6
DIO7
VDD2
DIO15
VSS2
DIO14
DIO13
DIO12
VB_DIG
DIO11
DIO10
DIO9
DIO8
Figure 2: 40-pin QFN Configuration (top view)
Note: Please refer to Appendix B.4 JN516x Module Reference
Design for important applications information regarding the
connection of the PADDLE to the PCB. 10 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
2.1 Pin Assignment
Pin No Power supplies Signal
Type
Description
6, 8,
12, 14,
25, 35
VB_SYNTH, VB_VCO, VB_RF2, VB_RF1, VB_RAM, VB_DIG 1.8V Regulated supply voltage
9, 30 VDD1, VDD2 3.3V Supplies: VDD1 for
analogue, VDD2 for digital
21, 39,
Paddle
VSS1, VSS2, VSSA 0V Grounds (see appendix A.2
for paddle details)
General
3 RESETN CMOS Reset input
4,5 XTAL_OUT, XTAL_IN 1.8V System crystal oscillator
Radio
7 VCOTUNE 1.8V VCO tuning RC network
10 IBIAS 1.8V Bias current control
13 RF_IN 1.8V RF antenna
Analogue Peripheral I/O
15, 16,
17
ADC1, DIO0 (ADC3), DIO1 (ADC4) 3.3V ADC inputs
11 VREF/ADC2 1.8V Analogue peripheral
reference voltage or ADC
input 2
1, 2 DIO16 (COMP1P), DIO17 (COMP1M) 3.3V Comparator inputs
Digital Peripheral I/O
Primary Alternate Functions
16 DIO0 SPISEL1 ADC3 CMOS DIO0, SPI Master Select
Output 1 or ADC input 3
17 DIO1 SPISEL2 ADC4 PC0 CMOS DIO1, SPI Master Select
Output 2, ADC input 4 or
Pulse Counter 0 Input
18 DIO2 RFRX TIM0CK_GT CMOS DIO2, Radio Receive Control
Output or Timer0 Clock/Gate
Input
19 DIO3 RFTX TIM0CAP CMOS DIO3, Radio Transmit
Control Output or Timer0
Capture Input
26 DIO4 CTS0 JTAG_TCK TIM0OUT PC0 CMOS DIO4, UART 0 Clear To
Send Input, JTAG CLK Input,
Timer0 PWM Output, or
Pulse Counter 0 input
27 DIO5 RTS0 JTAG_TMS PWM1 PC1 CMOS DIO5, UART 0 Request To
Send Output, JTAG Mode
Select Input, PWM1 Output
or Pulse Counter 1 Input
28 DIO6 TXD0 JTAG_TDO PWM2 CMOS DIO6, UART 0 Transmit Data
Output, JTAG Data Output or
PWM2 Output
29 DIO7 RXD0 JTAG_TDI PWM3 CMOS DIO7, UART 0 Receive Data
Input, JTAG Data Input or
PWM 3 Output
31 DIO8 TIM0CK_GT PC1 PWM4 CMOS DIO8, Timer0 Clock/Gate
Input, Pulse Counter1 Input
or PWM 4 Output© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 11
32 DIO9 TIM0CAP 32KXTALIN RXD1 32KIN CMOS DIO9, Timer0 Capture Input,
32K External Crystal Input,
UART 1 Receive Data Input
or 32K external clock Input
33 DIO10 TIM0OUT 32KXTALOUT CMOS DIO10, Timer0 PWM Output
or 32K External Crystal
Output
34 DIO11 PWM1 TXD1 CMOS DIO11, PWM1 Output or
UART 1 Transmit Data
Output
36 DIO12 PWM2 CTS0 JTAG_TCK ADO SPISMO
SI
CMOS DIO12, PWM2 Output, UART
0 Clear To Send Input, JTAG
CLK Input, Antenna Diversity
Odd Output or SPI Slave
Master Out Slave In Input
37 DIO13 PWM3 RTS0 JTAG_TMS ADE SPISMI
SO
CMOS DIO13, PWM3 Output, UART
0 Request To Send Output,
JTAG Mode Select Input,
Antenna Diversity Even
output or SPI Slave Master In
Slave Out Output
38 DIO14 SIF_CLK TXD0 TXD1 JTAG_TDO SPISEL
1
SPISSE
L
CMOS DIO14, Serial Interface
Clock, UART 0 Transmit
Data Output, UART 1
Transmit Data Output, JTAG
Data Output, SPI Master
Select Output 1 or SPI Slave
Select Input
40 DIO15 SIF_D RXD0 RXD1 JTAG_TDI SPISEL
2
SPISCL
K
CMOS DIO15, Serial Interface Data,
UART 0 Receive Data Input,
UART 1 Receive Data Input,
JTAG Data Input, SPI Master
Select Output 2 or SPI Slave
Clock Input
1 DIO16 COMP1P SIF_CLK SPISMOSI CMOS DIO16, Comparator Positive
Input, Serial Interface clock
or SPI Slave Master Out
Slave In Input
2 DIO17 COMP1M SIF_D SPISMISO CMOS DIO17, Comparator Negative
Input, Serial Interface Data or
SPI Slave Master In Slave
Out Output
23 DIO18 SPIMOSI CMOS SPI Master Out Slave In
Output
24 DIO19 SPISEL0 CMOS SPI Master Select Output 0
20 DO0 SPICLK PWM2 CMOS SPI Master Clock Output or
PWM2 Output
22 DO1 SPIMISO PWM3 CMOS SPI Master In Slave Out
Input or PWM3 Output
The PCB schematic and layout rules detailed in Appendix B.4
must be followed. Failure to do so will likely result in the
JN516x failing to meet the performance specification detailed
herein and worst case may result in device not functioning in
the end application.12 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
2.2 Pin Descriptions
2.2.1 Power Supplies
The device is powered from the VDD1 and VDD2 pins, each being decoupled with a 100nF ceramic capacitor. VDD1
is the power supply to the analogue circuitry; it should be decoupled to ground. VDD2 is the power supply for the
digital circuitry; and should also be decoupled to ground. In addition, a common 10µF tantalum capacitor is required
for low frequencies. Decoupling pins for the internal 1.8V regulators are provided which each require a100nF
capacitor located as close to the device as practical. VB_SYNTH, VB_RAM and VB_DIG require only a 100nF
capacitor. VB_RF and VB_RF2 should be connected together as close to the device as practical, and require one
100nF capacitor and one 47pF capacitor. The pin VB_VCO requires a 10nF capacitor. Refer to B.4.1 for schematic
diagram.
VSSA (paddle), VSS1, VSS2 are the ground pins.
Users are strongly discouraged from connecting their own circuits to the 1.8v regulated supply pins, as the regulators
have been optimised to supply only enough current for the internal circuits.
2.2.2 Reset
RESETN is an active low reset input pin that is connected to a 500kΩ internal pull-up resistor. It may be pulled low
by an external circuit. Refer to Section 6.2 for more details.
2.2.3 32MHz Oscillator
A crystal is connected between XTAL_IN and XTAL_OUT to form the reference oscillator, which drives the system
clock. A capacitor to analogue ground is required on each of these pins. Refer to Section 5.1 for more details. The
32MHz reference frequency is divided down to 16MHz and this is used as the system clock throughout the device.
2.2.4 Radio
The radio is a single ended design, requiring a capacitor and just two inductors to match to 50Ω microstrip line to the
RF_IN pin.
An external resistor (43kΩ) is required between IBIAS and analogue ground (paddle) to set various bias currents and
references within the radio.© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 13
2.2.5 Analogue Peripherals
The ADC requires a reference voltage to use as part of its operation. It can use either an internal reference voltage
or an external reference connected to VREF. This voltage is referenced to analogue ground and the performance of
the analogue peripherals is dependent on the quality of this reference.
