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SmartRF06 Evaluation Board User`s Guide (Rev

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1. 1 6 1 1 18 3 28 173 2 3 6 24 1 http www tij co jp EVALUATION BOARD KIT MODULE EVM WARNINGS RESTRICTIONS AND DISCLAIMERS For Feasibility Evaluation Only in Laboratory Development Environments Unless otherwise indicated this EVM is not a finished electrical equipment and not intended for consumer use It
2. i i VDD SENSE JTAG Connector i P403 P405 PINROW_SMD_2X10_2 54MM P406 LV_LED_3 fo ob RF1 2 RF12 LV SDCARD CS loo RF2 12 i RF2 17 JTAG TDI i 2 RF14 T RF2 13 LV LED 4 Ky oft RF1 4 3 RFts LV LED 2 fo of RF2 4 JTAG TMS VDD_SENSE 1 5 mr24 jrAG TMS i 43 BEIS i x 4 JTAG d REG of ts RES LV aco INTZ fo of Res eae ASLO REA E m LV_BTN LEFT lo of RF1 6 eH e _RF1 10 LV BTN RESET fool RF218 RESET i te BR TAG IDe RE 1 14 i m RF2 15_RESET LV_BTN_RIGHT PSI RF1 8 Seer tia LV ACC INT1 lo oo RF2416 i Rede HAG SO ka gr RF1 13 PINROW_SMD_2X5_1 27MM g a SE T ij LV BTN UP 6 o 2 RF1 10 Saori TNROW_SMD_2X5_2 54MM REZTE RESET EE s x LV LCD MODE e e RF1 11 bo P407 i LV BIN DOWN l5 o s RF1 12 1 Re RF1 16 SEL SCK i LV LCD RESET AI RF1 13 3 RF117 bor ER Eu PINROW_SMD_2X10_2 54MM LV_BTN_SELECT So 5 RF120 SPI MISO I Rao EEN Tok krak RFz e VDD MEASURED 1 2 d zH BER 1 LV SPI SCK lo of RF1 16 SPI sck 9 RF2 10 li 1 1 i RFz 1 Com Lo i iv LCD cs foot RF1 17 P411 i LV SPI MOSI look RF1 18 SPI MOSI LG eis 8 g ho RF1 20 sPi Miso RE2 13 i lo S LV SPI MISO So SPI I
3. Ei NX e Se a w i C i 7 EE EN 3 In 5 CONNECTOR FOR go Pe eT ene 2 EXTERNAL POWER CR el i re E iH 8 H ES 5 era EE E z afe vour i EH sii 84 E Fa 2 BEI i luo 3 2 REGULATOR GES 8 AU OOP Noma Bypass SH i EZ T s L C 2U2 0402 xsR_M ePavoc JUMPER 3 3 8o t z SE 3 npo 3 LV_3 3V_EN 2 BUCK 2 1V BUCK BOOST 3 3V Fo 9 MAIN ON OFF SWITCH BATTERY or EXTERNAL o 1 9 A 2 1 3 3V veat REG REG V_UNREG USB 5V d SMD_SWITCH_DPDT POWER SELECT SWITCH v_uss POWERED from BATTERY or External Power Supply 3 3V FOR HV PERIPHERALS for enabling the High Voltage o Sub auger SEO domain for board peripherals P2 1V SB92 P3 3V oe E VM vos on ou LV_3 3V_EN Pa3vxs Paawos XDS100v3 VOLTAGE REGULATORS XDS 3 3V USB TO 3 3V g POWERED from USB XDS100v3 P3 3VXDS gt u2 TPS73533 2 1V FOR EM and LV PERIPHERALS 10 50 C 100N 0402 X5R K 10 VIN NC TPS73533 o C 100N 0402 X5R eu Test Cie 40ma USB TO 1 5V FPGA P3 3VXDS us TLV70015 Tesi 402 XSR K 10 VIN VOUT GND TLV70015 EN NC4 ESCH 4 cas C 100N 0402 X5R K 10 c32
4. P3 3VXDS P3 SVXDS P3 3VXDS ars H P33VXDS Aa P33VXDS o FS ASDM 100 000MHZ g 1 2 s 4 HR 2 os ASDM R33 og SE 1 STANDBY vog R_51_0402_6 Za vecpLE at 2 lend OUTPUT 2 CLK_100M RESET_N g RESET Ne cas cm 3 alk cw Zar 0609 XSR_K 6 C 15N 0402 X7R K 25 e i E E 3 a ojojo al 2 222 2 U11 y O 0 0 D i lek i Fb i E Ne DSOOOOO lt lt OO lt O lt 0005006000 E ZemammmOGn ao TT AIOE z REP VO 4 os OUOO0PP OPOUUOCNoO0oUOo U DS SG S SoNyvar tiy N 89999 00 0309 2208908 Si 98822 BN pnr 9989071 z 3 a a 100 VTARGET oe P Ivo oEAzotoeRsSg 862 26 OB go eee ER i CLK FAIL 2 OO oo vu o gt 28 m gt GEB210105RSBT E z zones gk SRST_OUT 28 GEC210104RSB1 GABO IOO2RSBO LI T Dis IDIS Ds RICK 2 io102RSB1 Gasinoosrsso delen TTRST EMUO 20 io100RSB1 gt Gaconoosrsso _ EXT SELECT EXT SELECT EMU EN 21 iosonse1 oO Gactnoosrsso 1 2 arg TEST 3 ioozRSB1 1007RsBo 2 1 27 T EMUZ ms 9 RET Sa 1096RSB1 n E i 5 T EMU4 Tpo R52 R 51 0402 6 IO95RSB1 msn ADv MoDE Apv_wopg Tp 9 zZ IO94RSB1 a 1 2 T rus 1018RS8 Tck 3 Rar eon odG2 F IO93RSB1 son
5. DwG High Voltage SmartRF06EB Peripherals SIZE FscMNo DWG NO REV A3 1 2 1 zeg sneer 6 7 LEDS BUTTONS ACCELEROMETER AMBIENT LIGHT SENSOR TN SELECT BMA250 S E Geng RECOMMENDED 2 3V 5 5V RED BUSH BUTTON SKHAAK Se C Hex 4 ivAS our D601 nr 2 leo a LV ALS PWR vins Dh n th cats Let 7 100N_0402 ep ku to_voo LIGHT SENSOR Ser e veo ueneno LT nam oz KE L0 0402 XS ps SEET o eut PUSH BUTTON SKRAAK LV BTN RIGHT 8 arg i Accelerometer as YELLOW Needs from 1 62V 3 6V E ad S603 d PUSH_BUTTON_SKRAAK vus psp LV SPLMISO Biz a a LV SPI MOS 7 Spx vod 7 LV ACC PWR LED ELIG2IUYC A2 lt v R680 0402 G LV ACC GS less BMA250 Vnd R608 tt ps AXIS INT 5 LV ACC INT1 S604 Lv sPi Sch 2 5c Accelerometer wa 3 LV ACC INT2 emm x ACC INT2 m PUSH_BUTTON_SKRAAK Cr chine IEND un Lv ACC PWR GEN 2 EE PWR GREEN Se D603 C612 Dents 605 Sege 100N_0402 X5R_K 10 mE T PUSH BUTTON SKRAAK ur LED ELI2ISYGC nam twee R609 e RED ORANGE D604 LV LED 4 m LED ELIB2ISURC Z R 680 0402 G R610 CONTRACT NO COMPANY NAME Texas Instruments APPROVALS DATE DWG Low Voltage MAW SmartRFOGEB Peripherals DRAWN 1210712 SIZE FSCMNO DWG NO REV CHECKED 130712 A3 1 2 1 ISSUED
6. Figure 16 SmartRFO6EB I O breakout overview 6 11 4 1 0 Breakout Headers The I O breakout headers on SmartRFO6EB consist of pin connectors P406 P407 P411 and P412 P406 P407 and P411 are located at the top left side of SmartRFOGEB All EM signals available on these probe headers can be connected to or disconnected from SmartRFO6EB peripherals using jumpers on headers P403 P404 P405 Probe header P412 is located near the bottom right corner of the SmartRFOGEB The signals available on P412 are connected to the XDS100v3 Emulator s UART back channel using jumpers on header P408 The I O breakout mapping between the SmartRF06EB and the mounted EM is given in Table 14 The leftmost column in the below table refers to the silk print seen on the SmartRFO6EB The rightmost column shows the corresponding CC2538 I O pad on CC2538EM Page 23 32 IA TEXAS INSTRUMENTS Probe header Silk print EB signal name EM connector User s Guide SWRU321A May 2013 CC2538EM yo P406 RF1 LV LED 3 RF1 PC2 RF1 LV LED 4 RF1 4 PC3 RF1 NC RF1 5 PB1 RF1 LV BTN LEFT RF1 6 PC4 RF1 LV_BTN_RIGHT RF1 8 PC5 RF1 LV BTN UP RF1 10 PC6 RF1 LV_LCD_MODE RF1 11 PB2 RF1 LV BTN DOWN RF1 12 PC7 RF1 LV LCD RESET RF1 13 PB3 RF1 RF1 15 LV BTN SELECT LV 3 3V EN RF
7. 6 2 3 External Power Supply The SmartRFO6EB can be powered using an external power supply To power the mounted EM and the EB peripherals using an external power supply the power source selection switch S502 should be in BAT position Figure 10 in section 6 2 2 The external supply s ground should be connected to the SmartRFOGEB ground e g to the ground pad in the top left corner of the EB Connect the positive supply connector to the external power header J501 Figure 11 The applied voltage must be in the range from 2 1 V to 3 6 V and limited to max 1 5 A When powered by an external power supply the EM power domain is by default regulated to 2 1 V The voltage regulator may be bypassed by mounting a jumper on J502 See section 6 3 2 for more details There is a risk of damaging the onboard components if the applied voltage on the external power connector header is lower than 0 3 V or higher than 3 6 V combined absolute maximum ratings for onboard components See section 5 1 for further information MAX 3 BV Figure 11 SmartRF06EB external power supply header J501 Page 16 32 IA TEXAS INSTRUMENTS User s Guide SWRU321A May 2013 6 3 Power Domains The SmartRFOGEB is divided into three power domains described in detail in the following sections The SmartRFO6EB components and what power domain they belong to is shown in Figure 12 and Table 5 below Mounted EM XDS domain T EM doma
8. CONTRACT NO COMPANY NAME Texas Instruments APPROVALS DATE DWG SmartRFOGEB Power Supply Drawn Miro sizE FSCMNO DWG No REV CHECKED 130712 A3 1 2 1 ISSUED mem scale sHeet 5 7 MICROSD LEVEL SHIFTERS zL HH R606 zL HH R 0 0603 R614 LH R_0_0603 R615 R_0_0603 HL voD J601 MICROSD sPI NA ER HV SDCARD CS wa Fn mosi HV SPLMOSI em mS vof S scu HV SPI SCK GNI ZS pomiso HV SPI MISO ER NA HLVDD cens L C 100N 0402 X5R K 10 uU LCD lt D 2 3 GN 4 g sg mm HV SPI MOSI E seg num HV SPI SCK 2 g wey T HV LCD MODE m MM F HV_LCD_RESET ai HV rep cs ali EC ceos ceoe csor csos Team a ce 9 ce m e Ba 5 E 2 8582 Ss SS SS 3 5S 3 304 L CE 2 P2 E e z e S g HI VDD HI VDD SIP SOCKET SMD 1X20 24MM LCD d i Wi e i e g g el e J INSERT y 1 pe SIP_SOCKET_SMD_1X20_2 54MM o NE NE NE 2 Lo o 2peSIP_SOCKET_SMD_1X3_2 54MM id 8 8 8 8 amp 3 Los L es 2 amp ii DOGM128W 6 NO CON 88 zo Ze 3 Si 8 8 2 23 2379 i
9. The PC tools SmartRF Studio and SmartRF M Flash Programmer have their own user manual See chapter 9 for references to relevant documents and web pages Page 5 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 3 Acronyms and Abbreviations ALS cJTAG CW DK EB EM FPGA UO JTAG LCD LED LPRF MCU MISO MOSI NA NC RF RTS RX SoC SPI Tl TP TX UART USB VCP Ambient Light Sensor Compact JTAG IEEE 1149 7 Continuous Wave Development Kit Evaluation Board Evaluation Module Field Programmable Gate Array Input Output Joint Test Action Group IEEE 1149 1 Liquid Crystal Display Light Emitting Diode Low Power RF Micro Controller Master In Slave Out SPI signal Master Out Slave In SPI signal Not Applicable Not Available Not Connected Radio Frequency Request to Send Receive System on Chip Serial Peripheral Interface Texas Instruments Test Point Transmit Universal Asynchronous Receive Transmit Universal Serial Bus Virtual COM Port Page 6 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 4 Getting Started Before connecting the SmartRFO6EB to the PC via the USB cable it is highly recommended to perform the steps described below 4 1 Installing SmartRF Studio and USB drivers Before your PC can communicate with the SmartRFO6EB over USB you will need to install the USB drivers for the EB The latest SmartRF Studio installer 1 includes USB drivers b
