Renesas Starter Kit+ for RZ/A1H User`s Manual
Contents
1. 173 180 118 99 6 29 0 3 3 4 PLACES 4 PLACES 2 oer dia ru CN26 Lu GE DES Eu EIl eo EBER A 010 un ele e EB B ERI EEB 1119 ee He 358 25 166 E A e EEE 2 LL ee sle Ce on SEE NOTE 3 5 sed e E E s E enu o E A 99 y E e a g El wo 99 y 8 os 2 22 7 el 8 o Ts Bs 47 d i 24 B 72 gel 2 HAB axe 4 B ER E 2 e ES e sel 9 8 2 a se 8 q ES 8 m wo ei mm m ma EU E E m e ka ey oe EN O O O E 2 M M Ed D T EE EEB ER o 70000290000 1 8 3 75 l 31 68 76 13 78 65 105 35 120 58 145 99 TPAO OVNI E 959 al 2 m o Tv NO EZEJ VINO o 1925 mo ie oR2. w o c S 5 0 Pet TP32 aa 1 FE SER EE 2222 22 p ro 27 pes N E OE R269 c oP Le E t i CN26 BELI TP10 9T 3024 o CN25 TP4 CN19 CN20 E2385 1 o z SIE Des ES o o o 1 El o g 8 888 E a E C198 Call Ries 3l et IC13 El 2 5 o E EE E E 5 E E E EE m CN12 R61 860 J 160 ak 692 sm zm SW4 ml LED8 RIL LEDT R6 pH Lee 1 El C68 9 ol CN16 CN5 l TP6 aud d T 2552 E
3. Table 6 7 Option Link configuration for QSPI FLASH 6 1 7 CAN Channels Table 6 8 details the option links associated with the CAN interface MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove id Fit Remove CAN 5 10 B7 CAN CTX1 R206 R207 JA5 Pin5 CHANNEL 1 59 1 104 105 JA5 Pin6 CAN 73 J3 CAN CTX2 R174 R173 JA5 Pin7 CHANNEL 2 72 Hi CAN CRX2 R18 R4 JA5 Pin8 ES Table 6 8 Option Link configuration for CAN R20UT3007EG0200 Rev 2 00 RENESAS Page 35 of 53 May 17 2015 RSK RZA1H 6 1 8 Ethernet Table 6 9 details the option links associated with the Ethernet Functionality 6 Configuration MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove bcd Fit Remove 1 14 AA19 ET COL R270 R278 5 Pin3 R278 Ethernet R104 59 A7 ET MDC R105 R104 JA5 Pin6 R105 Table 6 9 Option Link configuration for Ethernet 6 1 9 USB Serial Table 6 10 details the option links associated with the USB Serial Interface MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove pc Fit Remove R177 4 14 019 G1C RTS R190 178 USB Serial R162 JA2 Pin23 R163 18 mee R163 JA2 B Pin23 R86 A Table 6 10 Option Link configuration for USB Serial 6 1 10 Tabl
4. D 5 i LENESAS RZ A1H Group Renesas Starter Kit User s Manual For e studio ASSAM RENESAS MCU Family RZ A1 Series All information contained in these materials including products and product specifications represents information on the product at the time of publication and is subject to change by Renesas Electronics Corporation without notice Please review the latest information published by Renesas Electronics Corporation through various means including the Renesas Electronics Corporation website http www renesas com Renesas Electronics www renesas com Rev 2 00 May 2015 10 11 12 Notice Descriptions of circuits software and other related information in this document are provided only to illustrate the operation of semiconductor products and application examples You are fully responsible for the incorporation of these circuits software and information in the design of your equipment Renesas Electronics assumes no responsibility for any losses incurred by you or third parties arising from the use of these circuits software or information Renesas Electronics has used reasonable care in preparing the information included in this document but Renesas Electronics does not warrant that such information is error free Renesas Electronics assumes no liability whatsoever for any damages incurred by you resulting from errors in or omissions from the information incl
5. RSK LS Host PC Figure 4 2 Debugger Connection Diagram R20UT3007EGO200 Rev 2 00 RENESAS Page 15 of 53 May 17 2015 RSK RZA1H 5 User Circuitry 5 User Circuitry 5 1 Potentiometer A single turn potentiometer RV1 is connected as a potential divider to analogue input AN7 P1_15 pin Y19 The potentiometer can be used to create a voltage between AVCC and AD_Ground The potentiometer is fitted to offer an easy method of supplying a variable analogue input to the microcontroller It does not necessarily reflect the accuracy of the controllers ADC Refer to the RZ A1H Group Hardware Manual for further details 5 2 Clock Circuit Clock circuits are fitted to the RSK to generate the required clock signals to drive the MCU and associated peripherals Refer to the RZ A1H Group Hardware Manual for details regarding the clock signal requirements and the RSK RZA1H board schematics for information regarding the clock circuitry in use on the RSK Details of the oscillators fitted to the board are listed in Table 5 1 below Crystal Oscillator Function Default Placement Frequency Device Package OSC2 Main MCU oscillator Fitted 13 333MHz SOJ 4Pin OSC1 Audio oscillator Fitted 22 5792MHz TXC TD 2P5X2 OSC3 Video oscillator Fitted 27 000MHz QFN4 X6 RTC 1 clock Fitted 32 768kHz 506 X3 RTC 2 clock Fitted 4 000MHz HC 49 X4 USB Clock Fitted 48 000MHz FA 238 Table 5 1 Oscill
6. o mm 8 o pes En 529 En TP2 725 CN38 9vr eve CN39 CN17 er 1818 Tree EN e 281 IC31 HE 19 1 25 EM Om En 1C26 122 TEJ 8 21 E19 ima ama 8202 1012 9012 228 o E END s ede TOM Sore HE CN9 77 828 BI o TOT 62 5 3 o 5 g LEDO LEDI LED 1803 ae TP35 RIO R76 R8 RIS REO Rie 873 RIA Cs 3 1 9 9 NMI
7. Reserved 050002009 OxFO00 1FFF Cortex AS Private Area 0 000 0000 DAEFFEFEFF Reserved 92250000 OxES22 FFFF vO OxES20 0000 ESF FEF Reserved 958440090 OxES13 FFFF vO 0 810 0000 DAESOFFEFF Reserved 9 205 0000 0 804 NO 0 803 0000 UXESOZFFFF Reserved 9000 OxES01 FFFF 0 500 0000 DEIF FEEF Reserved 06050 9050 GU On Chip RAM Mirror Area 06000 0000 Ox5FFF FFFF SPI Channel 1 Mirror Area Ox5C00 0000 Ox5BFF FFFF QSPI Channel 0 Mirror Area 0x5800 0000 Q 57FF FFFF 55 Mirror Area 035400 0000 0453 FFFF CS4 Mirror Area 0 5000 0000 Ox4FFF FFFF CS3 Mirror Area Ox4C00 0000 Os4BFF FFFF CS2 Mirror Area 034800 0000 Ox47FF FFFF CS1 Mirror Area 024400 0000 FFFF CSO Mirror Area 024000 0000 Son QSPI Channel 1 4 QSPI Channel 0 54Mb Onboard NAND FLASH 54Mb C83 Space not useable if On board SDRAM is Active Onboard SDRAM 32Mb Onboard NOR FLASH 32M Upper Address Function Lower Address Ox3FFF FFFF WO Ox3FFF C000 GGFFEBFEF Reserved DasPEFCOOO s3FEF BFFF WO Ox3FEF A000 FEF Reserved 012040 0000 0x208F FFFF On Chip Large Capacity RAM 022002 0000 RSK Memory Ox2001FFFF On Chip data Retention RAM 0x2000 0000 OMFFF FFFF QSPI Channel 1 01000 0000 OxIBFF FFFF QSPI Channel 0 0x1800 0000 OFF FFFF css 0x1400 0000 OxIaFF FFFF cs4 0 000 0000 OOF FF FFFF
8. P6 3 D5 21 BD4 P6 4 A2 22 BD5 P6 5 C1 23 BD6 P6 6 D2 24 BD7 P6 7 01 25 BRD P7 8 K4 R155 26 BWR P7 5 J1 R146 27 BCS1 7 YA R227 28 BCS3 P7 1 H2 R164 29 BD8 P6 8 E3 30 BD9 P6 9 E2 31 BD10 P6 10 El 32 BD11 P6 11 F3 33 BD12 P6 12 G4 34 BD13 P6_13 F2 35 BD14 P6_14 F1 36 BD15 P6_15 G3 37 16 8 V2 38 BA17 P8 9 V3 39 18 P8 10 W2 40 19 P8 11 W3 41 20 12 Yi 42 BA21 P8 13 V4 43 22 14 Y2 44 BCKIO CKIO V1 45 BWAIT P1 13 Y18 46 BCKE P7 4 J2 R115 47 BWE1 DQMLU P7 7 K2 48 BWEO DQMLL P7 6 K3 49 BCAS P7 3 J3 R173 50 BRAS P7_2 H1 R20UT3007EGO200 Rev 2 00 May 17 2015 Table 7 3 Application Header JA3 Connections TENESAS Page 43 of 53 May 17 2015 RSK RZA1H 7 Headers Table 7 4 below lists the connections of the Misc Connector CN15 Misc Connector CN15 Pin Header Name MCU Link Pin Header Name MCU Link Port Pin Required Port Pin Required P2 11 E19 1 MISO4 Set PX1 EN1 2 BA23 P8 15 AA1 1 P2 10 B22 3 MOSI4 Set PX1 EN1 4 BA24 P9 0 AB2 1 2 8 D20 5 RSPCK4 Set PX1 EN1 6 BA25 P9 1 AA3 1 P2 9 C21 7 SSL40 Set PX1 EN1 8 P5B 10 P5 10 B7 R207 1 Table 7 4 Connector CN15 Connections
9. Table 6 3 Option Link configuration for SP DIF 6 1 3 SDRAM Table 6 4 details the option links associated with the SDRAM MCU Exclusive Function Header Connection Function Header Port Pin Signal Fit Remove Pin Fit Remove 73 J3 CAS SDRAM R173 R174 72 H1 RAS_SDRAM R4 R18 en SDRAM 7_5 J1 WR SDRAM R146 R158 ace 74 J2 CKE SDRAM R115 se m i Table 6 4 Option Link configuration for SDRAM R20UT3007EGO200 Rev 2 00 RENESAS Page 34 of 53 May 17 2015 RSK RZA1H 6 Configuration 6 1 4 NOR FLASH Table 6 5 details the option links associated with the NOR FLASH MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove Fit Remove NOR FLASH 78 K4 RD NOR R155 R159 JA2 Pin20 R159 Table 6 5 Option Link configuration for NOR FLASH 6 15 NAND FLASH Table 6 6 details the option links associated with the NAND FLASH MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove Fit Remove NAND FLASH 55 C10 FCE NAND R167 R168 e Table 6 6 Option Link configuration for NAND FLASH 6 1 6 QSPI FLASH Table 6 7 details the option links associated with the QSPI FLASH MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove kj Fit Remove QSPI FLASH 92 C8 SPBCLK 0 R373 R378