There are four ADC inputs and a pair of comparator inputs. ADC1 has a designated input pin but ADC2 uses the
same pin as VREF, invalidating its use as an ADC pin when an external reference voltage is required. The remaining
2 ADC channels are shared with the digital I/Os DIO0 and DIO1 and connect to pins 16 and 17. When these two
ADC channels are selected, the corresponding DIOs must be configured as Inputs with their pull-ups disabled.
Similarly, the comparator shares pins 1 and 2 with DIO16 and DIO17, so when the comparator is selected these pins
must be configured as Inputs with their pull-ups disabled. The analogue I/O pins on the JN516x can have signals
applied up to 0.3v higher than VDD1. A schematic view of the analogue I/O cell is shown in Figure 3. Figure 4
demonstrates a special case, where a digital I/O pin doubles as an input to analogue devices. This applies to ADC3,
ADC4, COMP1P and COMP1M.
In reset, sleep and deep sleep, the analogue peripherals are all off. In sleep, the comparator may optionally be used
as a wakeup source.
Unused ADC and comparator inputs should not be left unconnected, for example connected to analogue ground.
VDD1
Analogue
I/O Pin
VSSA
Analogue
Peripheral
Figure 3: Analogue I/O Cell
2.2.6 Digital Input/Output
For the DC properties of these pins see Section 19.2.3.
When used in their primary function all Digital Input/Output pins are bi-directional and are connected to weak internal
pull up resistors (50kΩ nominal) that can be disabled. When used in their secondary function (selected when the
appropriate peripheral block is enabled through software library calls), their direction is fixed by the function. The pull
up resistor is enabled or disabled independently of the function and direction; the default state from reset is enabled.
A schematic view of the digital I/O cell is in Figure 4. The dotted lines through resistor RESD represent a path that
exists only on DIO0, DIO1, DIO16 and DIO17 which are also inputs to the ADC (ADC3, ADC4) and Comparator
(COMP1P, COMP1M) respectively. To use these DIO pins for their analogue functions, the DIO must be set as an
Input with its pull-up resistor, RPU, disabled.14 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
O
VDD2
Pu
RPU
OE
DIO[x] Pin
RESD
ADC or
COMP1 Input
I
IE
RPROT
VSS VSS
Figure 4: DIO Pin Equivalent Schematic
In reset, the digital peripherals are all off and the DIO pins are set as high-impedance inputs. During sleep and deep
sleep, the DIO pins retain both their input/output state and output level that was set as sleep commences. If the DIO
pins were enabled as inputs and the interrupts were enabled then these pins may be used to wake up the JN516x
from sleep.© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 15
3 CPU
The CPU of the JN516x is a 32-bit load and store RISC processor. It has been architected for three key
requirements:
• Low power consumption for battery powered applications
• High performance to implement a wireless protocol at the same time as complex applications
• Efficient coding of high-level languages such as C provided with the Software Developers Kit
It features a linear 32-bit logical address space with unified memory architecture, accessing both code and data in the
same address space. Registers for peripheral units, such as the timers, UART and the baseband processor are also
mapped into this space.
The CPU has access to a block of 15 32-bit General-Purpose (GP) registers together with a small number of special
purpose registers which are used to store processor state and control interrupt handling. The contents of any GP
register can be loaded from or stored to memory, while arithmetic and logical operations, shift and rotate operations,
and signed and unsigned comparisons can be performed either between two registers and stored in a third, or
between registers and a constant carried in the instruction. Operations between general or special-purpose registers
execute in one cycle while those that access memory require a further cycle to allow the memory to respond.
The instruction set manipulates 8, 16 and 32-bit data; this means that programs can use objects of these sizes very
efficiently. Manipulation of 32-bit quantities is particularly useful for protocols and high-end applications allowing
algorithms to be implemented in fewer instructions than on smaller word-size processors, and to execute in fewer
clock cycles. In addition, the CPU supports hardware Multiply that can be used to efficiently implement algorithms
needed by Digital Signal Processing applications.
The instruction set is designed for the efficient implementation of high-level languages such as C. Access to fields in
complex data structures is very efficient due to the provision of several addressing modes, together with the ability to
be able to use any of the GP registers to contain the address of objects. Subroutine parameter passing is also made
more efficient by using GP registers rather than pushing objects onto the stack. The recommended programming
method for the JN516x is by using C, which is supported by a software developer kit comprising a C compiler, linker
and debugger.
The CPU architecture also contains features that make the processor suitable for embedded, real-time applications.
In some applications, it may be necessary to use a real-time operating system to allow multiple tasks to run on the
processor. To provide protection for device-wide resources being altered by one task and affecting another, the
processor can run in either supervisor or user mode, the former allowing access to all processor registers, while the
latter only allows the GP registers to be manipulated. Supervisor mode is entered on reset or interrupt; tasks starting
up would normally run in user mode in a RTOS environment.
Embedded applications require efficient handling of external hardware events. Exception processing (including reset
and interrupt handling) is enhanced by the inclusion of a number of special-purpose registers into which the PC and
status register contents are copied as part of the operation of the exception hardware. This means that the essential
registers for exception handling are stored in one cycle, rather than the slower method of pushing them onto the
processor stack. The PC is also loaded with the vector address for the exception that occurred, allowing the handler
to start executing in the next cycle.
To improve power consumption a number of power-saving modes are implemented in the JN516x, described more
fully in Section 18. One of these modes is the CPU doze mode; under software control, the processor can be shut
down and on an interrupt it will wake up to service the request. Additionally, it is possible under software control, to
set the speed of the CPU to 1, 2, 4, 8, 16 or 32MHz. This feature can be used to trade-off processing power against
current consumption.16 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
4 Memory Organisation
This section describes the different memories found within the JN516x. The device contains Flash, RAM, and
EEPROM memory, the wireless transceiver and peripherals all within the same linear address space.
0xFFFFFFFF
Unpopulated
0xF0008000
RAM
0x04000000
0x02000000
FLASH Boot Code 8K
0x000C0000
0x00000000
0x00080000
Flash & EEPROM Registers
0x01000000
Peripherals
FLASH
Applications
Code
(256KB)
Figure 5: JN5168 Memory Map
4.1 FLASH
The embedded Flash consists of 2 parts: an 8K region used for holding boot code, and a 256K region (JN5168) used
for application code. The sector size of the application code is always 32K, for any size of Flash memory. The
maximum number of write cycles or endurance is, 10k guaranteed and typically 100k, while the data retention is
guaranteed for at least 10 years. The boot code region is pre-programmed by NXP on supplied parts, and contains
code to handle reset, interrupts and other events (see section 7). It also contains a Flash Programming Interface to
allow interaction with the PC-based Flash Programming Utility which allows user code compiled using the supplied
SDK to be programmed into the Application space. For further information, refer to the Flash Programmer User
Guide.[9]. The memory can be erased by a single or multiple sectors and written to in units of 256 bytes, known as
pagewords.
4.2 RAM
The JN516x devices contain up to 32Kbytes of high speed RAM, which can be accessed by the CPU in a single clock
cycle. It is primarily used to hold the CPU Stack together with program variables and data. If necessary, the CPU can
execute code contained within the RAM (although it would normally just execute code directly from the embedded
Flash). Software can control the power supply to the RAM allowing the contents to be maintained during a sleep
period when other parts of the device are un-powered, allowing a quicker resumption of processing once woken.
4.3 OTP Configuration Memory
The JN516x devices contain a quantity of One Time Programmable (OTP) memory as part of the embedded Flash
(Index Sector). This can be used to securely hold such things as a user 64-bit MAC address and a 128-bit AES
security key. By default the 64-bit MAC address is pre-programmed by NXP on supplied parts; however customers © NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 17
can use their own MAC address and override the default one. The user MAC address and other data can be written
to the OTP memory using the Flash programmer [9]. Details on how to obtain and install MAC addresses can be
found in the Flash Programmer User Guide. In addition 384bits are available, organised as three 128bit words, for
customer use for storage of configuration or other information.