10. The TI XDS100v3 USB VID is 0x0403 and the PID is OxA6D1 but if you wish to find the PID using a terminal window shell use lsusb grep i future b Install driver using modprobe In a terminal window shell navigate to the ftdi siofolder and run gt sudo modprobe ftdi sio vendor 0x403 product 0xA6D1 Bom SmartRFOGEB should now be correctly mounted The above steps have been tested on Fedora and Ubuntu distributions If the above steps failed try uninstalling brltty prior to step 5 technical note TN 101 2 gt sudo apt get remove brltty Page 9 32 A TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 5 Using the SmartRF06 Evaluation Board The SmartRFOGEB is a flexible test and development platform that works together with RF Evaluation Modules from Texas Instruments An Evaluation Module EM is a small RF module with RF chip balun matching filter SMA antenna connector and I O connectors The modules can be plugged into the SmartRFOGEB which lets the PC take direct control of the RF device on the EM over the USB interface SmartRFO6EB currently supports CC2538bEM SmartRFO6EB is included in e g the CC2538 development kit Figure 3 SmartRFOGEB rev 1 2 1 with EM connected The PC software that controls the SmartRF06EB EM is SmartRF Studio Studio can be used to perform several RF tests and measurements e g to set up a CW signal and send receive packets Page 10 32 IA TEXAS User s Guide
11. P411 6 Table 9 Ambient Light Sensor signal connections 6 8 Buttons There are 6 buttons on the SmartRFO6EB Status of the LEFT RIGHT UP DOWN and SELECT buttons are available to the mounted EM These buttons are intended for user interfacing and development of demo applications The EM RESET button resets the mounted EM by pulling its reset line low RFZ 15 RESET Table 10 shows an overview of I O signals related to the buttons Signal name Description Probe header LV BTN LEFT Left button active low RF1 6 P406 4 LV BTN RIGHT Right button active low RF1 8 P406 5 LV BTN UP Up button active low RF1 10 P406 6 LV BTN DOWN Down button active low RF1 12 P406 8 LV_BTN_SELECT Select button active low RF 1 14 P406 10 LV BTN RESET EM reset button active low RFZ 15 RESET P411 4 Table 10 Button signal connections Page 20 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 6 9 LEDs 6 9 1 General Purpose LEDs The four LEDs D601 D602 D603 D604 can be controlled from the mounted EM and are suitable for demo use and debugging The LEDs are active high Table 11 shows an overview of I O signals related to the LEDs Signal name Description Probe header LV LED 1 LED 1 red RF2 11 P407 10 LV LED 2 LED 2 yellow RF2 13 P411 2 LV LED 3 LED 3 green RF1 2 P406 1 LV LED 4 LED 4 red orange RF1 4 P406 2 Table 11 General purpo
12. Probe header RF2 8 P407 8 RF2 16 P411 5 RF2 14 P411 3 RF2 10 P407 9 RF1 16 SCK P407 2 RF1 18 MOSI P407 4 Signal name LV ACC PWR LV ACC INT1 Description Acc power enable signal Acc interrupt signal Acc interrupt signal Acc Chip Select active low SPI Clock SPI MOSI acc input LV ACC INT2 LV ACC CS LV SPI SCK LV SPI MOSI The LCD and SD card are both powered in the 3 3 V domain and cannot be powered on off individually Page 19 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 SPI MISO acc output RF1 20_MISO P407 5 Table 8 Accelerometer signal connections 6 7 Ambient Light Sensor The SmartRFO6EB has an analog SFH 5711 ambient light sensor ALS from Osram 7 that is available for the mounted EM via the EM connectors enabling quick application development for demo use and prototyping Figure 14 and Table 9 shows an overview of I O signals related to the ambient light sensor The recommended operating condition for the ambient light sensor is a supply voltage between 2 3 V and 5 5 V The min max operating temperature is 40 85 C M LV ALS PWR Ambient Light Sensor Ee LV_ALS OUT H woz Figure 14 Simplified schematic of Ambient Light Sensor setup Signal name Description Probe header LV_ALS_PWR ALS power enable signal RF2 6 P407 7 LV_ALS_OUT ALS output signal analog RF2 5
13. d 1 S S S ood o o d pana 7 7 s 5 x8 B P3 x M x DEEN sm soorer sub n 2 sa LO VDD Hi VDD cs T oe C 100N 0402 XSR K 10 C 100N 0402 XSR K 10 ER num i S U401 SN74AVC4T245 i 1 1 i veca cm nn VOCE LV ssV EN SR Beer i LV SPI SCK 1 4 4 1B1 LS HV SPI SCK i LV SPI MOSI S 1a2 182 HV SPL MOSI LV SPLMISO 7 oA 281 T HV SPI MISO 222 282 cime mic E LO VDD nm i LO VDD LO VDDLO VDD car 1 T os C 100N 0402 XSR K 10 TE C 100N 0402 XsR_K 10 sss RSS i Ss g 35 g H Lovo Hi vob i ETT U402 i dw tp SN74AVCAT245 E i x je e een vocs 2 15 LV 33V EN CT eai 10E a LV_3 3V_EN 2DIR 20E i LV LCD RESET 4 1Aq 181 HV LCD RESET LV LCD CS Sin 182 HV LeD cs LV_L D_MODE coe 281 HV LCD MODE i LV SDCARD CS 7 A2 282 2 EV SDCARD CS GND GN LEVEL SHIFTERS TRANSLATION To_Vpp U401 U402 i i Lo Hi Lo m a 1A1 gt 1B1 1A1 gt 1B1 1A2 gt 1B2 1A2 gt 182 Y 2A1 lt 2B1 2A1 gt 2B1 as 2A2 lt 2B2 2A2 gt 2B2 i Ec i HV SPL SCK pu j Tesipsint_crcle_40mis i 2N7002F HV_SPI_MOSI i TP15 Testpsint_crcle_40mis HV_SPI_MISO TP16 aie i Testpsint_Cicle_40mis CONTRACT NO APPROVALS DATE MAW DRAWN 1210712 CHECKED 13 7 12 ISSUED 13 07 12 COMPANY NAME Texas Instruments
14. 1 8 3 6 0 3 3 75 Component LCD 5 3 0 3 3 0 3 3 6 Accelerometer 6 1 62 3 6 0 3 4 25 Ambient light sensor 7 212 45 5 NA 6 Table 2 Supply voltage Recommended operating conditions and absolute max ratings Operating temperature Storage temperature Min C Max C Min C Max C XDS100v3 Emulator 4 20 70 50 110 LCD 5 70 30 80 Accelerometer 6 85 50 150 Ambient light sensor 7 85 40 85 Component Table 3 Temperature Recommended operating conditions and storage temperatures 1 The XDS100v3 Emulator is USB powered Values refer to the supply and I O pin voltages of the connected target Recommended minimum operating voltage Page 11 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 6 SmartRFO06 Evaluation Board Overview SmartRFOGEB acts as the motherboard in development kits for ARM Cortex based Low Power RF SoCs from Texas Instruments The board has several user interfaces and connections to external interfaces allowing fast prototyping and testing of both software and hardware An overview of the SmartRFOGEB architecture is found in Figure 4 The board layout is found in Figure 5 and Figure 6 while the schematics are located in Appendix A This chapter will give an overview of the general architecture of the board and describe the available 1 0 The following sub sections will explain the I O in mo
15. 6 LCD signal connechons sise 19 Table 7 Micro SD Card signal connections neret 19 Table 8 Accelerometer signal Connechons ene 20 Table 9 Ambient Light Sensor signal connections 20 Table 10 Button signal connections su 20 Table 11 General purpose LED signal connections ss 21 Table 12 EM connector RF1 Gin out nennen nnne nnne 22 Table 13 EM connector RF2 poin out nennen enne enne 22 Table 14 SmartRF06EB I O breakout overview uate 24 Table 15 20 pin ARM JTAG header pin out P409 uu 25 Table 16 10 pin ARM Cortex Debug header pin out P410 26 Table 17 Debugging external target Minimum strapping CJTAG support 30 Table 18 Debugging external target Optional strappind lt 30 Page 4 32 IA TEXAS INSTRUMENTS 1 Introduction User s Guide SWRU321A May 2013 The SmartRF06 Evaluation Board SmartRFOGEB or simply EB is the motherboard in development kits for Low Power RF ARM Cortex M based System on Chips from Texas Instruments The board has a wide range of features listed in Table 1 below Component Description TI XDS100v3 Emulator cJTAG and JTAG emulator for easy programming and debugging of SoCs on Evaluation Modules or external targets High speed USB 2 0 interface Easy plug and play
16. 6 P403 11 12 RF1 11 GPIO signal to EM board P406 7 P403 13 14 RF1 12 GPIO signal to EM board P406 8 P403 15 16 RF1 13 GPIO signal to EM board P406 9 P403 17 18 RF1 14 GPIO signal to EM board P406 10 P403 19 20 RF1 15 GPIO signal to EM board P407 1 P404 1 2 RF1 16 SPI SCK EM SPI Clock P407 2 P404 3 4 RF1 17 GPIO signal to EM board P407 3 P404 5 6 RF1 18 SPI MOSI EM SPI MOSI P407 4 P404 7 8 GND Ground RF1 20 SPI MISO Signal name EM SPI MISO Table 12 EM connector RF1 pin out Description P407 5 P404 9 10 Probe Breakout header header RF2 1 JTAG TCK JTAG Test Clock P409 9 P408 1 2 GND Ground RF VDD2 EM power TP10 J503 1 2 RF2 4 JTAG TMS JTAG Test Mode Select P409 7 P408 3 4 RF2 5 GPIO signal to EM board P407 6 P404 11 12 RF2 6 GPIO signal to EM board P407 7 P404 13 14 RF VDD1 EM power TP10 J503 1 2 RF2 8 GPIO signal to EM board P407 8 P404 15 16 RF VDD1 EM power TP10 J503 1 2 RF2 10 GPIO signal to EM board P407 9 P404 17 18 RF2 11 GPIO signal to EM board P407 10 P404 19 20 RF2 12 GPIO signal to EM board P411 1 P405 1 2 RF2 13 GPIO signal to EM board P411 2 P405 3 4 RF2 14 GPIO signal to EM board P411 3 P405 5 6 HF2 15 HESET EM reset signal active low P411 4 P
17. M 3 REZ 14 i de LV ALS OUT bo RF2 5 RES RESET i o Hs RF2 16 i z i H LV_ALS_PWR bot RF2 6 a SEN H Optional i i LV ACC PWR 5 ol RF2 8 pate Ea RC filter IV ACC CS he RF2 10 1 T EM CURRENT MEASUREMENT bo e 12 RELZ UART RX i LV LED 1 8 og RF2 11 RAS RF UART TX i i o LH REt3 UART CTS i i Cen SH 5 REZ18 UART RTS PINROW sun 2x10 25aMM L ss eee lt Lo vo i Toapoint Cree Abi i ka i i R502 i R_OR15 0603 F i i J503 VDD_SENSE VDD_MEASURED i i e Be L 7 BNROW SM0 12 2544 e s i e i E ed M hp sl S 4 zE 7 d d E 7 E E i A i d EK H 1 z3 zz 5 L 3 Es ERE am h o o i n H M E od o Ten 720 RESET cunmens_oureur festens Presten suau Rehunt 0 15 Ohm ale Gain 100 seoe i PUSH_BUTTON_SKRAAK Vin lshunt x Rahunt E Vout Vin x Gain iP t a Saturation point for INA216 LV BTN RESET w m Vout_max LO_VDD 2 1V to 3 6V Vin_max LO_VDD 100 21mV to 36mV i Ishunt max 140mA to 240mA CONTRACT NO COMPANY NAME Texas Instruments APPROVALS DATE DWG EM Interface be SmartRFOGEB Level Shifters DRAWN 320702 size FSCMNO DWG No REV CHECKED 130712 A3 1 2 1 ISSUED mem scale sHeet 4 7 BATTERIES BATTERY REGULATORS
18. P3 3VXDS RT L BEAD 102 0402 qe 1 1 C20 C 100N de X5R K 10 P3 3VXDS cue SE Gar 060b X5R_K le R8 NH L BEAD 102 0402 Ee par P3 avxos 1 1 CT c Zu de XR 10 Ga seh em d P3 3VXD83 3VXDSP1 8V LL Lou zl EI u4 Ez 58 8999 Frees 8 9 9 S 55 veus GES ds TPD2E001 vacan TE ERO Tck vrecour dee Too vec 102 ADBUS TMS i ag ADBUS3 P1 nc TPD2E001 an ADBUSA TRST USB B MICRO 3 Je S 3 ADBusd 2 EMU EN vVBuS 1 Fe ADBUse 2 EM ADBUS7 2 RTCK ol 2 sl USBDW pw Ges USBDP pp BEES WE SRST_OUT 2 cane RE CLK FAIL D d REF ACBUs2 TVD GND gia RESET AcBUs3 POD_RLS Shield ER AcBUSS BL Dis EI Acus 5 DTSA BYP E ALT FUNG ACBUS7 EEPROM CS mecs EEPROM_CLK EECLK 3 PRG TCK temone ine FT2232H asus HRA PRG TDI P3 3VXDS joan BDBUS2 PRG TDO Wee PRG TMS P3 3VXD83 3VXIRB 3VXDS 3 losco BDBUS4 H PRG_TRST v UsB BDBUSSL mm anm Yi D 45 SS a X_12 000 80 3d 10 20 TEST piers EE s s S DIS BDBUS7 RM 93AA46B g e i i w JE Ry Po 8 2 DE BcBUsoQ as po vec 4 metes 2 4 z BCBUs1 2 Pe GND 93AA46B CS 5 EEPROM_CS wa L oars eee BcBUSa DIN cik 4 ___ EEPROM cu 3 3 BcBusa hi a BCBUS4 P33VXDS 5 S BCBUSS S N LEo_ELte 21sYec EEPROM_DATA 9 9 e pe BCBUS6 2 Bcaus7l 1 ce CRE gt 100N 0402 X5R K 10 PWREN 9 PWREN LR SUSPEND 5 SUSPEND a 2 9990000 m 2222222 S lt 0000000 ho EE fe fs fs fs fer fs CONTRACT NO COMPANY NAME Texa