10. Note Default settings are shown in bold blue text MCU USB Signal Function Port Pin DPO Positive differential data signal DPO AA12 DMO Negative differential data signal DMO AB12 VBUSO Cable monitor pin VBUSINO Y12 USB PWR ENA VBUS power supply enable Port Expander 2 IO 5 See Table 5 4 USB OVR CURRENT Over current detection signal Port Expander 2 IO 4 See Table 5 4 Table 5 9 USBO Module MCU Connections Operation as USB Fit Connector CN6 Do Not Fit Connector CN8 Function Power from Connector CN6 Link JP11 pins 2 and 3 Fit Connector CN8 Do Not Fit Connector CN6 Operation as USB Host Power from RSK Link JP11 pins 1 and 2 Table 5 10 USBO Module Connector and Power Settings MCU USB Signal Function Port Pin DP1 Positive differential data signal DP1 AB11 DM1 Negative differential data signal DM1 AA11 VBUS1 Cable monitor pin VBUSIN1 Y11 USB_PWR_ENB VBUS power supply enable Port Expander 2 IO 6 See Table 5 4 USB_OVR_CURRENT Over current detection signal Port Expander 2 IO 4 See Table 5 4 Table 5 11 USB1 Module MCU Connections Operation as USB Host Fit Connector CN8 Power from RSK Do Not Fit Connector CN6 Link JP11 pins 1 and 2 Operation as USB Function Fit Connector 6 Power from Connector 6 Do Not Fit Connector CN8 Link JP11 pins 2 and 3 Table 5 12 USB1 Module Connecto
11. Table 7 5 below lists the connections of the application header JA5 Application Header JA5 JA5 B Pin Header Name MCU Link Pin Header Name MCU Link Port Pin Required Port Pin Required 1 AN4 P1 12 AB19 R307 2 OPEN 3 AN6 P1 14 19 R278 4 OPEN 5 CAN CTXI P5 10 B7 R206 6 CAN CRX1 P5 9 A7 R104 7 CAN CTX2 P7 3 J3 R174 8 CAN CRX2 P7 2 R18 9 IRQ4 P1 10 Y17 R193 10 IRQ5 P1 11 AA18 R189 11 OPEN 12 OPEN 13 TIOCOA P7 0 H4 R326 14 TIOCOB P7 1 H2 R181 15 OPEN 16 OPEN 17 18 19 P4 4 M21 P4 5 20 PWM2E Mux on IC30 20 PWM2F Mux on IC30 21 P4 6 L22 4 7 120 PWM2G Mux on IC30 22 PWM2H Mux on IC30 23 OPEN 24 OPEN Table 7 5 Application Header JA5 Connections R20UT3007EGO200 Rev 2 00 RENESAS Page 44 of 53 RSK RZA1H 7 Headers Table 7 6 below lists the connections of the application header JA6 Application Header JA6 JA6 B Pin Header Name MCU Link Pin Header Name MCU Link Port Pin Required Port Pin Required 1 OPEN 2 OPEN 3 OPEN 4 OPEN 5 6 7 8 9 TXD1 P4 12 H22 R309 10 OPEN 11 SCK1 P4 11 H19 R313 12 RXD1 P4_13 G21 R179 13 OPEN 14 OPEN 15 OPEN 16 OPEN 17 OPEN 18 OPEN 19 OPEN 20 OPEN 21 22 OPEN 23 OPEN 24 OPEN Table 7 6 Application Header JA6 Connections R20UT3007EG0200 Rev 2 00 RENESAS Page 45 of 53 May 17 2015 RSK RZA1H 8
12. are not guaranteed from the moment when power is supplied until the reset process is completed In a similar way the states of pins in a product that is reset by an on chip power on reset function are not guaranteed from the moment when power is supplied until the power reaches the level at which resetting has been specified Prohibition of Access to Reserved Addresses Access to reserved addresses is prohibited The reserved addresses are provided for the possible future expansion of functions Do not access these addresses the correct operation of LSI is not guaranteed if they are accessed Clock Signals After applying a reset only release the reset line after the operating clock signal has become stable When switching the clock signal during program execution wait until the target clock signal has stabilized When the clock signal is generated with an external resonator or from an external oscillator during a reset ensure that the reset line is only released after full stabilization of the clock signal Moreover when switching to a clock signal produced with an external resonator or by an external oscillator while program execution is in progress wait until the target clock signal is stable Differences between Products Before changing from one product to another i e to a product with a different part number confirm that the change will not lead to problems characteristics of an MPU or MCU in the same group
13. signals 14 P5 0 TXCLKOUTP LVDS Clock Positive Line 5 0 11 15 P5 1 TXCLKOUTM LVDS Clock Minus Line P5 1 B11 16 GROUND Isolates neighbouring pairs of data N A N A signals 17 BOARD VCC N A N A 18 GROUND N A N A 19 GROUND Used to configure the external display in N A N A 6 bit mode when pulled low 20 BOARD VCC This pin is used to display the image N A N A normal low signal inverse high signal Table 5 21 LVDS Connections 1 Enables writing to LVDS displays that have 8 bit data pairs This differential pair is not used since the RZ A1H device only has six differential LVDS data lines As a result the unused pins on the external display are wired so that the pair have constant opposing signals 3 3V and GROUND as required 2 This pin is the Mode signal on the external display It is configured low to signal to the display that it will be used in 6 bit mode 3 This pin must be pulled low or high on the external display board s design R20UT3007EG0200 Rev 2 00 May 17 2015 TENESAS Page 31 of 53 RSK RZA1H 5 20 Pin Multiplexing 5 User Circuitry The RSK uses multiplexing on various channels in order to increase the amount of available I O Table 5 22 Table 5 23 and Table 5 24 describe the signals being multiplexed and the signals that control them MCU Signal Routed to MCU Port Pin Signal PX1_EN1 High 1 EN1 Low
14. 7 SPBIO30 0 Hold IO 3 IC26 Device 0 P9 7 B5 P2 12 SPBIOO1 0 Serial Input IO 0 IC25 Device 1 P2 12 A21 P2 13 SPBIO11 0 Serial Output IO 1 C25 Device 1 P2 13 A20 P2 14 5 21 0 Write Protect IO 2 IC25 Device 1 P2 14 C18 P2 15 SPBIO31 0 IRQ1 Hold 1O 3 IC25 Device 1 P2 15 B19 R20UT3007EGO200 Rev 2 00 May 17 2015 Table 5 8 SPI Flash Connection TENESAS Page 19 of 53 RSK RZA1H 5 10 1 QSPI Modes of Operation 5 User Circuitry There are several modes of operation of the QSPI memory in conjunction with the serial memory controller in the RZ A1H MCU On the RSK board there are two QSPI memory devices attached to ports 0 and 1 of the Multi SPI controller s channel 0 Channel 1 is used for other functions SPI multi I O bus controller 1 26 Serial Flash 0 CS SCK SI 100 SO 101 Wit 102 HOLD 103 SPBMO0_0 SPBIOOO_0 i SPBMIO_0 SPBIO10_0 SPBIO20 0 i SPBIO30_0 1 25 Serial Flash 1 SI 100 SO 101 Wit 102 HOLD 103 PORT 1 SPBSSL 1 SPBCLK_1 SBBMO0 i SPBIOOO 1 PORTO SPBMIO 1 SPBIO10 1 i SPBIO20_1 i PSPBMOT T SPBIOOT Ti PORT 1 SPBMI1_1 SPBIO11_1 H SPBIO21 SPBIO31 Figure 5 1 RZ A1H SPI multi I O controller Each QSPI memory device can support one two or four simultaneous serial lines of I O Furthermore the controller allows each channel s ports to work in parallel providing up to eight s
15. CS3 0 0 00 0000 Ox0BFF FFFF CS2 0x0800 0000 Ox07FF FFFF 51 010400 0000 Ox03FF FFFF cso 00000 0000 QSPI Channel 1 64Mb QSPI Channel 0 64Mb Onboard NAND FLASH B4Mb C83 Space not useable if On board SDRAM is Active Onboard SDRAM 32Mb Onboard NOR FLASH 32Mb77 To enable SDRAM JP18 must be open and SW6 3 must be in the ON position CS0_MBOOT2 low To enable NOR FLASH JP18 must be shorted SW6 must be in the ON position CS0 MBBOOT low To enable QSPI JP18 must be shorted and SW6 s switches SW6 1 SW6 6 need to be set to OFF ON OFF ON ON ON Note that SDRAM and NOR FLASH cannot be enabled at the same time Device is 256MByte but only 64MByte is addressable Figure 8 1 RZ A1H Address Map On RSK Board R20UT3007EG0200 Rev 2 00 May 17 2015 12 N SAS Page 47 of 53 RSK RZA1H 9 Additional Information 9 Additional Information Technical Support For details on how to use e studio refer to the help file by opening e studio tion selecting Help gt Help Contents from the menu bar Welcome 7 Help Contents Search Dynamic Help For information about the RZ A1H series microcontrollers refer to the RZ A1H Group Hardware Manual For information about the RZ assembly language refer to the RZ Series Software Manual Technical Contact Details Please refer to the contact details listed in section 10 of the Quick Start