4.4 EEPROM
The JN516x devices contain 4Kbytes of EEPROM. The maximum number of write cycles or endurance is, 100k
guaranteed and 1M typically while the data retention is guaranteed for at least 20 years. (The Persistent Data
Manager, includes a wear-levelling algorithm which can help to extend the endurance.) This non-volatile memory is
primarily used to hold persistent data generated from such things as the Network Stack software component (e.g.
network topology, routing tables). As the EEPROM holds its contents through sleep and reset events, this means
more stable operation and faster recovery is possible after outages. Access to the EEPROM is via registers mapped
into the Flash and EEPROM Registers region of the address map. The memory can be erased by a single or multiple
pages of 64 bytes. It can be written to in single or multiple bytes up to 64 bytes. The customer may use part of the
EEPROM to store its own data if desired by interfacing with the Persistent Data Manager. Optionally the PDM can
also store data in an external memory. For further information, please read - JenOS User Guide [12].
4.5 External Memory
An optional external serial non-volatile memory (eg Flash or EEPROM) with a SPI interface may be used to provide
additional storage for program code, such as a new code image or further data for the device when external power is
removed. The memory can be connected to the SPI Master interface using select line SPISEL0 (see fig 6 for details)
JN516x
Serial
Memory
SPISEL0
SPIMISO
SPIMOSI
SPICLK
SS
SDO
SDI
CLK
Figure 6: Connecting External Serial Memory
The contents of the external serial memory may be encrypted. The AES security processor combined with a user
programmable 128-bit encryption key is used to encrypt the contents of the external memory. The encryption key is
stored in the flash memory index section. When bootloading program code from external serial memory, the JN516x
automatically accesses the encryption key to execute the decryption process, user program code does not need to
handle any of the decryption process; it is transparent. For more details, including the how the program code encrypts
data for the external memory, see the application note Boot Loader Operation. [8]
4.6 Peripherals
All peripherals have their registers mapped into the memory space. Access to these registers requires 3 peripheral
clock cycles. Applications have access to the peripherals through the software libraries that present a high-level view
of the peripheral’s functions through a series of dedicated software routines. These routines provide both a tested
method for using the peripherals and allow bug-free application code to be developed more rapidly. For details, see
Peripherals API User Guide [4].
4.7 Unused Memory Addresses
Any attempt to access an unpopulated memory area will result in a bus error exception (interrupt) being generated.18 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
5 System Clocks
Two system clocks are used to drive the on-chip subsystems of the JN516x. The wake-up timers are driven from a
low frequency clock (notionally 32kHz). All other subsystems (transceiver, processor, memory and digital and
analogue peripherals) are driven by a high-speed clock (notionally 32MHz), or a divided-down version of it.
The high-speed clock is either generated by the accurate crystal-controlled oscillator (32MHz) or the less accurate
high-speed RC oscillator ( 27-32MHz calibrated). The low-speed clock is either generated by the accurate crystalcontrolled
oscillator (32.768kHz), the less accurate RC oscillator (centered on 32kHz) or can be supplied externally
5.1 High-Speed (32MHz) System Clock
The selected high-speed system clock is used directly by the radio subsystem, whereas a divided-by-two version is
used by the remainder of the transceiver and the digital and analogue peripherals. The direct or divided down version
of the clock is used to drive the processor and memories (32, 16, 8, 4, 2 or 1MHz).
High Speed
RC Oscillator
32MHz Crystal
Oscillator
Div by 1,2,4,8,16 or 32
Div by 2
PERIPHERAL SYSTEM CLOCK
CPU CLOCK
Figure 7 System and CPU Clocks
Crystal oscillators are generally slow to start. Hence to provide a fast start-up following a sleep cycle or reset, the fast
RC oscillator is always used as the initial source for the high-speed system clock. The oscillator starts very quickly
and will run at 25-32MHz (uncalibrated) or 32MHz +/-5% (calibrated). Although this means that the system clock will
be running at an undefined frequency (slightly slower or faster than nominal), this does not prevent the CPU and
Memory subsystems operating normally, so the program code can execute. However, it is not possible to use the
radio or UARTs, as even after calibration (initiated by the user software calling an API function) there is still a +/-5%
tolerance in the clock rate over voltage and temperature. Other digital peripherals can be used (eg SPI Master/Slave),
but care must be taken if using Timers due to the clock frequency inaccuracy.
Further details of the High-Speed RC Oscillator can be found in section 19.3.11.
On wake-up from sleep, the JN516x uses the Fast RC oscillator. It can then either:
• Automatically switch over to use the 32MHz clock source when it has started up.
• Continue to use the fast RC oscillator until software triggers the switch-over to the 32MHz clock source, for
example when the radio is required.
• Continue to use the RC oscillator until the device goes back into one of the sleep modes.
The use of the fast RC Oscillator at wake-up means there is no need to wait for the 32MHz crystal oscillator to
stabilise Consequently, the application code will start executing quickly using the clock from the high-speed RC
oscillator.
5.1.1 32MHz Crystal Oscillator
The JN516x contains the necessary on chip components to build a 32MHz reference oscillator with the addition of an
external crystal resonator and two tuning capacitors. The schematic of these components are shown in Figure 8.
The two capacitors, C1 and C2, should typically be 15pF and use a COG dielectric. Due to the small size of these
capacitors, it is important to keep the traces to the external components as short as possible. The on chip
transconductance amplifier is compensated for temperature variation, and is self-biasing by means of the internal
resistor R1. This oscillator provides the frequency reference for the radio and therefore it is essential that the
reference PCB layout and BOM are carefully followed. The electrical specification of the oscillator can be found in © NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 19
Section 19.3.11. Please refer to Appendix B for development support with the crystal oscillator circuit. The oscillator
includes a function which flags when the amplitude of oscillation has reached a satisfactory level for full operation,
and this is checked before the source of the high-speed system clock is changed to the 32MHz crystal oscillator
XTALOUT
C1 C2
XTALIN R1
JN516x
Figure 8: 32MHz Crystal Oscillator Connections
For operation over the extended temperature range, 85 to 125 deg C, special care is required; this is because the
temperature characteristics of crystal resonators are generally in excess of +/-40ppm frequency tolerance defined by
the IEEE802.15.4 standard. The oscillator cell contains additional circuitry to compensate for the poor performance of
the crystal resonators above 100 deg C. Full details, including the software API function, can be found in the
application note JN516x Temperature-dependent Operating Guidelines [2]
5.1.2 High-Speed RC Oscillator
An on-chip High-Speed RC oscillator is provided in addition to the 32MHz crystal oscillator for two purposes, to allow
a fast start-up from reset or sleep and to provide a lower current alternative to the crystal oscillator for non-timing
critical applications. By default the oscillator will run at 27MHz typically with a wide tolerance. It can be calibrated,
using a software API function, which will result in a nominal frequency of 32MHz with a +/-1.6% tolerance at 3v and
25 deg C. However, it should be noted that over the full operating range of voltage and temperature this will increase
to +/-5%. The calibration information is retained through speed cycles and when the oscillator is disabled, so typically
the calibration function only needs to be called once. No external components are required for this oscillator. The
electrical specification of the oscillator can be found in Section 19.3.12.
5.2 Low-speed (32kHz) System Clock
The 32kHz system clock is used for timing the length of a sleep period (see Section 18). The clock can be selected
from one of three sources through the application software:
• 32kHz RC Oscillator
• 32kHz Crystal Oscillator
• 32kHz External Clock
Upon a chip reset or power-up the JN516x defaults to using the internal 32kHz RC Oscillator. If another clock source
is selected then it will remain in use for all 32kHz timing until a chip reset is performed.