19. access to full SoC control using SmartRF Studio PC software Integrated serial port over USB enables communication between the SoC via the UART back channel 64x128 pixels serial LCD Big LCD display for demo use and user interface development LEDs Four general purpose LEDs for demo use or debugging Micro SD card slot External flash for extra storage over the air upgrades and more Buttons Five push buttons for demo use and user interfacing Accelerometer Three axis highly configurable digital accelerometer for application development and demo use Light Sensor Ambient Light Sensor for application development and demo use Current measurement Current sense amplifier for high side current measurements Breakout pins Easy access to SoC GPIO pins for quick and easy debugging Table 1 SmartRFOGEB features 2 About this manual This manual contains reference information about the SmartRFOGEB Chapter 4 will give a quick introduction on how to get started with the SmartRFOGEB It describes how to install SmartRF Studio to get the required USB drivers for the evaluation board Chapter 5 briefly explains how the EB can be used throughout a project s development cycle Chapter 6 gives an overview of the various features and functionality provided by the board A troubleshooting guide is found in chapter 8 and Appendix A contains the schematics for SmartRFOGEB revision 1 2 1
20. 0v3 Emulator onboard the SmartRFOGEB Pin User s Guide SWRU321A May 2013 20 pin ARM JTAG Connector AMANAN MA mmo W M a CR He HB CE EE SE a WN WU B UU Figure 18 20 pin ARM JTAG header P409 Signal Description EB signal name XDS bypass header P409 1 VTRef Voltage reference VDD_SENSE P408 19 20 P409 2 VSupply Voltage supply NC P409 3 nTRST Test Reset NC P409 4 GND Ground GND P409 5 TDI Test Data In RF2 17_JTAG_TDI P409 6 GND Ground GND P409 7 TMS Test Mode Select RF2 4 JTAG TMS P409 8 GND Ground GND P409 9 TCK Test Clock RF2 1 JTAG TCK P409 10 GND Ground GND P409 11 RTCK Return Clock NC P409 12 GND Ground GND P409 13 TDO Test Data Out RF2 19 JTAG TDO P408 7 8 P409 14 GND Ground GND P409 15 nSRST System Reset HF2 15 RESET P408 9 10 P409 16 GND Ground GND P409 17 DBGRQ Debug Request NC P409 18 GND Ground GND P409 19 DBGACK Debug Acknowledge NC P409 20 GND Ground GND Table 15 20 pin ARM JTAG header pin out P409 Page 25 32 IA TEXAS INSTRUMENTS 6 11 4 User s Guide SWRU321A May 2013 10 pin ARM Cortex Debug Header The SmartRFO6EB comes with a standard 10 pin ARM Co
21. 1 14 PA3 RF1 16_SCK LV_SPI_SCK RF1 17 LV LCD CS RF1 18 MOSI LV SPI MOSI RF1 20 MISO LV SPI MISO RF2 5 LV ALS OUT RF2 6 LV ALS PWR RF2 8 LV_ACC_PWR RF2 10 LV ACC CS RF2 11 RF2 12 LV LED 1 LV SDCAHD CS PDO RF2 13 LV LED 2 PC1 RF2 14 LV_ACC_INT2 PD1 RF2 15 RESET LV BIN RESET nRESET RF2 16 EM_UART_RX LV_ACC_INT1 RF1 7 UART HA PD2 EM UART TX RF1 9 UART TX EM UART CTS RF1 3 UART CTS EM UART RTS Table 14 SmartRFOGEB I O breakout overview RF2 18 UART RTS 6 11 2 XDS100v3 Emulator Bypass Headers The XDS100v3 Emulator bypass header P408 is by default mounted with jumpers Figure 17 connecting the XDS100v3 Emulator to a mounted EM or external target By removing the jumpers on P408 the XDS100v3 Emulator may be disconnected from the target XDSI 8v3 BYPASS AA MOm n AAN N IO wu ju L 8 D In qn soie da de de ofe fa a e f s B E Le LL HU WU Figure 17 XDS100v3 Emulator Bypass Header P408 Page 24 32 IA TEXAS INSTRUMENTS 6 11 3 20 pin ARM JTAG Header The SmartRFO6EB comes with a standard 20 pin ARM JTAG header 8 Figure 18 enabling the user to debug an external target using the XDS100v3 Emulator The pin out of the ARM JTAG header is given in Table 15 Chapter 7 has more information on how to debug an external target using the XDS10
22. 405 7 8 RF2 16 GPIO signal to EM board P411 5 P405 9 10 RF2 17 JTAG TDI GPIO JTAG Test Data In P409 5 P408 5 6 RF2 18 UART RTS GPIO UART Back Channel P412 5 P408 17 18 RF2 19 JTAG TDO GPIO JTAG Test Data Out P409 13 P408 7 8 GND Ground Page 22 32 Table 13 EM connector RF2 pin out IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 6 11 Breakout Headers and Jumpers The SmartRFOGEB has several breakout headers giving access to all EM connector pins An overview of the SmartRFO6EB UO breakout headers is given in Figure 16 Probe headers P406 P407 P411 and P412 give access to the I O signals of the mounted EM Breakout headers P403 P404 and P405 allow the user to map any EM UO signal to any peripheral on the SmartRFO6EB The XDS bypass header P408 makes it possible to disconnect the XDS100v3 Emulator onboard the EB from the EM Using the 20 pin ARM JTAG header P409 or the 10 pin ARM Cortex Debug Header P410 it is possible to debug external targets using the onboard emulator Evaluation Module Peripheral 20 pin probe headers ARMJTAG P406 P407 Debug Header P411 P409 IO breakout headers XDS bypass header P408 P404 P405 P408 10 pin Cortex Debug Header P410 SmartRFO6EB UART back peripherals XDS100v3 channel probe ACC ALS keys LCD Emulator header LED SD card P412
23. 7 Figure 13 Mount a jumper on J502 to bypass EM domain voltage regulator 18 Figure 14 Simplified schematic of Ambient Light Sensor setup 20 Figure 15 SmartRF06EB EM connectors RF1 and RF2 sss 21 Page 3 32 13 TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 Figure 16 SmartRFO6EB I O breakout overview 23 Figure 17 XDS100v3 Emulator Bypass Header P408 sse 24 Figure 18 20 pin ARM JTAG header P409 us 25 Figure 19 10 pin ARM Cortex Debug header PDA10 26 Figure 20 Simplified schematic of high side current sensing Setup sess 27 Figure 21 Measuring current consumption using jumper J503 ssssssessssssssrssserrssrsrrssrrrrssrrrnsss 27 Figure 22 Simplified connection diagram for different debugging scenarios 28 Figure 23 Debugging external target using SmartRFOGEB 29 Figure 24 ARM JTAG header P409 with strapping to debug external target 30 List of Tables Table 1 SmartRFO6EB features sisi 5 Table 2 Supply voltage Recommended operating conditions and absolute max ratings 11 Table 3 Temperature Recommended operating conditions and storage temperatures 11 Table 4 UART Back channel signal connections sese 14 Table 5 Power domain overview of SmartRFO6EB eene 17 Table
24. Any use of radio frequencies and or power availability of this EVM and its development application s must comply with local laws governing radio spectrum allocation and power limits for this evaluation module It is the user s sole responsibility to only operate this radio in legally acceptable frequency space and within legally mandated power limitations Any exceptions to this are strictly prohibited and unauthorized by Texas Instruments unless user has obtained appropriate experimental development licenses from local regulatory authorities which is responsibility of user including its acceptable authorization For EVMs annotated as FCC FEDERAL COMMUNICATIONS COMMISSION Part 15 Compliant Caution This device complies with part 15 of the FCC Rules Operation is subject to the following two conditions 1 This device may not cause harmful interference and 2 this device must accept any interference received including interference that may cause undesired operation Changes or modifications not expressly approved by the party responsible for compliance could void the user s authority to operate the equipment FCC Interference Statement for Class A EVM devices This equipment has been tested and found to comply with the limits for a Class A digital device pursuant to part 15 of the FCC Rules These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment This eq
25. Buyer represents and agrees that it has all the necessary expertise to create and implement safeguards which anticipate dangerous consequences of failures monitor failures and their consequences lessen the likelihood of failures that might cause harm and take appropriate remedial actions Buyer will fully indemnify TI and its representatives against any damages arising out of the use of any TI components in safety critical applications In some cases TI components may be promoted specifically to facilitate safety related applications With such components TI s goal is to help enable customers to design and create their own end product solutions that meet applicable functional safety standards and requirements Nonetheless such components are subject to these terms No TI components are authorized for use in FDA Class III or similar life critical medical equipment unless authorized officers of the parties have executed a special agreement specifically governing such use Only those TI components which TI has specifically designated as military grade or enhanced plastic are designed and intended for use in military aerospace applications or environments Buyer acknowledges and agrees that any military or aerospace use of TI components which have not been so designated is solely at the Buyer s risk and that Buyer is solely responsible for compliance with all legal and regulatory requirements in connection with such use TI has specifically design
26. EMUS ont eNp_ aer ek a FEU UBD4E 002 T_TVD fior 104 T RTCK 2 Np TPD4E002 io2 ios 4 T0 e UPDAE002 LICK ot 104 LEM 2 eNp TPD4E002 San EMUO ida TsrsT The XDS100 is connected to the EM through connector P408 See the EM interface page for details PWRGOOD P33VXDS P33VXDS Em m d 3 inf xS i gs Testpoiibstimiet timis 40mils se a e vuss ition pue ez PS 3 ou SS 9 kd BC846 at DN R27 x bo etre vs 10 R Ko 0402 F g P 2 9 1 2 2 gA 5 1 INA us oute co Sa 5 of Amar OPA2363 ms 3 8 te s ijv INB 7 P Ze HIE Hena ene e 3 EN bp es ij 1 Ts g Sg dre s S Ze ei Al Trvp 3 M 3 R24 R_5K1_0402 J 1 2 R_120K_0402F 2 R25 cat C 100N 0402 XSR K 10 CONTRACT NO APPROVALS DATE MAW DRAWN 1210712 CHECKED 1307 12 ISSUED 13 0712 COMPANY NAME Texas Instruments DWG SmartRFOGEB XDS100v3 FPGA Sze rscwNo DWGNO REV A3 1 2 1 scale sueer 2 7 SH E wl E zi el E e x e E E e ig 78 E E g 18 E g 18 ES 18 18 E d d E d d d E d d d d 2 g s Ej s LS g 2 s LS S s TS 3 3 3 i 7373 3 T TS D 703 8 5 8 8 3 8 8 8 3 SES 85 8 si 3 S wi S ea chu So 2k 3 3 i