16. Electronics America Inc 2801 Scott Boulevard Santa Clara CA 95050 2549 U S A Tel 1 408 588 6000 Fax 1 408 588 6130 Renesas Electronics Canada Limited 01 Nicholson Road Newmarket Ontario L3Y 9C3 Canada 1 905 898 5441 Fax 1 905 898 3220 Renesas Electronics Europe Limited Dukes Meadow Millboard Road Bourne End Buckinghamshire SL8 U K el 44 1628 651 700 Fax 44 1628 651 804 Renesas Electronics Europe GmbH Arcadiastrasse 10 40472 D sseldorf Germany Tel 49 211 65030 Fax 49 211 6503 1327 Renesas Electronics China Co Ltd Room 1709 Quantum Plaza No 27 ZhiChunLu Haidian District Beijing 100191 P R China Tel 86 10 8235 1155 Fax 86 10 8235 7679 Renesas Electronics Shanghai Co Ltd Unit 301 Tower A Central Towers 555 LanGao Rd Putuo District Shanghai China 200333 el 86 21 2226 0888 Fax 86 21 2226 0999 Renesas Electronics Hong Kong Limited Unit 1601 1613 16 F Tower 2 Grand Century Place 193 Prince Edward Road West Mongkok Kowloon Hong Kong Tel 852 2886 9318 Fax 852 2886 9022 9044 Renesas Electronics Taiwan Co Ltd F No 363 Fu Shing North Road Taipei Taiwan Tel 886 2 8175 9600 Fax 886 2 8175 9670 Renesas Electronics Singapore Pte Ltd 80 Bendemeer Road Unit 06 02 Hyflux Innovation Centre Singapore 339949 Tel 65 6213 0200 Fax 65 6213 0300 Renesas Electronics Malaysia Sdn Bhd Unit 906 Block B Menara Amcorp A
17. P20 L21 P2 0 ETTXCLK ET TXCLK P2 0 100 P2 1 K22 P2 1 ETTXER ET TXER P2 1101 P22 Fa P22ETTIXN P211 P2 3 G20 P2 3 ETCRS ET CRS P2 1 P2 4 F19 P2 4 ETTXDO ET TXDO P2 1 104 P2 5 E22 P2 5 ETTXD1 ET TXD1 P2 1 105 P2 6 E20 P2 6 ETTXD2 ET TXD2 P2 1 106 P2 7 C22 P2 7 ETTXD3 ET TXD3 P2 1 107 P2 8 D20 P2 8 ETTRXDO RSPCK4 ET RXDO RSPCK4 P2 9 C21 P2 9 ETRXD1 SSL40 ET RXD1 SSL40 P2 10 B22 P2 10 ETRXD2 MOSI4 ET RXD2 MOSI4 P2 11 E19 P2 1 ETRXD3 MSO4 ET_RXD3 MSO 3 AA6 P3 3 ETMDIO SCICTS1 ET MDIO SIM RESET P3 4 Y5 P3 4 ETRXCLK SCISCKO ET RXCLK SIM CLK P3 5 4 P3 5 ETRXER SCITXDO ET RXER SIM TXD P3 6 AB3 6 ETRXDV SCIRXDO ET RXDV SIM RXD PX1_EN1 is connected to the MCU via port expander IC35 See section 5 5 for further details Table 5 22 Multiplexing for Signal PX1 EN1 IC29 MCU Signal Routed to MCU Port Pin Signal PX1_EN3 High PX1_EN3 Low P4 4 M21 P4 4 SSISCKO PWM2E PWM2E SSISCKO P4 5 M20 P4 5 SSIWSO PWM2F PWM2F SSIWSO P4 6 L22 P4 6 SSIRXDO PWM2G PWM2G SSIRXDO 4 7 L20 P4 7 SSITXDO PWM2H PWM2H SSITXDO PX1_EN3 is connected to the MCU via port expander IC35 See section 5 5 for further details Table 5 23 Multiplexing for Signal PX1 EN3 IC30 MCU Signal Routed to MCU Port Pin Signal PX1 High PX1_EN7 Low P8 10 W2 P8 10 A18 SGOUTO SGOUTO A18 P8 11 W3 P8 11 A19 SGOUTI SGOUT1 19 8_12 Vi P8 12 A20 SGOUT2 SGO
18. and is different from all other connectors on the RSK designs Details can be found in the Digilent Pmod Interface Specification Revision November 20 2011 Figure 5 9 Digilent PmodTM Compatible Header Pin Numbering Digilent Pmod Compatible Header Connections Pin Circuit Net Name MCU Pin Circuit Net Name MCU Port Pin Port Pin 1 PMOD1_CS P1_4 B17 7 PMOD_INT P1_3 A18 2 Port Expander 1 P11 14 MOSI1 P11 14 H3 8 PMOD1 RST IO 4 See section 5 5 3 P11 15 MISO1 P11 15 J4 9 PMOD PIN9 P4 15 F22 4 P11 12 RSPCK1 P11 12 G2 10 PMOD PIN10 P3 7 Y4 5 GROUND 11 GROUND 6 Board Vcc 12 Board Vcc Table 5 18 PMOD1 Header Connections Digilent Pmod Compatible Header Connections Pin Circuit Net Name MCU Pin Circuit Net Name MCU Port Pin Port Pin 1 PMOD2_CS P1_5 C16 7 PMOD_INT P1_3 A18 P11 14 MOSI1 P11 14 8 PMOD2 RST Port Expander 1 H3 IO 5 See section 5 5 3 P11 15 MISO1 P11 15 J4 9 PMOD PIN9 P4 15 F22 4 P11 12 RSPCK1 P11 12 G2 10 PMOD PIN10 P3 7 Y4 5 GROUND 11 GROUND 6 Board Vcc 12 Board Vcc Table 5 19 PMOD2 Header Connections R20UT3007EG0200 Rev 2 00 RENESAS Page 28 of 53 May 17 2015 RSK RZA1H 5 18 TFT LCD Panel Connector 5 User Circuitry A TFT display can connect to the RSK board via connector CN44 The signals route to the MCU via multiplexers IC37 and IC38 as described
19. but having a different part number may differ in terms of the internal memory capacity layout pattern and other factors which can affect the ranges of electrical characteristics such as characteristic values operating margins immunity to noise and amount of radiated noise When changing to a product with a different part number implement a system evaluation test for the given product How to Use This Manual 1 Purpose and Target Readers This manual is designed to provide the user with an understanding of the RSK hardware functionality and electrical characteristics It is intended for users designing sample code on the RSK platform using the many different incorporated peripheral devices The manual comprises of an overview of the capabilities of the RSK product but does not intend to be a guide to embedded programming or hardware design Further details regarding setting up the RSK and development environment can found in the tutorial manual Particular attention should be paid to the precautionary notes when using the manual These notes occur within the body of the text at the end of each section and in the Usage Notes section The revision history summarizes the locations of revisions and additions It does not list all revisions Refer to the text of the manual for details The following documents apply to the RZ A1HH Group Make sure to refer to the latest versions of these documents The newest versions o
20. on the RSK RZA1H board JP1 Enable SIM card 2 way communication or TX only Link Open 2 way communication enabled TXD and RXD connected to SIM TXD to SIM only JP3 Write protect NAND FLASH IC27 Jumper Position Link 1 2 Link 2 3 R233 Not Fitted NAND FLASH IC27 not write protected NAND FLASH 1 27 write protected Do NOT short pins 2 and 3 of JP3 when R233 is fitted which is default configuration JP4 MCU Core Current Measurement Remove R24 and short JP4 with meter to measure MCU core current JP5 Disable Ethernet MAC EEPROM write protection IC11 Link open EEPROM IC11 write unprotected EEPROM IC11 write protected JP6 MCU Port Pins Current Measurement Remove R26 and short JP6 with meter to measure MCU port pin current JP11 USB VBUS power select Link 1 2 Link 2 3 BOARD 5V VBUS JP12 USB VBUS1 power select Link 1 2 Link 2 3 BOARD 5V Power from connector CN9 pin1 VBUS1 JP18 NOR Flash Chip Enable Link Open NOR Flash active on CSO NOR Flash inactive JP21 Defining Function of BSCANP pin on RZ A1H MCU MCU Jumper Position Port Pin linked open Normal Operation Boundary Scan e ABER Pin held low Pin pulled up to BOARD VCC via R264 22K resistor PWR SEL Select Input power voltage setting Link 1 2 Link 2 3 12V 5V Do NOT connect a 12V input source to the RSK when PWR SEL j
21. which resetting has been specified 3 Prohibition of Access to Reserved Addresses Access to reserved addresses is prohibited The reserved addresses are provided for the possible future expansion of functions Do not access these addresses the correct operation of LSI is not guaranteed if they are accessed 4 Clock Signals After applying a reset only release the reset line after the operating clock signal has become stable When switching the clock signal during program execution wait until the target clock signal has stabilized When the clock signal is generated with an external resonator or from an external oscillator during a reset ensure that the reset line is only released after full stabilization of the clock signal Moreover when switching to a clock signal produced with an external resonator or by an external oscillator while program execution is in progress wait until the target clock signal is stable 5 Differences between Products Before changing from one product to another i e to a product with a different part number confirm that the change will not lead to problems The characteristics of an MPU or MCU in the same group but having a different part number may differ in terms of the internal memory capacity layout pattern and other factors which can affect the ranges of electrical characteristics such as characteristic values operating margins immunity to noise and amount of radiated noise When c