5.2.1 32kHz RC Oscillator
The internal 32kHz RC oscillator requires no external components. The internal timing components of the oscillator
have a wide tolerance due to manufacturing process variation and so the oscillator runs nominally at 32kHz -10%
/+40%. To make this useful as a timing source for accurate wakeup from sleep, a frequency calibration factor derived
from the more accurate 16MHz clock may be applied. The calibration factor is derived through software, details can
be found in Section 11.3.1. Software must check that the 32kHz RC oscillator is running before using it. The oscillator
has a default current consumption of around 0.5uA, optionally this can be reduced to 0.375uA, however, the 20 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
calibrated accuracy and temperature coefficient will be worse as a consequence. For detailed electrical
specifications, see Section 19.3.9.
5.2.2 32kHz Crystal Oscillator
In order to obtain more accurate sleep periods, the JN516x contains the necessary on-chip components to build a
32kHz oscillator with the addition of an external 32.768kHz crystal and two tuning capacitors. The crystal should be
connected between 32KXTALIN and 32KXTALOUT (DIO9 and DIO10), with two equal capacitors to ground, one on
each pin. Due to the small size of the capacitors, it is important to keep the traces to the external components as
short as possible.
The electrical specification of the oscillator can be found in Section 19.3.10. The oscillator cell is flexible and can
operate with a range of commonly available 32.768kHz crystals with load capacitances from 6 to 12.5pF. However,
the maximum ESR of the crystal and the supply current are both functions of the actual crystal used, see Appendix
B.1 for more details.
32KXTALIN 32KXTALOUT
JN516x
Figure 9: 32kHz Crystal Oscillator Connections
5.2.3 32kHz External Clock
An externally supplied 32kHz reference clock on the 32KXTALIN input (DIO9) may be provided to the JN516x. This
would allow the 32kHz system clock to be sourced from a very stable external oscillator module, allowing more
accurate sleep cycle timings compared to the internal RC oscillator. (See Section 19.2.3)© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 21
6 Reset
A system reset initialises the device to a pre-defined state and forces the CPU to start program execution from the
reset vector. The reset process that the JN516x goes through is as follows.
When power is first applied or when the external reset is released, the High-Speed RC oscillator and 32MHz crystal
oscillator are activated. After a short wait period (13µsec approx) while the High-Speed RC starts up, and so long as
the supply voltage satisfies the default Supply Voltage Monitor (SVM) threshold (2.0V+0.045V hysteresis), the
internal 1.8V regulators are turned on to power the processor and peripheral logic. The regulators are allowed to
stabilise (about 15us) followed by a further wait (150usec approx) to allow the Flash and EEPROM bandgaps to
stabilise and allow their initialisation, including reading the user SVM threshold from the Flash. This is applied to the
SVM and, after a brief pause (approx 2.5usec), the SVM is checked again. If the supply is above the new SVM
threshold, the CPU and peripheral logic is released from reset and the CPU starts to run code beginning at the reset
vector. This runs the bootloader code contained within the flash, which looks for a valid application to run, first from
the internal flash and then from any connected external serial memory over the SPI Master interface. Once found,
required variables are initialised in RAM before the application is called at its AppColdStart entry point. More details
on the bootloader can be found in the application note - Boot Loader Operation. [8]
The JN516x has five sources of reset:
• Internal Power-on / Brown-out Reset (BOR)
• External Reset
• Software Reset
• Watchdog timer
• Supply Voltage detect
Note: When the device exits a reset condition, device operating
parameters (voltage, frequency, temperature, etc.) must be met to ensure
operation. If these conditions are not met, then the device must be held in
reset until the operating conditions are met. (See Section 19.3)
6.1 Internal Power-On / Brown-out Reset (BOR)
For the majority of applications the internal power-on reset is capable of generating the required reset signal. When
power is applied to the device, the power-on reset circuit monitors the rise of the VDD supply. When the VDD
reaches the specified threshold, the reset signal is generated. This signal is held internally until the power supply and
oscillator stabilisation time has elapsed, when the internal reset signal is then removed and the CPU is allowed to
run.
The BOR circuit has the ability to reject spikes on the VDD rail to avoid false triggering of the reset module. Typically
for a negative going square pulse of duration 1uS, the voltage must fall to 1.2v before a reset is generated. Similarly
for a triangular wave pulse of 10us width, the voltage must fall to 1.3v before causing a reset. The exact
characteristics are complex and these are only examples.
Internal RESET
VDD
Figure 10: Internal Power-on Reset
When the supply drops below the power on reset ‘falling’ threshold, it will re-trigger the reset. If necessary, use of the
external reset circuit show in Figure 11 is suggested. 22 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
RESETN
C1
R1
JN516x
VDD
18k
470nF
Figure 11: External Reset Generation
The external resistor and capacitor provide a simple reset operation when connected to the RESETN pin but are not
neccessary.
6.2 External Reset
An external reset is generated by a low level on the RESETN pin. Reset pulses longer than the minimum pulse width
will generate a reset during active or sleep modes. Shorter pulses are not guaranteed to generate a reset. The
JN516x is held in reset while the RESETN pin is low. When the applied signal reaches the Reset Threshold Voltage
(VRST) on its positive edge, the internal reset process starts.
The JN516x has an internal 500kΩ pull-up resistor connect to the RESETN pin. The pin is an input for an external
reset only. By holding the RESETN pin low, the JN516x is held in reset, resulting in a typical current of 6uA.
Internal Reset
RESETN pin
Reset
Figure 12: External Reset
6.3 Software Reset
A system reset can be triggered at any time through software control, causing a full chip reset and invalidating the
RAM contents. For example this can be executed within a user’s application upon detection of a system failure.
6.4 Supply Voltage Monitor (SVM)
An internal Supply Voltage Monitor (SVM) is used to monitor the supply voltage to the JN516x; this can be used
whilst the device is awake or is in CPU doze mode. Dips in the supply voltage below a variable threshold can be
detected and can be used to cause the JN516x to perform a chip reset. Equally, dips in the supply voltage can be © NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 23
detected and used to cause an interrupt to the processor, when the voltage either drops below the threshold or rises
above it.
The supply voltage detect is enabled by default from power-up and can extend the reset during power-up. This will
keep the CPU in reset until the voltage exceeds the SVM threshold voltage. The threshold voltage is configurable to
1.95V, 2.0V, 2.1V, 2.2V, 2.3V, 2.4V, 2.7V and 3.0V and is controllable by software. From power-up the threshold is
set by a setting within the flash and the default chip configuration is for the 2.0V threshold. It is expected that the
threshold is set to the minimum needed by the system..
6.5 Watchdog Timer
A watchdog timer is provided to guard against software lockups. It operates by counting cycles of the high-speed RC
system clock. A pre-scaler is provided to allow the expiry period to be set between typically 8ms and 16.4 seconds
(dependent on high-speed RC accuracy: +30%, -15%). Failure to restart the watchdog timer within the pre-configured
timer period will cause a chip reset to be performed. A status bit is set if the watchdog was triggered so that the
software can differentiate watchdog initiated resets from other resets, and can perform any required recovery once it
restarts. Optionally, the watchdog can cause an exception rather than a reset, this preserves the state of the memory
and is useful for debugging.