27. IA TEXAS SWRU321 e peer INSTRUMENTS SmartRF06 Evaluation Board User s Guide SmartRF is a trademark of Texas Instruments IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 Table of Contents 4 1 INSTALLING SMARTRF STUDIO AND USB DRIVERS sense 7 4 1 1 SmanHF StUdio x oa coi un RO Ibm ees 7 4 1 2 FIDERUSB OVER sme ia ees E Stave NE A ese MON I nee 7 5 1 ABSOLUTE MAXIMUM RATINGS issus sesreeeeeussscereceeceeauaeeeereceneeuauaeececeecenneaneseee 11 6 1 XDST1OOVS EMUEATOR RNNK lt 4 Ek se cba eaa Diane fes i 13 6 1 1 DART back CHANNEL SE LES Rte eR es RS Raa eis 14 6 2 POWER SOURGES sene ves va wei De ree vL E NEE EEN 14 6 2 1 SO 75 622 ag7 6 WO 75 62 3 External Power SDO 16 6 3 POWER DOMAINS iene cM 17 6 3 1 D DS DOMAIN ERR 17 6 3 2 EM Domain i ei tein E be hones boca todas etas bes dise enge one iod 17 6 3 3 3 9 V DO 18 6 4 Hol ccu 18 6 5 MIGRO SD CARD SLOT ease ENEE eoa e di Pen vg Leve D goma 19 6 6 AGGCEEEROMETER cT 19 6 7 AMBIENT EIGHT SENSOR 3 5 a ctae ch pre nha v aka Pn vun rd qve Pa A LO rA LX EA GT dn FA Qoa Nk 20 6 8 B TTONS An eege e Eege ebe 20 6 9 ED RM 21 6 9 1 General Purpose LEDS etate bm nan anre dan dts 21 69 2 XDST00vS Emulator TEE 21 6 10 EM GONNECTORS SS i teres res th tveee EE 21 6 11 BREAKOUT HEADERS AND JUMPERS 2 ee r aea aa aE aE rn E Ea Eaa A AE aa 23 6 11 1 VO Breakout Headers dc EE AE ee 23 6 11 2 XDS100v3 Emulator Bypass Headers
28. INSTRUMENTS SWRU321A May 2013 The EB EM can be of great help during the whole development cycle for a new RF product Perform comparative studies Compare results obtained with EB EM with results from your own system Perform basic functional tests of your own hardware by connecting the radio on your board to SmartRF06EB SmartRF Studio can be used to exercise the radio Verify your own software with known good RF hardware by simply connecting your own microcontroller to an EM via the EB Test the send function by transmitting packets from your SW and receive with another board using SmartRF Studio Then transmit using SmartRF Studio and receive with your own software Develop code for your SoC and use the SmartRFO6EB as a standalone board without PC tools The SmartRFOGEB can also be used as a debugger interface to the SoCs from IAR Embedded workbench for ARM or Code Composer Studio from Texas Instruments For details on how to use the SmartRFOGEB to debug external targets see chapter 7 5 1 Absolute Maximum Ratings The minimum and maximum operating supply voltages and absolute maximum ratings for the active components onboard the SmartRFOGEB are summarized in Table 2 Table 3 lists the recommended operating temperature and storage temperature ratings Please refer to the respective component s datasheet for further details Operating voltage Absolute max rating Min V Max V Min V Max V XDS100v3 Emulator 4
29. LPT DI Processors S mo Sg 7 Include subfolders Update Driver Software Disable Uninstall Let me pick from a list of device drivers on my computer This list will show installed driver software compatible with the device and all driver software in the same category as the device Scan for hardware changes Launches the Update Driver Software Wizard for th a b Figure 1 Driver install a Update driver b Specify path to FTDI drivers Press Next and wait for the driver to be installed The selected device should now appear in the Device Manager as Tl XDS100v3 Channel x x A or B as seen in Figure 2b Repeat the above steps for the second Texas Instruments XDS100v3 listed under Other devices 4 1 2 1 1 Enable XDS100v3 UART back channel on Windows If you have both TI XDS100v3 Channel A and TI XDS100v3 Channel B listed under Universal Serial Bus Controllers you can proceed Right click on TI XDS100v3 Channel B and select Properties Under the Advanced tab make sure Load VCP is checked as shown in Figure 2a A USB Serial Port may be listed under Other devices as seen in Figure 1a Follow the same steps as for the Texas Instruments XDS100v3 devices to install the VCP driver When the drivers from Studio install dir gt Drivers ftdi is properly installed you should see the USB Serial Port device be listed under Ports COM amp LPT as shown in F
30. am for different debugging scenarios Page 28 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 7 1 20 pin ARM JTAG Header The SmartRF06EB has a standard 20 pin ARM JTAG header mounted on the right hand side P409 Make sure all the jumpers on the XDS bypass header P408 are mounted and that the jumper is removed from header J503 Connect the external board to the 20 pin ARM JTAG header P409 using a 20 pin flat cable as seen in Figure 23 Make sure pin 1 on P409 matches pin 1 on the external target See sections 6 11 3 and 6 11 2 for more info about the 20 pin ARM JTAG header and the XDS bypass header respectively Figure 23 Debugging external target using SmartRFO6EB 7 2 10 pin ARM Cortex Debug Header The SmartRFOGEB has a standard 10 pin ARM Cortex Debug header mounted on the right hand side P410 Make sure all the jumpers on the XDS bypass header P408 are mounted and that the jumper is removed from header J503 Connect the external board to the 10 pin ARM JTAG header using a 10 pin flat cable Make sure pin 1 on P410 matches pin 1 on the external target See sections 6 11 4 and 6 11 2 for more info about the 10 pin ARM Cortex Debug header and the XDS bypass header respectively Page 29 32 JA TEXAS INSTRUMENTS 7 3 Custom Strapping If the external board does not have a 20 pin ARM JTAG connector nor a 10 pin ARM Cortex connector the needed signals may be strapped from the onboard XDS100v3 Emulator t
31. ated certain components as meeting ISO TS16949 requirements mainly for automotive use In any case of use of non designated products TI will not be responsible for any failure to meet ISO TS16949 Products Applications Audio www ti com audio Automotive and Transportation www ti com automotive Amplifiers amplifier ti com Communications and Telecom www ti com communications Data Converters DLP Products DSP Clocks and Timers Interface Logic Power Mgmt Microcontrollers RFID OMAP Applications Processors Wireless Connectivity dataconverter ti com www dlp com www ti com clocks interface ti com logic ti com microcontroller ti com www ti rfid com www ti com omap Computers and Peripherals Consumer Electronics Energy and Lighting Industrial Medical Security Space Avionics and Defense Video and Imaging TI E2E Community www ti com wirelessconnectivity www ti com computers www ti com consumer apps www ti com energy www ti com industrial www ti com medical www ti com security www ti com space avionics defense www ti com video Mailing Address Texas Instruments Post Office Box 655303 Dallas Texas 75265 Copyright 2013 Texas Instruments Incorporated
32. chaque type d antenne Les types d antenne non inclus dans cette liste ou dont le gain est sup rieur au gain maximal indiqu sont strictement interdits pour l exploitation de l metteur Important Notice for Users of this Product in Japan This development kit is NOT certified as Confirming to Technical Regulations of Radio Law of Japan If you use this product in Japan you are required by Radio Law of Japan to follow the instructions below with respect to this product 1 Use this product in a shielded room or any other test facility as defined in the notification 173 issued by Ministry of Internal Affairs and Communications on March 28 2006 based on Sub section 1 1 of Article 6 of the Ministry s Rule for Enforcement of Radio Law of Japan 2 Use this product only after you obtained the license of Test Radio Station as provided in Radio Law of Japan with respect to this product or 3 Use of this product only after you obtained the Technical Regulations Conformity Certification as provided in Radio Law of Japan with respect to this product Also please do not transfer this product unless you give the same notice above to the transferee Please note that if you could not follow the instructions above you will be subject to penalties of Radio Law of Japan Texas Instruments Japan Limited address 24 1 Nishi Shinjuku 6 chome Shinjuku ku Tokyo Japan http www tij co jp
33. did a complete install of SmartRF Studio Windows will recognize the device automatically and the SmartRFOGEB is ready for use 4 1 2 1 Install FTDI USB driver manually in Windows If the SmartRFOGEB was not properly recognized after plugging it into your PC try the following steps to install the necessary USB drivers The steps described are for Microsoft Windows 7 but are very similar to those in Windows XP and Windows Vista It is assumed that you have already downloaded and installed the latest version of SmartRF Studio 7 1 Open the Windows Device Manager and right click on the first Texas Instruments XDS100v3 found under Other devices as shown in Figure 1a Select Update Driver Software and in the appearing dialog browse to lt Studio install dir gt Drivers ftdi as shown in Figure 1b Page 7 32 A TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 File Action View Help 9st Hs WIS Browse for driver software on your computer p Keyboards 8 Wace and other pomting dences Search for driver software in this location gt 4 Modems K Monitors Program Files x86 Texas Instruments SmartRF Tools Drivers ftdi v Browse Network adapters jj Non Plug and Play Drivers 4 M Other devices fq Texas Instruments XDS100v3 lig Texas Instruments XDS100v3 Unknown device 15 Unknown device J5 USB Serial Port b E PCMCIA adapters H Portable Devices Properties 1 Ports COM amp