22. 2 PC go to Start gt Control Panel Device Manager Go to the Ports COM 8 LPT section and the COM port should be listed there To verify the correct port the USB cable can be disconnected and re connected to show the COM port appearing and disappearing Ey Device Manager l mj lo File Action View 24 7365 3 Batteries 1 Computer Disk drives E Display adapters Aj DVD CD ROM drives Human Interface Devices IDE ATA ATAPI controllers Keyboards n Mice and other pointing devices Modems Monitors A Network adapters P Ports COM amp LPT 9 Communications Port COMI YD ECP Printer Port LPT1 n RSK USB Serial Port COM3 D Processors Xj Sound video and game controllers jS System devices Universal Serial Bus controllers Figure 5 5 Device Manager Ports R20UT3007EG0200 Rev 2 00 RENESAS Page 25 of 53 May 17 2015 RSK RZA1H User Circuitry 5 16 2 Changing the Virtual COM Port Number Some PC applications will only work with particular COM port numbers COM port numbers for the RSK serial USB are assigned automatically at the time of first connection to the PC It is possible to assign a different value manually The procedure to do this is as follows 1 Right click the USB Serial port in device manager and select Properties Ey Device Manager File
23. 2 Byte8 Byte4 Serial Flash 1 PORT 1 NOT ACCESSED Dual Channel Mode Serial Flash 0 8 Byte9 Byte1 PORTO BytelO 2 c Byte11 Byte3 Byte12 Byte4 Serial Flash 1 Byte13 Byte5 PORTA E Bytel4 Byte6 Byte15 Byte7 Byte16 Byte8 Figure 5 3 Memory access of Single and Dual Mode QSPI Operation The consequence of this is that data stored in QSPI FLASH needs to be accessed in the same manner as it has been programmed in If data is accessed in Single QSPI mode when it has been programmed in Dual QSPI mode then every fourth group of four bytes will be missing Conversely data accessed in Dual Channel mode when it has been programmed in Single Channel mode will have blocks of four bytes from the other port inserted between every fourth byte of correct data R20UT3007EGO200 Rev 2 00 May 17 2015 TENESAS Page 21 of 53 RSK RZA1H 5 User Circuitry 511 Universal Serial Bus USB This RSK board is fitted with two channels of USB Each channel can operate as either a host or as a function device Channel 0 is by default configured as USB Function and the connector and jumper link settings for the channel 0 power supply are shown in Table 5 10 Channel 1 is by default configured as USB Host and the connector and jumper link settings for the Channel 1 power supply are shown in Table 5 12 The signal connections to the MCU for Channel 0 and Channel 1 are detailed in Table 5 9 and Table 5 11 respectively
24. 6 Green Ethernet Indication These LEDs are connected to port expander IC34 s I O pin See section 5 5 for further details Table 5 15 LED Connections 514 Reset Circuit A reset control circuit is fitted to the RSK to generate the required reset signal and is triggered from the RES switch power supply monitor and debugger connection Refer to the RZ A1H hardware manual for details regarding the reset signal timing requirements and the RSK schematics for information regarding the reset circuitry in use on the board 5 15 Audio The RSK board provides audio input via a 3 5mm Stereo jack CN19 and audio output via 3 5mm stereo jack CN20 It also incorporates an audio codec device IC14 which is linked to the MCU the signals described in Table 5 16 Signal Function Port Pin SCL3 Clock Line 1_6 17 SDA3 Serial Data Line P1_7 B16 IRQ_AUDIO Hardware IRQ P3_1 AA7 SSIWSO Digital Audio Left Right Clock IO P4_5 M20 SSISCKO Digital Audio Bit Clock P4 47 M21 SSIRXDO Digital Audio Serial Data ADC Output P4 6 122 SSITXDO Digital Audio Serial Data DAC Input 4_7 120 Connection to ports via multiplexer IC30 See section 5 20 for more details Table 5 16 Audio Codec Connections R20UT3007EG0200 Rev 2 00 RENESAS Page 24 of 53 May 17 2015 RSK RZA1H 5 User Circuitry 5 16 USB Serial Port A USB serial port implemented in another Renesas low power microcontroller RL
25. 78 G1C is fitted on the RSK to the microcontroller Serial Communications Interface SCI module Multiple options are provided to allow re use of the serial interface Connections between the USB to Serial converter and the microcontroller are listed in Table 5 17 below Signal Name Function MCU Port Pin P3 0 TXD2 External SCI Transmit Signal P3_0 AB6 P3 2 RXD2 External SCI Receive Signal 2 Y7 G1C_CTS Clear To Send P1_8 AA17 G1C RTS Request to Send P4 14 G19 Table 5 17 Serial Port Connections When the RSK is first connected to a PC running Windows with the USB Serial connection the PC will look for a driver This driver is installed during the installation process so the PC should be able to find it The PC will report that it is installing for a driver and then report that a driver has been installed successfully as shown in Figure 5 4 The exact messages may vary depending upon operating system r Installing device driver software RSK USB Serial Port COM3 X Click here for status FF E Device driver software installed successfully Figure 5 4 USB Serial Windows Installation message 5 16 1 Reading the Virtual COM Port Number In order for the PC to be able to communicate with the RSK board via the USB virtual COM port the correct COM port number must be determined If the COM port number is not known follow this process 1 Connect the PC to the serial USB port
26. Action View ay 7365 Y Batteries 1 Computer va Disk drives E Display adapters i DVD CD ROM drives 95 Human Interface Devices IDE ATA ATAPI controllers Keyboards n Mice and other pointing devices Modems K Monitors XY Network adapters EI Portable Devices a Ports COM amp LPT YP Communications Port COM1 77 ECP Printer Port LPTI 27 RSK USB Serial Port COM3 511869112 NNE Processors Sound video and game contro System devices Universal Serial Bus controllers Opens property s Figure 5 6 Device Manager Port Properties 2 Select the Port Settings tab and click Advanced Update Driver Software Disable Uninstall Scan for hardware changes Properties RSK USB Serial Port COM3 Properties 27 General Port Settings Driver Details Bits per second 115200 gt Data bits 8 Parity None Stop bits 1 Flow control None Advanced Restore Defaults Cancel Figure 5 7 Device Manager Port Settings R20UT3007EG0200 Rev 2 00 May 17 2015 TENESAS Page 26 of 53 RSK RZA1H 5 User Circuitry 3 Select the new COM port from the drop down list Bear in mind that the in use label on various ports listed may not actually mean that port is in use at this cu
27. CU via a multiplexer IC IC29 Set Signal PX1 High to connect these signals to the MCU See section 5 20 for further details of the multiplexing on the RSK board Table 5 13 Ethernet Connection A 2KByte EEPROM is fitted in order to store the MAC address for the Ethernet connection This can be accessed via channel 3 with address OxAO Connection details are described in Table 5 14 below csi MCU ignal Function Port Pin SDA3 Serial Data Line P1_7 B16 SCL3 Clock Line 1 6 17 Table 5 14 EEPROM Connection Channel 3 There is an eight way configuration DIP switch SW4 which is used to determine Ethernet settings on the RSK board Refer to section 6 3 for further details R20UT3007EG0200 Rev 2 00 May 17 2015 TENESAS Page 23 of 53 RSK RZA1H 5 User Circuitry 5 13 LEDs There are ten LEDs on the RSK The function of each LED its colour and connection are shown in Table 5 15 LED Colour Function MCU Port Pin POWER_IN Green Indicates the status of the power connected to CN4 POWER Green Indicates the status of the BOARD_5V 5V power rail POWER Green Indicates the status of the BOARD_VCC 3 3V power rail LEDO Green User operated LED P7_1 H2 LED1 Orange User operated LED Li LED2 Red User operated LED i LED3 Red User operated LED LED4 Yellow Ethernet Indication LED5 Green Ethernet Indication LED