After power up, reset, start from deep sleep or start from sleep, the watchdog is always enabled with the largest
timeout period and will commence counting as if it had just been restarted. Under software control the watchdog can
be disabled. If it is enabled, the user must regularly restart the watchdog timer to stop it from expiring and causing a
reset. The watchdog runs continuously, even during doze, however the watchdog does not operate during sleep or
deep sleep, or when the hardware debugger has taken control of the CPU. It will recommence automatically if
enabled once the debugger un-stalls the CPU. 24 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
7 Interrupt System
The interrupt system on the JN516x is a hardware-vectored interrupt system. The JN516x provides several interrupt
sources, some associated with CPU operations (CPU exceptions) and others which are used by hardware in the
device. When an interrupt occurs, the CPU stops executing the current program and loads its program counter with a
fixed hardware address specific to that interrupt. The interrupt handler or interrupt service routine is stored at this
location and is run on the next CPU cycle. Execution of interrupt service routines is always performed in supervisor
mode. Interrupt sources and their vector locations are listed in Table 1 below:
Interrupt Source Vector Location Interrupt Definition
Bus error 0x08 Typically cause by an attempt to access an invalid address or a
disabled peripheral
Tick timer 0x0e Tick timer interrupt asserted
Alignment error 0x14 Load/store address to non-naturally-aligned location
Illegal instruction 0x1a Attempt to execute an unrecognised instruction
Hardware interrupt 0x20 interrupt asserted
System call 0x26 System call initiated by b.sys instruction
Trap 0x2c caused by the b.trap instruction or the debug unit
Reset 0x38 Caused by software or hardware reset.
Stack Overflow 0x3e Stack overflow
Table 1: Interrupt Vectors
7.1 System Calls
The b.trap and b.sys instructions allow processor exceptions to be generated by software.
A system call exception will be generated when the b.sys instruction is executed. This exception can, for example, be
used to enable a task to switch the processor into supervisor mode when a real time operating system is in use. (See
Section 3 for further details.)
The b.trap instruction is commonly used for trapping errors and for debugging.
7.2 Processor Exceptions
7.2.1 Bus Error
A bus error exception is generated when software attempts to access a memory address that does not exist, or is not
populated with memory or peripheral registers.
7.2.2 Alignment
Alignment exceptions are generated when software attempts to access objects that are not aligned to natural word
boundaries. 16-bit objects must be stored on even byte boundaries, while 32-bit objects must be stored on quad byte
boundaries. For instance, attempting to read a 16-bit object from address 0xFFF1 will trigger an alignment exception
as will a read of a 32-bit object from 0xFFF1, 0xFFF2 or 0xFFF3. Examples of legal 32-bit object addresses are
0xFFF0, 0xFFF4, 0xFFF8 etc.
7.2.3 Illegal Instruction
If the CPU reads an unrecognised instruction from memory as part of its instruction fetch, it will cause an illegal
instruction exception.
7.2.4 Stack Overflow
When enabled, a stack overflow exception occurs if the stack pointer reaches a programmable location.© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 25
7.3 Hardware Interrupts
Hardware interrupts generated from the transceiver, analogue or digital peripherals and DIO pins are individually
masked using the Programmable Interrupt Controller (PIC). Management of interrupts is provided in the Peripherals
API User Guide [4]. For details of the interrupts generated from each peripheral see the respective section in this
datasheet.
Interrupts can be used to wake the JN516x from sleep. The peripherals, baseband controller, security coprocessor
and PIC are powered down during sleep but the DIO interrupts and optionally the pulse counters, wake-up timers and
analogue comparator interrupts remain powered to bring the JN516x out of sleep.
Prioritised external interrupt handling (i.e., interrupts from hardware peripherals) is provided to enable an application
to control an events priority to provide for deterministic program execution.
The priority Interrupt controller provides 15 levels of prioritised interrupts. The priority level of all interrupts can be set,
with value 0 being used to indicate that the source can never produce an external interrupt, 1 for the lowest priority
source(s) and 15 for the highest priority source(s). Note that multiple interrupt sources can be assigned the same
priority level if desired.
If while processing an interrupt, a new event occurs at the same or lower priority level, a new external interrupt will
not be triggered. However, if a new higher priority event occurs, the external interrupt will again be asserted,
interrupting the current interrupt service routine.
Once the interrupt service routine is complete, lower priority events can be serviced. 26 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
8 Wireless Transceiver
The wireless transceiver comprises a 2.45GHz radio, modem, a baseband processor, a security coprocessor and
PHY controller. These blocks, with protocol software provided as a library, implement an IEEE802.15.4 standardsbased
wireless transceiver that transmits and receives data over the air in the unlicensed 2.4GHz band.
8.1 Radio
Figure 13 shows the single ended radio architecture.
LNA
synth
PA
ADC Reference
& Bias
Switch
Radio
Calibration
Lim1
Lim2
Lim3
Lim4
sigma
delta
D-Type
Figure 13: Radio Architecture
The radio comprises a low-IF receive path and a direct modulation transmit path, which converge at the TX/RX
switch. The switch connects to the external single ended matching network, which consists of two inductors and a
capacitor, this arrangement creates a 50Ω port and removes the need for a balun. A 50Ω single ended antenna can
be connected directly to this port.
The 32MHz crystal oscillator feeds a divider, which provides the frequency synthesiser with a reference frequency.
The synthesiser contains programmable feedback dividers, phase detector, charge pump and internal Voltage
Controlled Oscillator (VCO). The VCO has no external components, and includes calibration circuitry to compensate
for differences in internal component values due to process and temperature variations. The VCO is controlled by a
Phase Locked Loop (PLL) that has an internal loop filter. A programmable charge pump is also used to tune the loop
characteristic.
The receiver chain starts with the low noise amplifier/mixer combination whose outputs are passed to a low pass
filter, which provides the channel definition. The signal is then passed to a series of amplifier blocks forming a limiting
strip. The signal is converted to a digital signal before being passed to the Modem. The gain control for the RX path
is derived in the automatic gain control (AGC) block within the Modem, which samples the signal level at various
points down the RX chain. To improve the performance and reduce current consumption, automatic calibration is
applied to various blocks in the RX path.
In the transmit direction, the digital stream from the Modem is passed to a digital sigma-delta modulator which
controls the feedback dividers in the synthesiser, (dual point modulation). The VCO frequency now tracks the applied
modulation. The 2.4 GHz signal from the VCO is then passed to the RF Power Amplifier (PA), whose power control
can be selected from one of three settings. The output of the PA drives the antenna via the RX/TX switch© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 27
The JN516x radio when enabled is automatically calibrated for optimum performance. In operating environments with
a significant variation in temperature (e.g. greater than 20 deg C) due to diurnal or ambient temperature variation, it is
recommended to recalibrate the radio to maintain performance. Recalibration is only required on Routers and End
Devices that never sleep. End Devices that sleep when idle are automatically recalibrated when they wake. An
Application Note JN516x Temperature-dependent Operating Guidelines [2] describes this in detail and includes a
software API function which can be used to test the temperature using the on-chip temperature sensor and trigger a
recalibration if there has been a significant temperature change since the previous calibration.
8.1.1 Radio External Components
In order to realise the full performance of the radio it is essential that the reference PCB layout and BOM are carefully
followed. See Appendix B.4.
The radio is powered from a number of internal 1.8V regulators fed from the analogue supply VDD1, in order to
provide good noise isolation between the digital logic of the JN516x and the analogue blocks. These regulators are
also controlled by the baseband controller and protocol software to minimise power consumption. Decoupling for
internal regulators is required as described in Section 2.2.1.
For single ended antennas or connectors, a balun is not required, however a matching network is needed.