34. e EM domain via level shifters U401 and U402 The 3 3 V domain may be switched on off completely by the mounted EM board by pulling signal LV 3 3V EN to a logical 1 0 See Table 14 in section 6 11 1 for details about the mapping between the EM and signals onboard the SmartRFOGEB 6 4 LCD The SmartRFO6EB comes with a 128x64 pixels display from Electronic Assembly DOGM 128E 6 4 The LCD display is available to mounted EM via a SPI interface enabling software development of user interfaces and demo use Table 6 shows an overview of the I O signals related to the LCD The recommended operating condition for the LCD display is a supply voltage between 3 0 V and 3 3 V The LCD display is powered from the 3 3 V power domain HI VDD The min max operating temperature is 20 70 C The LCD connector on SmartRFO6EB is very tight to ensure proper contact between the EM and the LCD Be extremely cautious when removing the LCD to avoid the display from breaking Page 18 32 IA TEXAS INSTRUMENTS Signal name Description User s Guide SWRU321A May 2013 Probe header LV 3 3V EN 3 3 V domain enable signal RF1 15 P407 1 LV_LCD_MODE LCD mode signal LV LCD RESET LCD reset signal active low RF1 11 P406 7 LV LUD CS LCD Chip Select active low RF1 13 P406 9 RF1 17 P407 3 LV SPI SCK SPI Clock RF1 16 SCK P407 2 LV SPI MOSI SPI MOSI LCD inp
35. e m SL T EMUS R53 R 51 0402 G P1 5V occ N ved 9 Pav 1 s so end_ bal P3 3VXDS 39 em De pasa veciBi 1 EH RE VTARGET SUSPEND 40 jo87RSB1 i019RsBd A T TMS wur ALT FUNC a R15 R 81 0402 G E 1084RSB1 EA i 5 T TDI Re R51 0402 6 PRG_TCK XXX du lt Se PRG TMS 43 1o75RSB1 ose 2 T TDO me PRG_TDOAPRG_TDI 44 R16 R 51 0402 G GDC2 Io72RSB1 sospeso 2 i 5 RICK P33VXDS PRG TDO D R23 R51 m G epB2io71RSB1 EEN 5t T E T TCK IGDA2 IOTORSB1 RY TO t emuo ei GBC1 IO36RSBO PRG TCK Lan raa Ram GRE ET STe Tok D 1 2 ESS ol GBB0 IO37RSB0 E PRG TDi MM C Ret cr SS 5 esB1ossRSBo PRG_TMS PRG_TMS a Ms GBAO IO39RSBO d J T_EMU1 P3 3VXDS Lage R26 or GBA1 1040RSB0 5 o 000 0 ao 9990000800 zo 8 989082990 EIS SSQNSNRS lt SQO SS 9952999858 92999 DRISSAN N lt RETEA S 2222232220 32233 KH 350020005020 bo so OC ges EEE EE TELE EE 222902280800 80uz20D002 lt 6 se or ae olor Foles eaes polor oko ol zp 13 Gros Cice A0mis PRG IM a Tea gman Cele 4 PRG TMS we Tos Clasp Cic Anis RS TDI pe el Circle Z PRG TCK zy 1 o estpoint_ Crole_ 40mis PRG TRST Sg estpoint_Circle_40mis wRD4E002 mpp4goo2 T Emus ioi 104 Ls T emus ERES lies PT T Tus 2 GND TPD4E002 2 Np TPD4E002 T
36. er XDSIB8v3 wi Figure 7 Jumper mounted on J5 to enable the UART back channel Signal name Description Probe header RF1 7 UART RX UART Receive EM data in EM UART RX P412 2 RF1 9 UART TX UART Transmit EM data out EM UART TX P412 3 RF1 8 UART CTS UART Clear To Send signal EM UART CTS P412 4 RF2 18 UART RTS UART Request To Send signal EM UART RTS P412 5 Table 4 UART Back channel signal connections 6 2 Power Sources There are three ways to power the SmartRF06EB batteries USB bus and external power supply The power source can be selected using the power source selection switch 8502 seen in Figure 8 The XDS100v3 Emulator can only be powered over USB The main power supply switch 8501 cuts power to the SmartRFOGEB Never connect batteries and an external power source to the SmartRFOGEB at the same time Doing so may lead to excessive currents that may damage the batteries or cause onboard components to break The CR2032 coin cell battery is in particular very sensitive to reverse currents charging and must never be combined with other power sources AAA batteries or an external power source Page 14 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 SOURCE e Al E Figure 8 Main power switch P501 and source selection switch P502 6 2 1 USB Power When the SmartRFO6EB is connected to a PC via a USB cable it can draw power from the USB bu
37. ge injury or death even if the EVM should fail to perform as described or expected 4 You will take care of proper disposal and recycling of the EVM s electronic components and packing materials Certain Instructions It is important to operate this EVM within TI s recommended specifications and environmental considerations per the user guidelines Exceeding the specified EVM ratings including but not limited to input and output voltage current power and environmental ranges may cause property damage personal injury or death If there are questions concerning these ratings please contact a TI field representative prior to connecting interface electronics including input power and intended loads Any loads applied outside of the specified output range may result in unintended and or inaccurate operation and or possible permanent damage to the EVM and or interface electronics Please consult the EVM User s Guide prior to connecting any load to the EVM output If there is uncertainty as to the load specification please contact a TI field representative During normal operation some circuit components may have case temperatures greater than 60 C as long as the input and output are maintained at a normal ambient operating temperature These components include but are not limited to linear regulators switching transistors pass transistors and current sense resistors which can be identified using the EVM schematic located in the EVM User s Guide When
38. ian for help For EVMs annotated as IC INDUSTRY CANADA Compliant This Class A or B digital apparatus complies with Canadian ICES 003 Changes or modifications not expressly approved by the party responsible for compliance could void the user s authority to operate the equipment Concerning EVMs including radio transmitters This device complies with Industry Canada licence exempt RSS standard s Operation is subject to the following two conditions 1 this device may not cause interference and 2 this device must accept any interference including interference that may cause undesired operation of the device Concerning EVMs including detachable antennas Under Industry Canada regulations this radio transmitter may only operate using an antenna of a type and maximum or lesser gain approved for the transmitter by Industry Canada To reduce potential radio interference to other users the antenna type and its gain should be so chosen that the equivalent isotropically radiated power e i r p is not more than that necessary for successful communication This radio transmitter has been approved by Industry Canada to operate with the antenna types listed in the user guide with the maximum permissible gain and required antenna impedance for each antenna type indicated Antenna types not included in this list having a gain greater than the maximum gain indicated for that type are strictly prohibited for use with this device Cet appareil n
39. igure 2b The SmartRFOGEB drivers are now installed correctly Advanced Diver Details File Action View Help elle 4 7 Ports COM amp LPT 2 ie TI XDS100v3 Channel B ommunications Port COMI aii Use these settings to override normal device behaviour D Processors Smart card readers V Load VCP Xj Sound video and game controllers BR System devices 4 Universal Serial Bus controllers Generic USB Hub Intel R ICH8 Family USB Universal Host Controller 2830 Intel R ICH8 Family USB Universal Host Controller 2831 D Intel R ICH8 Family USB Universal Host Controller 2832 Intel R ICH8 Family USB Universal Host Controller 2834 Intel R ICH8 Family USB Universal Host Controller 2835 Intel R ICH8 Family USB2 Enhanced Host Controller 2836 ntel R TCHR Family LISR hanced Host Controller 283A TIXDS100v3 Channel A T1XDS100v3 Channel B Figure 2 Driver install a VCP loaded and b drivers successfully installed Page 8 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 4 1 2 2 Install XSD100v3 UART back channel on Linux The ports on SmartRFOGEB will typically be mounted as ttyUSBO or ttyUSB1 The UART back channel is normally mounted as ttyUSB1 Download the Linux drivers from 2 Untar the ftdi sio tar gz file on your Linux system Connect the SmartRFOGEB to your system Install driver a Verify the USB Product ID PID and Vendor ID VID
40. in The mounted EM board and most of the SmartRFOGEB peripherals are powered in the EM domain and signals in this domain accessible by the EM are prefixed LV in the schematics Table 5 lists the EB peripherals that are powered in the EM domain The domain is turned on off by the SmartRFO6EB power switch Page 17 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 The EM domain may be powered using various power sources USB powered regulated to 3 3 V battery powered regulated to 2 1 V or unregulated and using an external power supply regulated to 2 1 V or unregulated When battery powered or powered by an external source the EM power domain is by default regulated to 2 1 V using a step down converter The step down converter may be bypassed by mounting a jumper on J502 Figure 13 powering the EM domain directly from the source When J502 is not mounted the EM power domain is regulated to 2 1 V The maximum current consumption of the EM power domain is then limited by the regulator to 410 mA 6 3 3 3 3 V Domain The 3 3 V domain is a sub domain of the EM domain The 3 3 V domain is regulated to 3 3 V using a buck boost converter irrespective of the source powering the EM domain Signals in the 3 3V domain controlled by the EM are prefixed HV for High Voltage in the schematics Two EB peripherals are in the 3 3 V domain the LCD and the SD card slot as listed in Table 5 These peripherals are connected to th
41. in Level 3 3 V domain 3 3 V O 1 8 3 6 V 3 3 V XDS100v8 XDS LEDs shifters AC ALS keys LEDs shifters LCD SD card Power sources USB batteries external supply Figure 12 Power domain overview of SmartRFO6EB Component Power domain Power source Evaluation Module EM domain LO VDD USB battery external General Purpose LEDs EM domain LO VDD USB battery external Accelerometer USB battery external Ambient Light Sensor EM domain LO VDD USB battery external Current measurement MCU MSP EM domain LO VDD EM domain LO VDD USB battery external LEDs EM domain LO VDD USB battery external XDS100v3 Emulator XDS domain USB XDS100v3 LEDs XDS domain USB SD Card Slot 3 3 V domain HI VDD Same as EM domain LCD 3 3 V domain HI VDD Same as EM domain Table 5 Power domain overview of SmartRFOGEB 6 3 1 XDS Domain The XDS100v3 Emulator see section 6 1 onboard the SmartRFOGEB is in the XDS domain The XDS domain is powered over USB The USB voltage supply 5 V is down converted to 3 3 V and 1 5 V for the different components of the XDS100v3 Emulator The SmartRFO6EB must be connected to e g a PC over USB for the XDS domain to be powered up The domain is turned on off by the SmartRF06EB main power switch 6 3 2 EM Doma