28. Code Development 8 Code Development 8 1 Overview For all code debugging using Renesas software tools the RSK board must be connected to a PC via Segger JLink Lite debugger which is supplied with this RSK product 8 2 Mode Support The RZ A1H microcontroller supports five boot modes which includes booting from memory connected to the CSO space serial flash memory the NAND flash memory with an SD controller and the NAND flash memory with an MMC controller 8 3 Compiler Restrictions The version of the compiler provided with this RSK is a fully functional GNU compiler used in RSK RZA1H sample projects Support for the GNU NONE Compiler is available from http www kpitgnutools com 8 4 Debugger Support The RSK board is supplied with a Segger JLink Lite Debugger Please refer to the Segger website for further information www segger com R20UT3007EG0200 Rev 2 00 RENESAS Page 46 of 53 May 17 2015 RSK RZA1H 8 Code Development 8 5 Address Space Figure 8 1 below details the address space of the MCU This diagram is based on the Hardware Manual version 1 0 For further details refer to the RZ A1H Group Hardware Manual Upper Address Function Lower Address OxFFFF FFFF OxFFFF 0000 OXFFFEFFFF Reserved feFLODODOG FFFF OxFCFF 0000 RSK Memory OXFCFE FFFF vO OxF CFE 0000 DAFCEDFFFF Reserved 0 7008 0000 OXFCOTFFFF WO 0000
29. Guide General information on Renesas Microcontrollers can be found on the Renesas website at http www renesas com Trademarks All brand or product names used in this manual are trademarks or registered trademarks of their respective companies or organisations Copyright This document may be wholly or partially subject to change without notice All rights reserved Duplication of this document either in whole or part is prohibited without the written permission of Renesas Electronics Europe Limited 2014 Renesas Electronics Europe Limited All rights reserved 2014 Renesas Electronics Corporation All rights reserved 2014 Renesas Solutions Corp All rights reserved R20UT3007EG0200 Rev 2 00 RENESAS Page 48 of 53 May 17 2015 10 Appendix A Component Layout and Board Dimensions For the following renderings the following statements are true Board dimensions and connector positions All the through hole connectors are on a common 0 1 inch grid for easy interfacing Component placement of individual components on the top side PCB Component placement of individual components on the underside of the PCB
30. I chip is from channel 0 P4_10 to P4_15 in this mode Not supported on RSK 1 1 1 ki Boot mode 5 eMMC booting OFF OFF OFF Boots the LSI from the NAND flash memory with the MMC controller The only way of booting this LSI chip is from channel 0 P3 10to P3 15 in this mode Uses NAND flash 27 Table 6 20 MCU Boot Modes Note that it is not possible to boot from an SD card that is connected to the SD MMC connector CN1 This is because the connector utilises channel 1 of the SD controller which can only boot from channel 0 For further information refer to the hardware manual Table 3 1 note column order is transposed cf Table 6 20 SW6 4 Clock Signal Source ON EXTAL Uses OSC2 13 33MHz OFF USB 1 Uses X4 48MHz Table 6 21 Clock Signal Source SW6 5 Spread Spectrum Clock Generator SSCG Mode ON Enables the SSCG function of the MCU s internal PLL circuit This function attempts to reduce EMI peak levels by slightly modulating the output frequency OFF Disables the SSCG function Table 6 22 Spread Spectrum Clock Generator SSCG Mode SW6 6 is for test purposes only default is ON R20UT3007EGO200 Rev 2 00 May 17 2015 TENESAS Page 41 of 53 RSK RZA1H 7 Headers 7 Headers 7 1 Application Headers This RSK is fitted with application headers which can be used to connect compatible Renesas application devices or as easy access to MCU pins The following tables provide details of the pin connectio
31. NOR Flash IC23 connected to the address data buses Note that the SDRAM as fitted on the RSK board is configured in hardware to use the Chip Select line CS2 The BSC module within the RZ A1H MCU assumes a second SDRAM device will be connected also to CS3 As such it is necessary that the BSC within the RZ A1H MCU is configured to use both CS2 and CS3 as SDRAM even though a second SDRAM is not present on CS3 and that CS3 is not used on the expansion headers As such option link R164 must NOT be fitted to prevent bus conflicts By default this link is not fitted as this port pin is configured for LEDO For other external memory mapped devices chip select CS1 remains available for use This is a known limitation of the RSK board For new applications with only one SDRAM it is recommended to connect the SDRAM to CS3 which will allow single SDRAM use without issue See the hardware manual Bus State Controller section 8 4 3 CS2WCR SDRAM p171 for further details Note that the NOR Flash is configured to operate on the bus control line CSO In order for this to operate Jumper link JP18 and resistor link R314 fitted as default must be connected Refer to the RSK RZA1H board schematics for further information R20UT3007EG0200 Rev 2 00 RENESAS Page 18 of 53 May 17 2015 RSK RZA1H 5 User Circuitry 5 9 NAND Flash The connections of the NAND FLASH are detailed in Table 5 7 Signal Fu
32. S wo ED 085 esta SER TED Lea gt ES 1 MERO 255 TD Essa TEM EN 1521 gt 2 en ERE 1 o i ag HBH 2 UN a E olo E le 13 EM pg TFE m o gre 3 30 888 aN 2 E E E ES 2 E 4 dH Ba 5 i 8 esr TLO Gs B B o 0555 E eii AE stor 8 EAU E o rm ESOS AUD exar EO TEM E REVISION HISTORY RSK RZ A1H User s Manual Rev 1 00 Oct 06 2014 2 00 May 17 2015 3 2 5 16 Description Summary First Edition issued Improved Image quality minor corrections Renesas Starter Kit Manual User s Manual Publication Date Rev 2 00 May 17 2015 Published by Renesas Electronics Corporation LENESAS SALES OFFICES Renesas Electronics Corporation http www renesas com Refer to http www renesas com for the latest and detailed information Renesas
33. UT2 A20 P8 13 V4 P8_13_A21_SGOUT3 SGOUT3 A21 PX1_EN7 is connected to the MCU via port expander IC35 See section 5 5 for further details R20UT3007EGO200 Rev 2 00 May 17 2015 Table 5 24 Multiplexing for Signal PX1_EN7 IC20 TENESAS Page 32 of 53 RSK RZA1H 6 Configuration 6 Configuration 6 1 Modifying the RSK This section lists the option links that are used to modify the way RSK operates in order to access different configurations Configurations are made by modifying link resistors or headers with movable jumpers Table 6 1 below shows the RSK RZ A1H default configuration with respect to the peripheral functionality Bold blue text indicates the default configuration that the RSK is supplied with It is noted that certain peripheral functions are disabled by default as shown in Table 6 1 in the column entitled Secondary Function It is possible to activate these disabled peripherals but at the expense of the default peripheral functions as shown in the Table Refer to the sections cited in the Table in order to perform any required modifications When removing soldered components always ensure that the RSK is not exposed to a soldering iron for intervals greater than five seconds This is to avoid damage to nearby components mounted on the board When modifying a link resistor always check the related option links to ensure there is no possible signal contention or short circuits Because many of
34. ake ESD precautions when handling the equipment The Renesas Starter Kit does not represent an ideal reference design for an end product and does not fulfil the regulatory standards for an end product General Precautions in the Handling of MPU MCU Products The following usage notes are applicable to all MPU MCU products from Renesas For detailed usage notes on the products covered by this document refer to the relevant sections of the document as well as any technical updates that have been issued for the products Handling of Unused Pins Handle unused pins in accord with the directions given under Handling of Unused Pins in the manual input pins of CMOS products are generally in the high impedance state In operation with an unused pin in the open circuit state extra electromagnetic noise is induced in the vicinity of LSI an associated shoot through current flows internally and malfunctions occur due to the false recognition of the pin state as an input signal become possible Unused pins should be handled as described under Handling of Unused Pins in the manual Processing at Power on The state of the product is undefined at the moment when power is supplied states of internal circuits in the LSI are indeterminate and the states of register settings and pins are undefined at the moment when power is supplied In a finished product where the reset signal is applied to the external reset pin the states of pins