The RF matching network requires three external components and the IBIAS pin requires one external component as
shown in schematic in B.4.1. These components are critical and should be placed close to the JN516x pins and
analogue ground as defined in Table 12. Specifically, the output of the network comprising L2, C1 and L1 is
designed to present an accurate match to a 50 ohm resistive network as well as provide a DC path to the final output
stage or antenna. Users wishing to match to other active devices such as amplifiers should design their networks to
match to 50 ohms at the output of L1
R1 43K
IBIAS
C20 100nF
L2 3.9nH
VB_RF
VREF
VB_RF2
RF_IN
C3 100nF
C12 47pF
VB_RF1
C1 47pF L1 5.1nH
To Coaxial Socket
or Integrated Antenna
VB_RF
Figure 14: External Radio Components
8.1.2 Antenna Diversity
Support is provided for antenna diversity. Antenna diversity is a technique that maximises the performance of an
antenna system. It allows the radio to switch between two antennas that have very low correlation between their
received signals. Typically, this is achieved by spacing two antennae around 0.25 wavelengths apart or by using two
orthogonal polarisations. So, if a packet is transmitted and no acknowledgement is received, the radio system can
switch to the other antenna for the retry, with a different probability of success.28 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
Additionally antenna diversity can be enabled whilst in receive mode waiting for a packet. The JN516x measures the
received energy in the relevant radio channel every 40μs and the measured energy level is compared with a pre-set
energy threshold, which can be set by the application program. The JN516x device will automatically switch the
antennae if the measurement is below this threshold, except if waiting for an acknowledgement from a previous
transmission or if the process of receiving a packet, when it will wait until this has finished. Also, it will not switch if a
preamble symbol having a signal quality above a minimum specified threshold has not been detected in the last 40μs
Both modes can be used at once and use the same ADO and ADE outputs to control the switch.
The JN516x provides an output (ADO) on DIO12 that is asserted on odd numbered retries and optionally its
complement (ADE) on DIO13, that can be used to control an antenna switch; this enables antenna diversity to be
implemented easily (see Figure 15 and Figure 16).
Antenna A Antenna B
A B
COM
SEL
SELB
ADO (DIO[12])
ADE (DIO[13])
Device RF Port
RF Switch: Single-Pole, Double-Throw (SPDT)
Figure 15: Simple Antenna Diversity Implementation using External RF Switch
ADO (DIO[12])
TX Active
RX Active
ADE (DIO[13])
1st TX-RX Cycle 2nd TX-RX Cycle (1st Retry)
Figure 16: Antenna Diversity ADO Signal for TX with Acknowledgement
If two DIO pins cannot be spared, DIO13 can be configured to be a normal DIO pin, and the inverse of ADO
generated with an inverter on the PCB. © NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 29
8.2 Modem
The modem performs all the necessary modulation and spreading functions required for digital transmission and
reception of data at 250kbps in the 2450MHz radio frequency band in compliance with the IEEE802.15.4 standard.
AGC Demodulation
Symbol
Detection
(Despreading)
Modulation Spreading
TX
RX
TX Data
Interface
RX Data
Interface
VCO
Sigma-Delta
Modulator
IF Signal
Gain
Figure 17: Modem Architecture
Features provided to support network channel selection algorithms include Energy Detection (ED), Link Quality
Indication (LQI) and fully programmable Clear Channel Assessment (CCA).
The Modem provides a digital Receive Signal Strength Indication (RSSI) that facilitates the implementation of the
IEEE 802.15.4 ED function and LQI function.
The ED and LQI are both related to receiver power in the same way, as shown in Figure 18. LQI is associated with a
received packet, whereas ED is an indication of signal power on air at a particular moment.
The CCA capability of the Modem supports all modes of operation defined in the IEEE 802.15.4 standard, namely
Energy above ED threshold, Carrier Sense and Carrier Sense and/or energy above ED threshold.
Figure 18: Energy Detect Value vs Receive Power Level30 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
8.3 Baseband Processor
The baseband processor provides all time-critical functions of the IEEE802.15.4 MAC layer. Dedicated hardware
guarantees air interface timing is precise. The MAC layer hardware/software partitioning, enables software to
implement the sequencing of events required by the protocol and to schedule timed events with millisecond
resolution, and the hardware to implement specific events with microsecond timing resolution. The protocol software
layer performs the higher-layer aspects of the protocol, sending management and data messages between endpoint
and coordinator nodes, using the services provided by the baseband processor.
Supervisor
Append
Checksum Serialiser
DMA
Engine
TX
Stream
Radio
Protocol Timing Engine
CSMA CCA Backoff
Control
Control
RX
Stream Verify
Checksum Deserialiser
Protocol
Timers
Security Coprocessor
AES
Codec
Encrypt
Port
Decrypt
Port
Status
Processor
Bus
Figure 19: Baseband Processor
8.3.1 Transmit
A transmission is performed by software writing the data to be transferred into the Tx Frame Buffer in RAM, together
with parameters such as the destination address and the number of retries allowed, and programming one of the
protocol timers to indicate the time at which the frame is to be sent. This time will be determined by the software
tracking the higher-layer aspects of the protocol such as superframe timing and slot boundaries. Once the packet is
prepared and protocol timer set, the supervisor block controls the transmission. When the scheduled time arrives,
the supervisor controls the sequencing of the radio and modem to perform the type of transmission required, fetching
the packet data directly from RAM. It can perform all the algorithms required by IEEE802.15.4 such as CSMA/CA
without processor intervention including retries and random backoffs.
When the transmission begins, the header of the frame is constructed from the parameters programmed by the
software and sent with the frame data through the serialiser to the Modem. At the same time, the radio is prepared
for transmission. During the passage of the bitstream to the modem, it passes through a CRC checksum generator
that calculates the checksum on-the-fly, and appends it to the end of the frame.
8.3.2 Reception
During reception, the radio is set to receive on a particular channel. On receipt of data from the modem, the frame is
directed into the Rx Frame Buffer in RAM where both header and frame data can be read by the protocol software.
An interrupt may be provided on receipt of the frame header. As the frame data is being received from the modem it
is passed through a checksum generator; at the end of the reception the checksum result is compared with the
checksum at the end of the message to ensure that the data has been received correctly. An interrupt may be
provided to indicate successful packet reception. During reception, the modem determines the Link Quality, which is
made available at the end of the reception as part of the requirements of IEEE802.15.4.© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 31
8.3.3 Auto Acknowledge
Part of the protocol allows for transmitted frames to be acknowledged by the destination sending an acknowledge
packet within a very short window after the transmitted frame has been received. The JN516x baseband processor
can automatically construct and send the acknowledgement packet without processor intervention and hence avoid
the protocol software being involved in time-critical processing within the acknowledge sequence. The JN516x
baseband processor can also request an acknowledge for packets being transmitted and handle the reception of
acknowledged packets without processor intervention.
8.3.4 Beacon Generation
In beaconing networks, the baseband processor can automatically generate and send beacon frames; the repetition
rate of the beacons is programmed by the CPU, and the baseband then constructs the beacon contents from data
delivered by the CPU. The baseband processor schedules the beacons and transmits them without CPU
intervention.
8.3.5 Security
The transmission and reception of secured frames using the Advanced Encryption Standard (AES) algorithm is
handled by the security coprocessor and the stack software. The application software must provide the appropriate
encrypt/decrypt keys for the transmission or reception. On transmission, the key can be programmed at the same
time as the rest of the frame data and setup information.
8.4 Security Coprocessor
The security coprocessor is available to the application software to perform encryption/decryption operations. A
hardware implementation of the encryption engine significantly speeds up the processing of the encrypted packets
over a pure software implementation. The AES library for the JN516x provides operations that utilise the encryption
engine in the device and allow the contents of memory buffers to be transformed. Information such as the type of
security operation to be performed and the encrypt/decrypt key to be used must also be provided.