42. is intended solely for use for preliminary feasibility evaluation in laboratory development environments by technically qualified electronics experts who are familiar with the dangers and application risks associated with handling electrical mechanical components systems and subsystems It should not be used as all or part of a finished end product Your Sole Responsibility and Risk You acknowledge represent and agree that 1 You have unique knowledge concerning Federal State and local regulatory requirements including but not limited to Food and Drug Administration regulations if applicable which relate to your products and which relate to your use and or that of your employees affiliates contractors or designees of the EVM for evaluation testing and other purposes 2 You have full and exclusive responsibility to assure the safety and compliance of your products with all such laws and other applicable regulatory requirements and also to assure the safety of any activities to be conducted by you and or your employees affiliates contractors or designees using the EVM Further you are responsible to assure that any interfaces electronic and or mechanical between the EVM and any human body are designed with suitable isolation and means to safely limit accessible leakage currents to minimize the risk of electrical shock hazard 3 You will employ reasonable safeguards to ensure that your use of the EVM will not result in any property dama
43. mem scale sHeet 7 7 EVALUATION BOARD KIT MODULE EVM ADDITIONAL TERMS Texas Instruments TI provides the enclosed Evaluation Board Kit Module EVM under the following conditions The user assumes all responsibility and liability for proper and safe handling of the goods Further the user indemnifies TI from all claims arising from the handling or use of the goods Should this evaluation board kit not meet the specifications indicated in the User s Guide the board kit may be returned within 30 days from the date of delivery for a full refund THE FOREGOING LIMITED WARRANTY IS THE EXCLUSIVE WARRANTY MADE BY SELLER TO BUYER AND IS IN LIEU OF ALL OTHER WARRANTIES EXPRESSED IMPLIED OR STATUTORY INCLUDING ANY WARRANTY OF MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR PURPOSE EXCEPT TO THE EXTENT OF THE INDEMNITY SET FORTH ABOVE NEITHER PARTY SHALL BE LIABLE TO THE OTHER FOR ANY INDIRECT SPECIAL INCIDENTAL OR CONSEQUENTIAL DAMAGES Please read the User s Guide and specifically the Warnings and Restrictions notice in the User s Guide prior to handling the product This notice contains important safety information about temperatures and voltages For additional information on TI s environmental and or safety programs please visit www ti com esh or contact TI No license is granted under any patent right or other intellectual property right of TI covering or relating to any machine process or combination in which such TI
44. ng unit for measuring the current consumption of the mounted EM Figure 20 The current sensing setup is high side that is it measures the current going to the mounted EM The current is converted to a voltage available at the CURMEAS OUTPUT test point TP11 located near the right edge of the SmartRFOGEB Using the SmartRFO6EB together with for example an oscilloscope makes it easy to measure the EM current consumption as a function of time The relationship between the voltage measured at CURMEAS OUTPUT Vcurmeas and the EM current consumption leu is given by Equation 1 below I CURMEAS 1 15 lem To EM E VcunveAs Figure 20 Simplified schematic of high side current sensing setup 6 12 2 Current Measurement Jumper SmartRFO6EB has a current measurement header J503 for easy measurement of EM current consumption Header J503 is located on the upper right hand side of the EB By replacing the jumper with an ammeter as shown in Figure 21 the current consumption of the mounted EM can be measured Figure 21 Measuring current consumption using jumper J503 Page 27 32 IA TEXAS INSTRUMENTS User s Guide SWRU321A May 2013 7 Debugging an external target using SmartRFO6EB You can easily use XDS100v3 Emulator onboard the SmartRFO6EB to debug an external target It is in this chapter assumed that the target is self powered When debugging an external self powered target using SmartRFO6EB make s
45. o the external target board User s Guide SWRU321A May 2013 Make sure all the jumpers on the XDS bypass header P408 are mounted and that the jumper is removed from header J503 Table 17 shows the signals that must be strapped between the SmartRFOGEB and the target board Table 18 shows additional signals that are optional or needed for debugging using 4 pin JTAG Figure 24 shows where the signals listed in Table 17 and Table 18 can be found on the 20 pin ARM JTAG header VDD SENSE Target voltage supply GND Common ground for EB and external board RF2 1 JTAG TCK Test Clock RF2 4 JTAG TMS RF2 17 JTAG TDI P409 5 Test Mode Select Test Data In optional for cJTAG RF2 19 JTAG TDO P409 13 Test Data Out optional for cJTAG RF2 15 RESET P409 15 Target reset signal optional Table 18 Debugging external target Optional strapping Liu eil T a Ead E T ma T P Figure 24 ARM JTAG header P409 with strapping to debug external target Page 30 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 8 Frequently Asked Questions Q1 A1 Q2 A2 Q3 A3 Q4 A4 Nothing happens when power up the evaluation board Why Make sure you have a power source connected to the EB Verify that the power source selection switch S502 is set correctly according to your power source When powering the EB from either bat
46. oth for Windows x86 and Windows x64 platforms After you have downloaded SmartRF Studio from the web extract the zip file run the installer and follow the instructions Select the complete installation to include the SmartRF Studio program the SmartRF Studio documentation and the necessary drivers needed to communicate with the SmartRFO6EB 4 1 1 SmartRF Studio SmartRF Studio is a PC application developed for configuration and evaluation of many RF IC products from Texas Instruments The application is designed for use with SmartRF Evaluation Boards such as SmartRFO6EB and runs on Microsoft Windows operating systems SmartRF Studio lets you explore and experiment with the RF ICs as it gives full overview and access to the devices registers to configure the radio and has a control interface for simple radio operation from the PC This means that SmartRF Studio will help radio system designers to easily evaluate the RF IC at an early stage in the design process It also offers a flexible code export function of radio register settings for software developers The latest version of SmartRF Studio can be downloaded from the Texas Instruments website 1 where you will also find a complete user manual 4 1 2 FTDI USB driver SmartRF PC software such as SmartRF Studio uses a proprietary USB driver from FTDI 2 to communicate with SmartRF06 evaluation boards Connect your SmartRFOGEB to the computer with a USB cable and turn it on If you
47. placing measurement probes near these devices during normal operation please be aware that these devices may be very warm to the touch As with all electronic evaluation tools only qualified personnel knowledgeable in electronic measurement and diagnostics normally found in development environments should use these EVMs Agreement to Defend Indemnify and Hold Harmless You agree to defend indemnify and hold TI its licensors and their representatives harmless from and against any and all claims damages losses expenses costs and liabilities collectively Claims arising out of or in connection with any use of the EVM that is not in accordance with the terms of the agreement This obligation shall apply whether Claims arise under law of tort or contract or any other legal theory and even if the EVM fails to perform as described or expected Safety Critical or Life Critical Applications If you intend to evaluate the components for possible use in safety critical applications such as life support where a failure of the TI product would reasonably be expected to cause severe personal injury or death such as devices which are classified as FDA Class III or similar classification then you must specifically notify Tl of such intent and enter into a separate Assurance and Indemnity Agreement Mailing Address Texas Instruments Post Office Box 655303 Dallas Texas 75265 Copyright O 2013 Texas Instruments Incorporated IMPORTANT NOTICE Texas In
48. products or services might be or are used TI currently deals with a variety of customers for products and therefore our arrangement with the user is not exclusive Tl assumes no liability for applications assistance customer product design software performance or infringement of patents or services described herein REGULATORY COMPLIANCE INFORMATION As noted in the EVM User s Guide and or EVM itself this EVM and or accompanying hardware may or may not be subject to the Federal Communications Commission FCC and Industry Canada IC rules For EVMs not subject to the above rules this evaluation board kit module is intended for use for ENGINEERING DEVELOPMENT DEMONSTRATION OR EVALUATION PURPOSES ONLY and is not considered by TI to be a finished end product fit for general consumer use It generates uses and can radiate radio frequency energy and has not been tested for compliance with the limits of computing devices pursuant to part 15 of FCC or ICES 003 rules which are designed to provide reasonable protection against radio frequency interference Operation of the equipment may cause interference with radio communications in which case the user at his own expense will be required to take whatever measures may be required to correct this interference General Statement for EVMs including a radio User Power Frequency Use Obligations This radio is intended for development professional use only in legally allocated frequency and power limits