35. are not subject to radiation resistance design Please be sure to implement safety measures to guard them against the possibility of physical injury and injury or damage caused by fire in the event of the failure of a Renesas Electronics product such as safety design for hardware and software including but not limited to redundancy fire control and malfunction prevention appropriate treatment for aging degradation or any other appropriate measures Because the evaluation of microcomputer software alone is very difficult please evaluate the safety of the final products or systems manufactured by you Please contact a Renesas Electronics sales office for details as to environmental matters such as the environmental compatibility of each Renesas Electronics product Please use Renesas Electronics products in compliance with all applicable laws and regulations that regulate the inclusion or use of controlled substances including without limitation the EU RoHS Directive Renesas Electronics assumes no liability for damages or losses occurring as a result of your noncompliance with applicable laws and regulations Renesas Electronics products and technology may not be used for or incorporated into any products or systems whose manufacture use or sale is prohibited under any applicable domestic or foreign laws or regulations You should not use Renesas Electronics products or technology described in this document for any purpose relating to military applic
36. associated with SD card connector CN2 Note that the SD card connector CN2 is not fitted as standard MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove pc Fit Remove 4 9 K21 SD WP EXT R290 e CN2 Pin2 R290 R289 48 K20 SD CD EXT R306 R300 CN2 Pin3 R306 4 13 G21 SD CMD EXT R180 R179 CN2 Pin4 R180 4 12 H22 SD CLK EXT R311 R309 CN2 Pin5 R311 SD Card 4 11 H19 SD DO EXT R315 R313 CN2 Pin6 R315 4 10 J22 SD D1 EXT R294 R293 CN2 Pin7 R294 4 15 F22 SD D2 EXT R176 R175 CN2 Pin8 R176 R177 4 14 G19 SD D3 EXT R178 R190 CN2 Pin9 R178 Table 6 15 Option Link configuration for SD Card CN2 R20UT3007EG0200 Rev 2 00 ESAS Page 38 of 53 May 17 2015 RSK RZA1H 6 Configuration 6 2 Power Supply Configuration Power to the RSK RZA1H board should be applied to connector CN5 from a 5mm diameter centre positive plug at either 5Vdc or 12Vdc The header PWR_SEL is used to select operation from a 12V or 5V supply It is essential that if a 12V supply is used that PWR_SEL is NOT linked on pins 2 3 or an overvoltage will be applied to the MCU and associated devices resulting in likely destruction of the whole board Table 6 16 describes the jumper settings for the PWR_SEL header PWR_SEL Select Input power voltage setting Link 1 2 Link 2 3 12V supply 5V supply Do NOT connect a 12V input so
37. ations or use by the military including but not limited to the development of weapons of mass destruction When exporting the Renesas Electronics products or technology described in this document you should comply with the applicable export control laws and regulations and follow the procedures required by such laws and regulations It is the responsibility of the buyer or distributor of Renesas Electronics products who distributes disposes of or otherwise places the product with a third party to notify such third party in advance of the contents and conditions set forth in this document Renesas Electronics assumes no responsibility for any losses incurred by you or third parties as a result of unauthorized use of Renesas Electronics products This document may not be reproduced or duplicated in any form in whole or in part without prior written consent of Renesas Electronics Please contact a Renesas Electronics sales office if you have any questions regarding the information contained in this document or Renesas Electronics products or if you have any other inquiries Note 1 Renesas Electronics as used in this document means Renesas Electronics Corporation and also includes its majority owned subsidiaries Note 2 Renesas Electronics product s means any product developed or manufactured by or for Renesas Electronics 2012 4 General Precautions in the Handling of MPU MCU Products The following usage notes are appl
38. ators 5 3 RCA Video Input The RSK board provides two channels of RCA video input to the RZ A1H MCU on connectors CN38 and CN39 These connect to the RSK RZA1H MCU on pins VIN1A B15 and VIN2A A15 respectively via 100nF decoupling capacitors Refer to the RSK RZA1H board schematics for further information 5 4 Switches There are five switches located on the RSK board The function of each switch and its connection is shown in Table 5 2 For further information regarding switch connectivity refer to the RSK RZA1H schematics Switch Function Sen Port Pin RES When pressed the microcontroller is reset RESA Y8 SW1 Connects to an IRQ input for user controls IRQ3 P1 9 AB18 SW2 Connecis to an IRQ input for user controls IRQ2 P1 8 AA17 SW3 Connects to an IRQ input for user controls IRQ5 P1_11 AA18 NMI Connects to the non maskable input for user controls NMI Y9 Table 5 2 Switch Connections R20UT3007EG0200 Rev 2 00 ESAS Page 16 of 53 May 17 2015 RSK RZA1H 5 User Circuitry 5 5 Port Expander The RSK board utilises two port expander ICs IC34 and IC35 in order to provide more I O signals These devices are the CAT9554 from On Semiconductor For further information on these devices visit the On Semiconductor website at www onsemi com The port expanders provide 8 parallel I O lines each which can be accessed via an l C SMBus serial connection On the RSK board they are able t
39. by Table 5 20 Refer to the schematic for further information Connector i MCU CN44 Pin Signal Port 1 P11 7 LCDODATAO 7 M3 2 P11 6 LCDODATA1 Pili 6 M2 3 P11 5 LCDODATA2 11_5 Li 4 P11 4 LCDODATA3 4 L4 5 P11 3 LCDODATA4 3 C5 6 P11 2 LCDODATAS 2 B4 7 P11 1 LCDODATAG 1 6 8 P11 0 LCDODATA7 P11 0 A4 9 P10 15 LCDODATA8 P10 15 D21 10 P10 14 LCDODATA9 P10 14 D22 11 P10 13 LCDODATA10 P10 13 F20 12 P10 12 LCDODATA11 P10 12 E21 13 P10 11 LCDODATA12 P10 11 H20 14 P10 10 LCDODATA13 P10 10 H21 15 P10 9 LCDODATA14 P10 9 J20 16 P10 8 LCDODATA15 P10 8 J21 17 P10 7 LCDODATA16 P10 7 M22 18 P10 6 LCDODATA17 P10 6 N21 19 P10 5 LCDODATA18 P10 5 N20 20 P10 4 LCDODATA19 P10 4 N19 21 P10 3 LCDODATA20 P10 3 AB5 22 P10 2 LCDODATA21 P10 2 Y6 23 P10 1 LCDODATA22 P10 1 AA5 24 P10 0 LCDODATA23 P10 0 AB4 25 RESET2 N Connected to reset circuit 26 P11 15 LCDOCLK P11 15 J4 27 12 LCDOTCON2 P11_12 G2 28 P11_11_LCDOTCON3 11 U3 29 P11_10_LCDOTCON4 P11_10 T3 30 P11_13_LCDOTCON1 P11_13 G1 31 P11 14 LCDOTCONO P11 14 H3 32 P11 9 LCDOTCON5 P11 9 T2 33 P11 8 LCDOTCONG P11 8 T1 34 BL PWM CTRL P3 1 IRQ6 R20UT3007EGO200 Rev 2 00 May 17 2015 Table 5 20 TFT Signal Connections RENESAS Page 29 of 53 User Circuitry RSK RZA1H 5 Connector i MCU CN44 Pin Sig
40. c if required with appropriate changes to jumper settings as detailed in Table 2 1 Ensure to check the three pin PWR_SEL jumper settings prior to connecting the power supply Details of the power supply requirements for the RSK and configuration are shown in Table 2 1 below The default RSK power configuration is shown in bold blue text It is essential that if a 12V supply is used that PWR_SEL is NOT linked on pins 2 3 or an overvoltage will be applied to the MCU and associated devices resulting in likely destruction of the whole board CN5 Setting PWR SEL Setting Regulator IC Output IC Voltage Power Name Pint2shoted 5 Bv IC4 3 3V BOARD IC21 1 18V CORE 5V Pin2 3 shorted IC36 3 3V AVREF Table 2 1 Main Power Supply Requirements The main power supply connected to PWR1 should supply a minimum of 5W to ensure full functionality When designing an RZ A1H MCU into a new board it should be noted that if the 3 3V supply is valid and the 1 18V core supply is not then MCU input and output ports will be in an undefined state until the 1 18V core supply is valid When designing the MCU power sequencing during board hardware design it is strongly advised to ensure that the 1 18V supply is valid before the 3 3V The 1 18V core supply on the RSK RZA1H board is valid before the 3 3V supply so on the RSK RZA1H the input output ports remain in a