Processor
Interface
AES
Block
Encryption
Controller
AES
Encoder
Key Generation
Figure 20: Security Coprocessor Architecture
8.5 Time of Flight Engine
The JN516x family includes unique hardware functions to enable measurement of the distance between two nodes
using a “Time of Flight” (ToF) function. This function uses dedicated timers and interpolation of the timing of
correlation peaks in the demodulator to measure the delays introduced by the time taken for the radio signals to travel
between nodes. It is also possible to use the received signal strength (RSSI) to indicate the distance. Due to the
characteristics of the transmitted signal and the baseband circuitry, ToF offers a significant improvement in accuracy
for distance measurements above 10m compared with RSSI, while RSSI provides better ranging results below 10m.
Hence, ToF is best suited to long range distance measurement. The raw timing results are made available through
an API function, but the responsibility for converting these into location information lies with the user.
For more information, see the Time-of-flight API User Guide [10]32 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
9 Digital Input/Output
There are 20 Digital I/O (DIO) pins which when used as general-purpose pins can be configured as either an input or
an output, with each having a selectable internal pull-up resistor. In addition, there are 2 Digital Output (DO) pins.
Most DIO pins are shared with the digital and analogue peripherals of the device. When a peripheral is enabled, it
takes control over the device pins allocated to it. However, note that most peripherals have 2 alternative pin
allocations to alleviate clashes between uses, and many peripherals can disable the use of specific pins if not
required. Refer to Section 2.1 and the individual peripheral descriptions for full details of the available pinout
arrangements.
Following a reset (and whilst the RESETN input is held low), all peripherals are forced off and the DIO pins are
configured as inputs with the internal pull-ups turned on.When a peripheral is not enabled, the DIO pins associated
with it can be used as digital inputs or outputs. Each pin can be controlled individually by setting the direction and
then reading or writing to the pin.
The individual pull-up resistors, RPU, can also be enabled or disabled as needed and the setting is held through sleep
cycles. The pull-ups are generally configured once after reset depending on the external components and
functionality. For instance, outputs should generally have the pull-ups disabled. An input that is always driven should
also have the pull-up disabled.
When configured as an input each pin can be used to generate an interrupt upon a change of state (selectable
transition either from low to high or high to low); the interrupt can be enabled or disabled. When the device is
sleeping, these interrupts become events that can be used to wake the device up. Equally the status of the interrupt
may be read. See Section 18 for further details on sleep and wakeup.
The state of all DIO pins can be read, irrespective of whether the DIO is configured as an input or an output.
Throughout a sleep cycle the direction of the DIO, and the state of the outputs, is held. This is based on the resultant
of the GPIO Data/Direction registers and the effect of any enabled peripherals at the point of entering sleep.
Following a wake-up these directions and output values are maintained under control of the GPIO data/direction
registers. Any peripherals enabled before the sleep cycle are not automatically re-enabled, this must be done through
software after the wake-up.
For example, if DIO0 is configured to be SPISEL1 then it becomes an output. The output value is controlled by the
SPI functional block. If the device then enters a sleep cycle, the DIO will remain an output and hold the value being
output when entering sleep. After wake-up the DIO will still be an output with the same value but controlled from the
GPIO Data/Direction registers. It can be altered with the software functions that adjust the DIO, or the application may
re-configure it to be SPISEL1.
Unused DIO pins are recommended to be set as inputs with the pull-up enabled.
Two DIO pins can optionally be used to provide control signals for RF circuitry (e.g. switches and PA) in high power
range extenders.
DIO3/RFTX is asserted when the radio is in the transmit state and similarly, DIO2/RFRX is asserted when the radio is
in the receiver state.© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 33
MUX
SPI Slave
DIO0/SPISEL1/ADC3
DIO1/SPISEL2/ADC4/PC0
DIO2/RFRX/TIM0CK_GT
DIO3/RFTX/TIM0CAP
DIO4/CTS0/TIM0OUT/PC0
DIO5/RTS0/PWM1/PC1
DIO6/TXD0/PWM2
DIO7/RXD0/PWM3
DIO8/TIM0CK_GT/PC1/PWM4
DIO9/TIM0CAP/32KXTALIN/RXD1/32KIN
DIO10/TIM0OUT/32KXTALOUT
DIO11/PWM1/TXD1
DIO12/PWM2/CTS0/ADO/SPISMOSI
DIO13/PWM3/RTS0/ADE/SPISMISO
DIO14/SIF_CLK/TXD0/TXD1/SPISEL1/SPISSEL
DIO15/SIF_D/RXD0/RXD1/SPISEL2/SPISCLK
DIO16/COMP1P/SIF_CLK/SPISMOSI
DIO17/COMP1M/SIF_D/SPISMISO
DIO18/SPIMOSI
DIO19/SPISEL0
DO0/SPICLK/PWM2
DO1/SPIMISO/PWM3
TXD0
SPI
Master
UART0
UART1
RXD0
RTS0
CTS0
TxD1
RxD1
TIM0CK_GT
TIM0OUT
TIM0CAP
PWM1
PWM2
PWM3
PWM4
SIF_D
SIF_CLK
PC0
PC1
JTAG_TDI
JTAG_TMS
JTAG_TCK
JTAG_TDO
ADO
ADE
Timer0
PWMs
2-wire
Interface
Pulse
Counters
JTAG
Debug
Antenna
Diversity
SPICLK
SPIMOSI
SPIMISO
SPISEL0
SPICLK
SPIMOSI
SPIMISO
SPISEL0
SPISEL1
SPISEL2
Figure 21 DIO Block Diagram34 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
10 Serial Peripheral Interface
10.1 Serial Peripheral Interface Master
The Serial Peripheral Interface (SPI) allows high-speed synchronous data transfer between the JN516x and
peripheral devices. The JN516x operates as a master on the SPI bus and all other devices connected to the SPI are
expected to be slave devices under the control of the JN516x CPU. The SPI includes the following features:
• Full-duplex, three-wire synchronous data transfer
• Programmable bit rates (up to 16Mbit/s)
• Programmable transaction size up to 32-bits
• Standard SPI modes 0,1,2 and 3
• Manual or Automatic slave select generation (up to 3 slaves)
• Maskable transaction complete interrupt
• LSB First or MSB First Data Transfer
• Supports delayed read edges
Clock
Divider
SPI Bus
Cycle
Controller
Data Buffer
DIV
Clock Edge
Select
Data
CHAR_LEN
LSB
SPIMISO
SPIMOSI
SPICLK
Select
Latch
SPISEL [2..0]
16 MHz
Figure 22: SPI Master Block Diagram
The SPI bus employs a simple shift register data transfer scheme. Data is clocked out of and into the active devices
in a first-in, first-out fashion allowing SPI devices to transmit and receive data simultaneously. Master-Out-Slave-In or
Master-In-Slave-Out data transfer is relative to the clock signal SPICLK generated by the JN516x.
The JN516x provides three slave selects, SPISEL0 to SPISEL2 to allow three SPI peripherals on the bus. SPISEL0
is accessed on DI019. SPISEL1 is accessed, depending upon the configuration, on DIO0 or DIO14. SPISEL2 is
accessed on DIO1 or DIO15. This is enabled under software control. The following table details which DIO are used
for the SPISEL signals depending upon the configuration.
Signal DIO Assignment
Standard pins Alternative pins
SPISEL1 DIO0 DIO14
SPISEL2 DIO1 DIO15
SPICLK DO0
SPIMISO DO1
SPIMOSI DIO18
SPISEL0 DIO19
Table 2: SPI Master IO© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 35
The interface can transfer from 1 to 32-bits without software intervention and can keep the slave select lines asserted
between transfers when required, to enable longer transfers to be performed.
When the device reset is active, all the SPI Master pins are configured as inputs with their pull-up resistors active.