49. re detail Pin connections between the EM and the evaluation board I O can be found in section 6 10 Figure 4 SmartRFOGEB architecture Page 12 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 EMI O breakout PATI 4 Eu vonz RF Em connectors Ambient Light Pos LEDs Sensor ip He BEE JL IRON ENT EL EM current LEDs measurement L i Dette SmartRFO6 NE A cotpoint and Accelerometer eN ag pEb e Evaluation Board Main power Switch m ai Power source 20 pin ARM selection switch cw 055590050595 JTAG Header Lee e EM reset button ES 8 Bp UART back H channel enable reed v 239 Jumper bypass jumper 10 pin ARM External power 1 P je i Cortex Header supply he g c SELECT Es neral purpose LCD UART back Micro SD channel card a MICRO SD n Figure 5 SmartRFOGEB revision 1 2 1 front side 1 5 VAAA XDS100v3 Alkaline Battery Emulator holder X7S108v3 DEBUG PROBE CR2032 coin 1 5 VAAA Alkaline Battery cell battery holder holder in E gt gt gt gt of 3 D w D D lt Figure 6 SmartRFOGEB revision 1 2 1 reverse side 6 1 XDS100v3 Emulator The XDS100v3 Emulator from Texas Instruments has cJTAG and regular JTAG support cJTAG is a 2 pin extension to regular 4 pin JTAG The XDS100v3 consists of a USB to JTAG chip from FTDI 2 and an FPGA to convert JTAG inst
50. right relating to any combination machine or process in which TI components or services are used Information published by TI regarding third party products or services does not constitute a license to use such products or services or a warranty or endorsement thereof Use of such information may require a license from a third party under the patents or other intellectual property of the third party or a license from TI under the patents or other intellectual property of TI Reproduction of significant portions of TI information in TI data books or data sheets is permissible only if reproduction is without alteration and is accompanied by all associated warranties conditions limitations and notices TI is not responsible or liable for such altered documentation Information of third parties may be subject to additional restrictions Resale of TI components or services with statements different from or beyond the parameters stated by TI for that component or service voids all express and any implied warranties for the associated TI component or service and is an unfair and deceptive business practice Tl is not responsible or liable for any such statements Buyer acknowledges and agrees that it is solely responsible for compliance with all legal regulatory and safety related requirements concerning its products and any use of TI components in its applications notwithstanding any applications related information or support that may be provided by TI
51. rtex debug header 8 Figure 19 enabling the user to debug an external target using the XDS100v3 Emulator The ARM Cortex debug header is located near the right hand edge of the EB The header pin out is given in Table 16 Chapter 7 has more information on how to debug an external target using the XDS100v3 Emulator onboard the SmartRFO6EB Pin Signal ITA TH Lei CU SRG C FORTI Description ortex Debug header P410 EB signal name XDS bypass header P410 1 VCC Voltage reference VDD_SENSE P408 19 20 P410 2 TMS Test Mode Select RF2 4 JTAG TMS P408 3 4 P410 3 GND Ground GND P410 4 TCK Test Clock RF2 1_JTAG_TCK P408 1 2 P410 5 GND Ground GND P410 6 TDO Test Data Out RF2 19 JTAG TDO P408 7 8 P410 7 KEY Key NC P410 8 TDI Test Data In RF2 17 JTAG TDI P408 5 6 P410 9 GNDDetect Ground detect GND P410 10 nRESET System Reset RF2Z 15 RESET P408 9 10 Table 16 10 pin ARM Cortex Debug header pin out P410 Page 26 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 6 12 Current Measurement The SmartRFO6EB provides two options for easy measurements of the current consumption of a mounted EM The following sections describe these two options in detail 6 12 1 High side current sensing The SmartRFOGEB comes with a current sensi
52. ructions to cJTAG format Page 13 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 In addition to regular debugging capabilities using cJTAG or JTAG the XDS100v3 Emulator supports a UART backchannel over a USB Virtual COM Port VCP to the PC The UART back channel supports flow control 8 N 1 format and data rates up to 12Mbaud Please see the XDS100v3 emulator product page 4 for detailed information about the emulator The XDS100v3 Emulator is powered over USB and is switched on as long as the USB cable is connected to the SmartRFOGEB and the main power switch S501 is in the ON position The XDS100v3 Emulator supports targets with operating voltages between 1 8 V and 3 6 The min max operating temperature is 20 70 C 6 1 1 UART back channel The mounted EM can be connected to the PC via the XDS100v3 Emulator s UART back channel When connected to a PC the XDS100v3 is enumerated as a Virtual COM Port VCP over USB The driver used is a royalty free VCP driver from FTDI available for e g Microsoft Windows Linux and Max OS X The UART back channel gives the mounted EM access to a four pin UART interface supporting 8 N 1 format at data rates up to 12 Mbaud To enable the SmartRFO6EB UART back channel the Enable UART over XDS100v3 jumper J5 located on the lower right side of the EB must be mounted Figure 7 Table 4 shows an overview of the I O signals related to UART Back Channel Kal Enable UART om ov
53. s The onboard voltage regulator supplies approximately 3 3 V to the mounted EM and the EB peripherals To power the mounted EM and the EB peripherals from the USB bus the power source selection switch S502 should be in USB position Figure 9 The maximum current consumption is limited by the regulator to 1500 mA SOURCE T7 e 1 1 Figure 9 SmartRF06EB power selection switch P502 in USB position 6 2 2 Battery Power The SmartRFO6EB can be powered using two 1 5 V AAA alkaline batteries or a 3 V CR2032 coin cell battery The battery holders for the AAA batteries and the CR2032 coin cell battery are located on the reverse side of the PCB To power the mounted EM and the EB peripherals using batteries the power source selection switch S502 should be in BAT position Figure 10 When battery powered the EM power domain is by default regulated to 2 1 V The voltage regulator may be bypassed by mounting a jumper on J502 See section 6 3 2 for more details Do not power the SmartRFO6EB using two 1 5 V AAA batteries and a 3 V CR2032 coin cell battery at the same time Doing so may lead to excessive currents that may damage the batteries or cause onboard components to break Note that most USB power sources are limited to 500 mA Page 15 32 IA TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 Ze TE eg Figure 10 SmartRFO6EB power source selection switch P502 in BAT position
54. s Instruments APPROVALS DATE DWG MAW SmartRFOGEB XDS100v3 FTDI DRAWN 12 07 12 SIZE FSCMNO DWG NO CHECKED XU A3 ISSUED mmm scale SHEET 3 7 Am ap oan HN P3 3VXDS P3 3VXDS P3 3VXDS P3 3VXDS P3 3VXDS EM DEBUG CONNECTION EM CONNECTORS Bypass jumper block for connection RF2 between EM and XDS100v3 RF1 SMb HEADER 2x10 i i SMD HEADER 2x10 x D SMD HEADER 2X1 RE2 1 JTAG TCK ELI 2 GND Zeg RETS oo RE2 1 JTAG TCK i RF1 8 RF_VDD1 i RE1 10 d Ko RF2 4_JTAG_TMS SES o RETTA SES RH oh RF2 17_JTAG_TDI i RF146 SPI SCK REZ TS REZ 16 i i RET 16_SPLSGK SES T REZ T8 UART lc ole RF2 19_JTAG_TDO i o RF120 SPI MISO RF2 19 GND i es k ole RFZ15 RESET oo i i t H RF1 7 UART RX bo aa f t H RF1 9 UART TX i So LL d p le RF1 3 UART CTS 6o e Je RF2 18_UART_RTS 6o la bo VDD SENSE So PINROW_SMD_2X10_2 54MM EM lt gt EB BREAKOUT and PROBE HEADERS 20 pin ARM JTAG Connector 10 pin ARM Cortex
55. se LED signal connections 6 9 2 XDS100v3 Emulator LEDs The XDS100v3 emulator has two LEDs to indicate its status D2 and D4 The LEDs are located on the top side of the SmartRFO6EB LED D2 is lit whenever the XDS100v3 Emulator is powered while LED D4 ADVANCED MODE is lit when the XDS100v3 is in an active cJTAG debug state 6 10 EM Connectors The EM connectors shown in Figure 15 are used for connecting an EM board to the SmartRFOGEB The connectors RF1 and RF2 are the main interface and are designed to inhibit incorrect mounting of the EM board The pin out of the EM connectors is given in Table 12 and Table 13 EM HO RF2 Cap T C482 jai fi eee eee ee R482 5 e 3 Figure 15 SmartRFO6EB EM connectors RF1 and RF2 Page 21 32 IA TEXAS INSTRUMENTS Signal name Description User s Guide SWRU321A May 2013 Probe Breakout header header GND Ground RF1 2 GPIO signal to EM board P406 1 P403 1 2 RF1 3 UART CTS UART back channel GPIO P412 4 P408 15 16 RF1 4 GPIO signal to EM board P406 2 P403 3 4 RF1 5 GPIO signal to EM board P406 3 P403 5 6 RF1 6 GPIO signal to EM board P406 4 P403 7 8 RF1 7 UART RX UART back channel EM RX P412 2 P408 11 12 RF1 8 GPIO signal to EM board P406 5 P403 9 10 RF1 9 UART TX UART back channel EM TX P412 3 P408 13 14 RF1 10 GPIO signal to EM board P406
56. sessi 24 6 11 3 20 pin ARM STAG Header ss 25 6 11 4 10 pin ARM Cortex Debug Header 26 6 12 GURRENT MEASUREMENT 5 4 2 t tesi teret repose i ree etes Dee ce ete Ee 27 6 12 1 High side current sensing sise 2Z 6 12 2 Current Measurement Jumper 2Z 7 1 20 PINARMJTAGHEADER SS Nk 29 7 2 10 PIN ARM CORTEX DEBUG HEADER i 29 7 3 CUSTOM STRAPPING2 3 idit va TEE nes trad te ann da net tea E A na ad te ET 30 List of Figures Figure 1 Driver install a Update driver b Specify path to FTDI drivers 8 Figure 2 Driver install a VCP loaded and b drivers successfully installed 8 Figure 3 SmartRFOGEB rev 1 2 1 with EM connected 10 Figure 4 SmartRFOGEB architecture eee enne enne nennen 12 Figure 5 SmartRFOGEB revision 1 2 1 front side eene 13 Figure 6 SmartRFOGEB revision 1 2 1 reverse side uur 13 Figure 7 Jumper mounted on J5 to enable the UART back channel 14 Figure 8 Main power switch P501 and source selection switch P502 15 Figure 9 SmartRFO6EB power selection switch P502 in USB position 15 Figure 10 SmartRFO6EB power source selection switch P502 in BAT position eee 16 Figure 11 SmartRFO6EB external power supply header J501 sss 16 Figure 12 Power domain overview of SmartRFO6EB 1