41. defined state during the power up period 2 2 Power Up Behaviour When the RSK is purchased the RSK board has the Release or stand alone code from the example tutorial software pre programmed into the Renesas microcontroller On powering up the board the LEDs will start to flash After 200 flashes or after pressing any switch the text on the LCD display will change and the LEDO will begin to flash at a rate controlled by the potentiometer R20UT3007EGO200 Rev 2 00 RENESAS Page 11 of 53 May 17 2015 RSK RZA1H 4 Connectivity 3 Board Layout 3 1 Component Layout Figure 3 1 below shows the top component layout of the board Reset Switch Video In USBO Host USB1 Host Pmod2 Application Headers ARM JTAG CORESIGHT gt a RZIA1H CAN1 2 c Audio Out ovr 5 USB Serial v 5 t lt g o User LEDs PWR SEL SWANS Power Jack Em um m lob dof dof dof User Switches NMI Switch Potentiometer Figure 3 1 Board Layout R20UT3007EG0200 Rev 2 00 RENESAS Page 12 of 53 May 17 2015 RSK RZA1H 4 Connectivity 3 2 Board Dimensions See Appendix A R20UT3007EG0200 Rev 2 00 TEN ESAS Page 13 of 53 May 17 2015 RSK RZA1H 4 Connectivity 4 Connectivity 4 1 Internal RSK Connections The diagram below shows the RSK board components and their connectivity to the MCU PMOD interface 2 channels Audio CODEC USB Serial Int
42. e 6 11 details the option links associated with the TFT display connection MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove gc Fit Remove R289 4_9 21 TP INT R384 R290 11 C17 SDAO R302 R304 Table 6 11 Option Link configuration for R20UT3007EG0200 Rev 2 00 ESAS Page 36 of 53 May 17 2015 RSK RZA1H 6 Configuration 6 1 11 Audio Codec Table 6 12 details the option links associated with the Audio Codec MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove i Fit Remove R107 Audio 31 7 IRQ AUDIO R106 R186 La LINEIN1 R129 R130 CN19 Pin2 Audio line Tr LINEIN2 R131 R132 CN19Pin3 JACKSNS R323 R324 MICL R130 R129 CN19 2 Audio em mann pana ruangm o u Mic In E MICR R132 R131 CN19Pin3 JACKSNS R324 R323 ES io Audio HPR R133 R134 CN20 Pin3 o p m HPL R135 R136 CN20 Pin2 a M Audio LOUTR R134 R133 CN20 Pin3 Line Out LOUTL R136 R135 CN20 Pin2 aus a Audio Input MICGND R319 R320 CN20 Pint R319 R320 Gnd AUDIO GND 8320 19 CN20 Pint R320 R319 T Via 1uF Decoupling Capacitor Table 6 12 Option Link configuration for th
43. e Audio Codec 6 1 12 LVDS Table 6 13 details the option links associated with the LVDS functionality MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove dead Fit Remove LVDS 56 A9 P5 6 TXOUTOP R170 R169 CN17 Pine R170 R169 Channel 0 57 B9 P5 7 TXOUTOM R182 R183 CN17 Pins R182 R183 LVDS 54 11 P5 4 TXOUTIP_X R432 des CN17 Ping R432 Channel 1 55 Ci0 P5 5 TXOUTIM R168 R167 CN17Pin8 R168 R167 Table 6 13 Option Link configuration for LVDS R20UT3007EG0200 Rev 2 00 RENESAS Page 37 of 53 May 17 2015 RSK RZA1H 6 Configuration 6 1 13 Pmod Interfaces Table 6 14 details the option links associated with the Pmod Interfaces MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove peus Fit Remove R227 CN25 Pin10 3 7 Y4 PMOD PIN10 R171 R144 CN26 Pin10 R171 14 B17 PMOD1 CS R301 CN25 Pin1 R301 PMOD1 CN25 Pind 4 15 F22 PMOD PIN9 R175 R176 CN26 Ping R175 CN25 Pin7 13 A18 PMOD INT R305 R247 CN26 Pin7 R305 R227 CN25 Pin10 37 Y4 PMOD_PIN10 R171 R144 CN26 Pin10 R171 15 C16 PMOD2 CS R303 CN26 Pin1 R303 PMOD2 CN25 Pin9 4 15 F22 PMOD PIN9 R175 R176 CN26 Pind R175 CN25 Pin7 13 A18 PMOD INT R305 R247 CN26 Pin7 R305 Table 6 14 Option Link configuration for PMOD 6 1 14 50 Card Table 6 11 details the option links
44. eparation distance should be used between this and any sensitive equipment Its use outside the laboratory classroom study area or similar such area invalidates conformity with the protection requirements of the Electromagnetic Compatibility Directive and could lead to prosecution The product generates uses and can radiate radio frequency energy and may cause harmful interference to radio communications However there is no guarantee that interference will not occur in a particular installation If this equipment causes harmful interference to radio or television reception which can be determined by turning the equipment off or on you are encouraged to try to correct the interference by one or more of the following measures e ensure attached cables do not lie across the equipment e reorient the receiving antenna e increase the distance between the equipment and the receiver e connect the equipment into an outlet on a circuit different from that which the receiver is connected e power down the equipment when not in use e consult the dealer or an experienced radio TV technician for help NOTE It is recommended that wherever possible shielded interface cables are used The product is potentially susceptible to certain EMC phenomena To mitigate against them it is recommended that the following measures be undertaken e The user is advised that mobile phones should not be used within 10m of the product when in use e The user is advised to t
45. erface SDRAM 4x User LEDs PORTS 64MB 512Mb 3x Power LE Ds NOR Flash 64MB 512Mb SDCARD Slot MMCCARD Slot NAND Flash 256MB 2Gb QSPI Flash 128MB 1 iili NAND EEPROM 3 R 16kB Composite Video Fiters CVin lIC Ethemet MAC Storage 2x Channels CAN 2 channels USB 1xHost Function Digital video Connector aii ee MIL xFunction Hosi 8 or 16 bit possible default as Function Selected 8 bit Ethernet SIM Gard las sja LVDS Pads Only Not fitted LVDS LVDS CMOS Camera Interface ius HDMI Connector Only No Camera Debugger JLINK SSI Interface 20pin ULINK2 Pin header only 20pin ETM External display Panel SPDIF 7 Projective Capacitive touch 800 X 480 Figure 4 1 Internal RSK Block Diagram R20UT3007EG0200 Rev 2 00 RENESAS Page 14 of 53 May 17 2015 RSK RZA1H 4 Connectivity 4 2 Debugger Connections The diagram below shows the connections between the RSK SEGGER JLink Lite debugger and the host PC User Interface n i Cable USB Cable a 8 i SEGGER mag Jlink Lite
46. f the documents listed may be obtained from the Renesas Electronics Web site Document Type Description Document Title Document No User s Manual Describes the technical details of the RSK hardware RSK RZA1H R20UT3007EG User s Manual Tutorial Manual Provides a guide to setting up RSK environment RSK RZ A1H R20UT3008EG running sample code and debugging programs Tutorial Manual Quick Start Guide Provides simple instructions to setup the RSK and RSK RZA1H R20UT3006EG run the first sample on a single A4 sheet Quick Start Guide Schematics Full detail circuit schematics of the RSK RSK RZA1H R20UT2586EG Schematics Hardware Manual Provides technical details of the RZ A1H RZ A1HH Group RO1UH0403EJ microcontroller User s Manual Hardware 2 List of Abbreviations and Acronyms Abbreviation Full Form Asynchronous Communications Interface Adapter bits per second Cyclic Redundancy Check Direct Memory Access Direct Memory Access Controller Global System for Mobile Communications High Impedance Inter Equipment Bus Input Output Infrared Data Association Least Significant Bit Vost Significant Bit NC Non Connect PLL Phase Locked Loop PWM Pulse Width Modulation SFR Special Function Register Subscriber Identity Module Universal Asynchronous Receiver Transmitter Voltage Controlled Oscillator Abbreviation Full Form Analog to Digital Converter e2