The pins stay in this state until the SPI Master block is enabled, or the pins are configured for some other use. SS
Slave 0
Flash/
EEPROM
Memory
JN5142 SPISE L0 SPISE L1
SPIMOSI
SPICLK
SPIMISO SS
Slave 1
User
Defined
SS
Slave 2
User
Defined
SPISE L2
SI
C
SO
SI
C
SO
SI
C
SO
JN516X
Figure 23: Typical JN516x SPI Peripheral Connection
The data transfer rate on the SPI bus is determined by the SPICLK signal. The JN516x supports transfers at
selectable data rates from 16MHz to 125kHz selected by a clock divider. Both SPICLK clock phase and polarity are
configurable. The clock phase determines which edge of SPICLK is used by the JN516x to present new data on the
SPIMOSI line; the opposite edge will be used to read data from the SPIMISO line. The interface should be configured
appropriately for the SPI slave being accessed.
SPICLK
Polarity Mode Description
(CPOL)
Phase
(CPHA)
0 0 0 SPICLK is low when idle – the first edge is positive.
Valid data is output on SPIMOSI before the first clock and changes every
negative edge. SPIMISO is sampled every positive edge.
0 1 1 SPICLK is low when idle – the first edge is positive.
Valid data is output on SPIMOSI every positive edge. SPIMISO is sampled every
negative edge.
1 0 2 SPICLK is high when idle – the first edge is negative.
Valid data is output on SPIMOSI before the first clock edge and is changed
every positive edge. SPIMISO is sampled every negative edge.
1 1 3 SPICLK is high when idle – the first edge is negative.
Valid data is output on SPIMOSI every negative edge. SPIMISO is sampled
every positive edge.
Table 3: SPI Configurations36 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
If more than one SPISEL line is to be used in a system they must be used in numerical order starting from SPISEL0.
A SPISEL line can be automatically de-asserted between transactions if required, or it may stay asserted over a
number of transactions. For devices such as memories where a large amount of data can be received by the master
by continually providing SPICLK transitions, the ability for the select line to stay asserted is an advantage since it
keeps the slave enabled over the whole of the transfer.
A transaction commences with the SPI bus being set to the correct configuration, and then the slave device is
selected. Upon commencement of transmission (1 to 32 bits) data is placed in the FIFO data buffer and clocked out,
at the same time generating the corresponding SPICLK transitions. Since the transfer is full-duplex, the same
number of data bits is being received from the slave as it transmits. The data that is received during this transmission
can be read (1 to 32 bits). If the master simply needs to provide a number of SPICLK transitions to allow data to be
sent from a slave, it should perform transmit using dummy data. An interrupt can be generated when the transaction
has completed or alternatively the interface can be polled.
If a slave device wishes to signal the JN516x indicating that it has data to provide, it may be connected to one of the
DIO pins that can be enabled as an interrupt.
Figure 24 shows a complex SPI transfer, reading data from a FLASH device that can be achieved using the SPI
master interface. The slave select line must stay low for many separate SPI accesses, and therefore manual slave
select mode must be used. The required slave select can then be asserted (active low) at the start of the transfer. A
sequence 8 and 32 bit transfers can be used to issue the command and address to the FLASH device and then to
read data back. Finally, the slave select can be deselected to end the transaction.
0 1 2 3 4 5 6 7
Instruction (0x03)
23 22 21 3 2 1 0
8 9 10 28 29 30 31
24-bit Address
MSB
Instruction Transaction
7 6 5 4 3 2 1 0
MSB
0 1 2 3 4 5 7 8N-1
3 2 1 0
LSB
Read Data Bytes Transaction(s) 1-N
SPISEL
SPICLK
SPIMOSI
SPIMISO
SPISEL
SPICLK
SPIMOSI
SPIMISO
8 9 10
7 6 5
MSB
Byte 1 Byte 2 Byte N
value unused by peripherals
6
Figure 24: Example SPI Waveforms – Reading from FLASH Device using Mode 0© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 37
10.2 Serial Peripheral Interface Slave
The Serial Peripheral Interface (SPI) Slave Interface allows high-speed synchronous data transfer between the
JN516x and a peripheral device. The JN516x operates as a slave on the SPI bus and an external device connected
to the SPI bus operates as the master. The pins are different from the SPI master interface and are shown in the
following table.
Signal DIO Assignment
Standard pins Alternative pins
SPISCLK DIO15
SPISMISO DIO13 DIO17
SPISMOSI DIO12 DIO16
SPISSEL DIO14
Table 4: SPI Slave IO
The SPI bus employs a simple shift register data transfer scheme, with SPISSEL acting as the active low select
control. Data is clocked out of and into the active devices in a first-in, first-out fashion allowing SPI devices to
transmit and receive data simultaneously. Master-Out-Slave-In or Master-In-Slave-Out data transfer is relative to the
clock signal SPISCLK generated by the external master.
The SPI slave includes the following features:
• Full-duplex synchronous data transfer
• Slaves to external clock up to 8MHz
• Supports 8 bit transfers (MSB or LSB first configurable), with SPISSEL deselected between each transfer
• Internal FIFO up to 255 bytes for transmit and receive
• Standard SPI mode 0, data is sampled on positive clock edge
• Maskable interrupts for receive FIFO not empty, transmit FIFO empty, receive FIFO fill level above
threshold, transmit FIFO fill level below threshold, transmit FIFO overflow, receive FIFO overflow, receive
FIFO underflow, transmit FIFO underflow, receive timeout
• Programmable receive timeout period allows an interrupt to be generated to prompt the receive FIFO to
be read if no further data arrives within the timeout period38 JN-DS-JN516x v1.3 Production © NXP Laboratories UK 2013
11 Timers
11.1 Peripheral Timer/Counters
A general-purpose timer/counter unit, Timer0, is available that can be configured to operate in one of five possible
modes. This has:
• Clocked from internal system clock (16MHz)
• 5-bit prescaler, divides system clock by 2 prescale value as the clock to the timer (prescaler range is 0 to 16)
• 16-bit counter, 16-bit Rise and Fall (period) registers
• Timer: can generate interrupts off Rise and Fall counts. Can be gated by external signal
• Counter: counts number of transitions on external event signal. Can use low-high, high-low or both
transitions
• PWM/Single pulse: outputs repeating Pulse Width Modulation signal or a single pulse. Can set period and
mark-space ratio
• Capture: measures times between transitions of an applied signal
• Delta-Sigma: Return-To-Zero (RTZ) and Non-Return-to-Zero (NRZ) modes
• Timer usage of external IO can be controlled on a pin by pin basis
Four further timers are also available that support the same functionality but have no Counter or Capture mode.
These are referred to as PWM timers. Additionally, is not possible to gate these four timers with an external signal.
>= D Q
Rise
=
<
Fall
Delta Sigma
Interrupt
Generator
Counter
Interrupt Enable
Capture
Generator
Prescaler SYSCLK
TIMxCK_GT
TIMxCAP
Interrupt
PWM/∆Σ
PWM/∆Σ
PWM/∆Σ
Reset
Generator
Edge
Select
EN
EN
TIMxOut
Sw
Reset
System
Reset
Single
Shot
-1
Figure 25: Timer Unit Block Diagram© NXP Laboratories UK 2013 JN-DS-JN516x v1.3 Production 39
The clock source for the Timer0 unit is fed from the 16MHz system clock. This clock passes to a 5-bit prescaler
where a value of 0 leaves the clock unmodified and other values divide it by 2 prescale value. For example, a prescale
value of 2 applied to the 16MHz system clock source results in a timer clock of 4MHz.
The counter is optionally gated by a signal on the clock/gate input (TIM0CK_GT). If the gate function is selected,
then the counter is frozen when the clock/gate input is high.
An interrupt can be generated whenever the counter is equal to the value in either of the High or Low registers.
The following table details which DIO are used for timer0 and the PWM depending upon the configuration.
Signal DIO Assignment
Standard pins Alternative pins
TIM