57. ssembly DOGM128 6 Datasheet http www Icd module com eng pdf grafik dogm128e pdf 6 Bosch Sensortec BMA250 Datasheet http ae bst resource bosch com media products dokumente bma250 bst bma250 ds002 05 pdf 7 Osram SFH 5711 http www osram os com 8 Cortex M Debug Connectors http infocenter arm com help topic com arm doc faqs attached 13634 cortex_debu g_connectors pdf 10 Document History Revision Date Description Changes SWRU321A 2013 05 21 Minor fixes to Figure 4 Fixed incorrect EM mapping in Table 11 Added steps for installing SmartRFO6EB on Linux SWRU321 2012 09 07 Initial version Page 32 32 TEXAS INSTRUMENTS User s Guide SWRU321A May 2013 Appendix A Schematics SmartRFOGEB 1 2 1 XDS100v3 FPGA XDS100v3 FTDI EM INTERFACE LEVEL SHIFTERS POWER SUPPLY HIGH VOLTAGE PERIPHERALS FIDUCIAL MARK mm FIDUCIAL MARK imm FIDUCIAL_MARK_1mm FM1 FM2 FM3 FIDUCIAL MARK mm FIDUCIAL MARK imm FIDUCIAL MARK mm FM4 TESTPOINT_PAD TESTPOINT_PAD TP12 TP13 S HOLE 3 HOLE 3 HOLE 3 HOLE 3 FAN a RS BA 4 jw Nec NEP Na LOW VOLTAGE PERIPHERALS CONTRACT NO COMPANY NAME Texas Instruments APPROVALS DATE DWG MAW SmartRFO6EB Top Level DRAWN 120712 sizE FscMNo DWG No REV CHECKED ior A3 1 2 1 ISSUED mem scale sneer 1 7
58. struments Incorporated and its subsidiaries Tl reserve the right to make corrections enhancements improvements and other changes to its semiconductor products and services per JESD46 latest issue and to discontinue any product or service per JESD48 latest issue Buyers should obtain the latest relevant information before placing orders and should verify that such information is current and complete All semiconductor products also referred to herein as components are sold subject to Tl s terms and conditions of sale supplied at the time of order acknowledgment TI warrants performance of its components to the specifications applicable at the time of sale in accordance with the warranty in TI s terms and conditions of sale of semiconductor products Testing and other quality control techniques are used to the extent TI deems necessary to support this warranty Except where mandated by applicable law testing of all parameters of each component is not necessarily performed Tl assumes no liability for applications assistance or the design of Buyers products Buyers are responsible for their products and applications using Tl components To minimize the risks associated with Buyers products and applications Buyers should provide adequate design and operating safeguards TI does not warrant or represent that any license either express or implied is granted under any patent right copyright mask work right or other intellectual property
59. teries or an external power source S502 should be in BAT position When powering the EB over USB the switch should be in USB position Also make sure the EM current measurement jumper J503 is short circuited Why are there two JTAG connectors on the SmartRFO6EB which one should use The SmartRFOGEB comes with two different standard debug connectors the 20 pin ARM JTAG connector P409 and the compact 10 pin ARM Cortex debug connector P410 These debug connectors are there to more easily debug external targets without the need of customized strapping For more details on how to debug external targets using the SmartRF06EB see chapter 7 Can I use the SmartRFO6EB to debug an 8051 SoC such as CC2530 No you cannot debug an 8051 SoC using the SmartRFOGEB When connecting my SmartRFO6EB to my PC no serial port appears Why It may be that the virtual COM port on the SmartRFOGEB s XDS100 channel B hasn t been enabled Section 4 1 2 1 1 describes how to enable the Vritual COM Port in the USB driver Page 31 32 TEXAS User s Guide INSTRUMENTS SWRU321A May 2013 9 References 1 SmartRF Studio Product Page http www ti com tool smartrftm studio 2 FTDI USB Driver Page http www ftdichip com 3 SmartRF Flash Programmer Product Page http www ti com tool flash programmer 4 XDS100 Emulator Product Page http processors wiki ti com index php XDS100 5 Electronic A
60. uipment generates uses and can radiate radio frequency energy and if not installed and used in accordance with the instruction manual may cause harmful interference to radio communications Operation of this equipment in a residential area is likely to cause harmful interference in which case the user will be required to correct the interference at his own expense FCC Interference Statement for Class B EVM devices This equipment has been tested and found to comply with the limits for a Class B digital device pursuant to part 15 of the FCC Rules These limits are designed to provide reasonable protection against harmful interference in a residential installation This equipment generates uses and can radiate radio frequency energy and if not installed and used in accordance with the instructions may cause harmful interference to radio communications However there is no guarantee that interference will not occur in a particular installation If this equipment does cause harmful interference to radio or television reception which can be determined by turning the equipment off and on the user is encouraged to try to correct the interference by one or more of the following measures Reorient or relocate the receiving antenna Increase the separation between the equipment and receiver Connect the equipment into an outlet on a circuit different from that to which the receiver is connected Consult the dealer or an experienced radio TV technic
61. um rique de la classe A ou B est conforme la norme NMB 003 du Canada Les changements ou les modifications pas express ment approuv s par la partie responsable de la conformit ont pu vider l autorit de l utilisateur pour actionner l quipement Concernant les EVMs avec appareils radio Le pr sent appareil est conforme aux CNR d Industrie Canada applicables aux appareils radio exempts de licence L exploitation est autoris e aux deux conditions suivantes 1 l appareil ne doit pas produire de brouillage et 2 l utilisateur de l appareil doit accepter tout brouillage radio lectrique subi m me si le brouillage est susceptible d en compromettre le fonctionnement Concernant les EVMs avec antennes d tachables Conform ment la r glementation d Industrie Canada le pr sent metteur radio peut fonctionner avec une antenne d un type et d un gain maximal ou inf rieur approuv pour l metteur par Industrie Canada Dans le but de r duire les risques de brouillage radio lectrique l intention des autres utilisateurs il faut choisir le type d antenne et son gain de sorte que la puissance isotrope rayonn e quivalente p i r e ne d passe pas l intensit n cessaire l tablissement d une communication satisfaisante Le pr sent metteur radio a t approuv par Industrie Canada pour fonctionner avec les types d antenne num r s dans le manuel d usage et ayant un gain admissible maximal et l imp dance requise pour
62. ure to remove the jumper from the current measurement header J503 as shown in the second scenario of Figure 22 In this scenario the onboard XDS100v3 senses the target voltage of the external target In the left side scenario of the same figure the XDS100v3 senses the target voltage of the EB s EM domain Having a jumper mounted on header J503 when debugging an external target will cause a conflict between the EB s EM domain supply voltage and the target s supply voltage This may result in excess currents damaging the onboard components of the SmartRFO6EB or the target board In Figure 22 the right hand side scenario shows how it is possible to debug an EM mounted on the SmartRF06EB using an external debugger In this scenario all the jumpers must be removed from the SmartRFO6EB header P408 to avoid signaling conflicts between the onboard XDS100v3 Emulator and the external debugger O6EB XDS EM O6EB XDS external target EM EM EM domain EM domain J503 e ech mourted Current measurement jumper hat trourted Debug Target VDD header P408 T xps bypass header P408 jumpers on jumpers on XDS100v3 XDS100v3 P409 P410 Ext target External debugger EM EM EM domain J503 mounted P409 P410 External debugger P408 jumpers XDS100v3 Figure 22 Simplified connection diagr
63. ut RF1 18 MOSI P407 4 Table 6 LCD signal connections 6 5 Micro SD Card Slot The SmartRFOGEB has a micro SD card slot for connecting external SD MMC flash devices flash device not included A connected flash device is available to the mounted EM via a SPI interface giving it access to extra flash enabling over the air upgrades and more Table 8 shows an overview of I O signals related to the micro SD card slot The micro SD card is powered from the 3 3 V power domain HI VDD Signal name Description Probe header LV 3 3V EN 3 3 V domain enable signal RF1 15 P407 1 LV SDCAHD CS SD card Chip Select active low RF2 12 P411 1 LV SPI SCK SPI Clock RF1 16 SCK P407 2 LV SPI MOSI SPI MOSI SD card input RF1 18 MOSI P407 4 LV SPI MISO SPI MISO SD card output RF1 20 MISO P407 5 Table 7 Micro SD Card signal connections 6 6 Accelerometer The SmartRFO6EB is equipped with a BMA250 digital accelerometer from Bosch Sensortech 6 The accelerometer is available to the mounted EM via an SPI interface and has two dedicated interrupt lines The accelerometer is suitable for application development prototyping and demo use Table 8 shows an overview of I O signals related to the accelerometer The recommended operating condition for the accelerometer is a supply voltage between 1 62 V and 3 6 V The min max operating temperature is 40 85 C

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