47. hanging to a product with a different part number implement a system evaluation test for the given product Disclaimer By using this Renesas Starter Kit RSK the user accepts the following terms The RSK is not guaranteed to be error free and the entire risk as to the results and performance of the RSK is assumed by the User The RSK is provided by Renesas on an as is basis without warranty of any kind whether express or implied including but not limited to the implied warranties of satisfactory quality fitness for a particular purpose title and non infringement of intellectual property rights with regard to the RSK Renesas expressly disclaims all such warranties Renesas or its affiliates shall in no event be liable for any loss of profit loss of data loss of contract loss of business damage to reputation or goodwill any economic loss any reprogramming or recall costs whether the foregoing losses are direct or indirect nor shall Renesas or its affiliates be liable for any other direct or indirect special incidental or consequential damages arising out of or in relation to the use of this RSK even if Renesas or its affiliates have been advised of the possibility of such damages Precautions The following precautions should be observed when operating any RSK product This Renesas Starter Kit is only intended for use in a laboratory environment under ambient temperature and humidity conditions A safe s
48. he connections of the application header JA2 Application Header JA2 JA2 B Pin Header Name MCU Link Pin Header Name MCU Link Port Pin Required Port Pin Required 1 RESET2_N sem 2 CON EXTAL AB16 R112 3 NMI Y9 4 OV 5 IRQO P1 0 19 R372 6 TXDO P4 9 K21 R289 7 OPEN 8 RXDO P4 10 J22 R293 9 IRQ1 P1 1 C17 R304 10 SCKO P4 8 K20 R300 11 OPEN 12 OPEN 13 OPEN 14 OPEN 15 OPEN 16 OPEN 17 OPEN 18 OPEN 19 OPEN 20 P7 8 4 R159 21 TCLKB P1_10 Y17 R188 22 7 Y4 R144 23 IRQ2 P1 8 AA17 R163 24 OPEN 25 26 OPEN Table 7 2 Application Header JA2 Connections Table 7 3 below lists the connections of the application header JA3 Note that address lines BA23 BA25 are manifested on Connector CN15 as detailed in Table 7 4 Application Header JA3 JA3 B Pin Header Name MCU Link Pin Header Name MCU Link Port Pin Required Port Pin Required 1 BAO P9 2 R378 2 BA1 P7_9 K1 3 BA2 P7 10 L3 4 P7 11 12 5 BA4 P7 12 MI 6 5 P7 13 N1 7 BA6 P7 14 N2 8 7 P7 15 9 P8 0 P1 10 9 P8 1 P2 ti BA10 P8 2 P3 12 P8 3 R1 13 BA12 4 R2 14 1 P8_5 R3 15 14 P8 6 U2 16 15 P8 7 U4 17 BDO P6_0 B3 18 BD1 P6 1 D6 19 BD2 P6 2 4 20
49. icable to all MPU MCU products from Renesas For detailed usage notes on the products covered by this document refer to the relevant sections of the document as well as any technical updates that have been issued for the products 1 Handling of Unused Pins Handle unused pins in accordance with the directions given under Handling of Unused Pins in the manual The input pins of CMOS products are generally in the high impedance state In operation with an unused pin in the open circuit state extra electromagnetic noise is induced in the vicinity of LSI an associated shoot through current flows internally and malfunctions occur due to the false recognition of the pin state as an input signal become possible Unused pins should be handled as described under Handling of Unused Pins in the manual 2 Processing at Power on The state of the product is undefined at the moment when power is supplied The states of internal circuits in the LSI are indeterminate and the states of register settings and pins are undefined at the moment when power is supplied In a finished product where the reset signal is applied to the external reset pin the states of pins are not guaranteed from the moment when power is supplied until the reset process is completed In a similar way the states of pins in a product that is reset by an on chip power on reset function are not guaranteed from the moment when power is supplied until the power reaches the level at
50. imultaneous serial lines of I O in dual QSPI mode During the QSPI boot mode Port 0 is used and is accessed using only the clock SPBMOO and SPBMIO signals Single bit Single channel Channel 0 Port 0 SPBSSL SPBCLK 5 SPBMIO T7 T6 T5 T4 T3 T2 T1 TO R7 R6 R5 R3 X RX RI RO Serial Flash Figure 5 2 Single bit single channel operation mode R20UT3007EGO200 Rev 2 00 May 17 2015 TENESAS Page 20 of 53 RSK RZA1H 5 User Circuitry It is important to recognise that these eight lines are serial inputs and are not operating on the same byte but successive bytes When operating over the two ports it should be noted that the memory structure is fundamentally different from single channel operation as lines 1 4 are working with the memory on Port 0 and 5 8 are working with Port 1 Figure 5 3 attempts to show this visually Byte13 Byte9 5 14 Byte10 Byte6 15 11 Byte7 16 Byte12 Byte8 Byte9 Byte10 Bytet1 Byte12 Byte13 Byte14 Byte15 Byte16 Byte1 Byte2 Byte3 Byte4 Byte1 Byte2 Byte3 Byte4 Byte5 Byte6 Byte7 Byte8 Single Channel Mode Serial Flash 0 gt Bytel3 Byte9 5 Bytel 14 Bytel0 Bytee Byte2 15 Bytei1 Byte7 Byte3 Bytel6 Bytel
51. mcorp Trade Centre No 18 Persiaran Barat 46050 Petaling Jaya Selangor Darul Ehsan Malaysia el 60 3 7955 9390 Fax 60 3 7955 9510 Renesas Electronics Korea Co Ltd F 234 Teheran ro Gangnam Gu Seoul 135 080 Korea 82 2 558 3737 Fax 82 2 558 5141 DP 2014 Renesas Electronics Corporation All rights reserved Colophon 3 0 RZ A1H Group RENESAS Renesas Electronics Corporation R20UT3007EG0200
52. nal Pon Bin 35 NC 36 NC 37 SDAO P1 1 C17 38 SCLO P1 0 A19 39 TP INT P4 9 K21 40 P11 12 RSPCK1 P11 12 G2 41 P11 14 MOSI1 P11_14 H3 42 15 MISO1 P11 15 J4 43 TFT CS Port Expander 2 2 See section 5 5 DUIS 44 NC 45 BOARD VCC 46 BOARD VCC 47 GROUND 48 GROUND 49 BOARD 5V 50 BOARD 5V R20UT3007EGO200 Rev 2 00 May 17 2015 Table 5 20 TFT Signal Connections continued RENESAS Page 30 of 53 RSK RZA1H 5 19 LVDS The RSK board provides an LVDS interface from connector CN17 Connection details to the MCU are described in Table 5 21 5 User Circuitry Connector Slanal da MCU i igna unction a Port Pin 1 BOARD_VCC 3 3V Power supplied to external display N A N A BOARD_VCC 3 3V Power supplied to external display N A N A GROUND GROUND connection for the external N A N A display 4 GROUND GROUND connection for the external N A N A display P5_7_TXOUTOM LVDS Channel 0 Minus Line P5 7 B9 P5 6 TXOUTOP LVDS Channel 0 Positive Line P5 6 A9 GROUND Isolates neighbouring pairs of data N A N A signals P5 5 TXOUT1M LVDS Channel 1 Minus Line P5 5 C10 P5 4 TXOUTIP X LVDS Channel 1 Positive Line P5 4 11 10 GROUND Isolates neighbouring pairs of data N A N A signals ti P5 3 TXOUT2M LVDS Channel 2 Minus Line P5 3 B10 12 P5 2 TXOUT2P LVDS Channel 2 Positive Line 5_2 10 13 GROUND Isolates neighbouring pairs of data N A N A
53. nction iets Port Pin NAFO TRACEDO SMCD IO line 0 P3 8 V19 NAF1 TRACED1 SMWP1 IO line 1 _9 W20 NAF2_TRACED2_SMD1 IO line 2 P3 10 T20 NAF3 TRACED3 SMDO IO line 3 11 T21 NAF4_SMCLK IO line 4 P3 12 T22 NAF5 SMCMD IO line 5 P3 13 R22 NAF6 TRACECLK SMD3 IO line 6 P3 14 R21 NAF7 SMD2 IO line 7 P3 15 R20 P4 3 FWE MMCD7 Write Enable P4 3 N22 P4 2 FALE MMCD6 Address latch Enable P4 2 P21 P4 1 FCLE MMCD5 Command Latch Enable 4 1 P22 P4 0 FRE MMCD4 Read Enable P4 0 P20 P1 2 FRB Ready Busy P12 B18 FCE NAND Chip Enable P5 5 C10 RESET2 N Write Protect Connected to reset circuit Table 5 7 NAND Flash Connection To enable boot for the NAND FLASH set SW6 pins 1 2 3 to OFF The NAND device is 256MByte in size however it should be noted however that only 64MByte is addressable Refer to section 6 1 5 for further details 5 10 Dual QSPI Flash The RSK board provides two 64MByte Serial Flash memory ICs IC25 and IC26 which connect to the RZ A1H MCU via the SPI Multi Bus Controller Signal Connections are detailed in Table 5 8 below MCU Signal Function Port Pin SPBCLK 0 Serial Clock Common P9 2 C8 P9 3 SPBSSL 0 Chip Select Common P9 3 A6 RESET N Device Reset Common Connected to reset circuit P9 4 SPBIOO0 0 Serial Input IO 0 IC26 Device 0 P9 4 B6 P9 5 SPBIO10 0 Serial Output IO 1 IC26 Device 0 P9 5 C7 P9 6 SPBIO20 0 Write Protect IO 2 IC26 Device 0 P9 6 A5 P9
54. nded nor authorized for use in products or systems that may pose a direct threat to human life or bodily injury artificial life support devices or systems surgical implantations etc or may cause serious property damages nuclear reactor control systems military equipment etc You must check the quality grade of each Renesas Electronics product before using it in a particular application You may not use any Renesas Electronics product for any application for which it is not intended Renesas Electronics shall not be in any way liable for any damages or losses incurred by you or third parties arising from the use of any Renesas Electronics product for which the product is not intended by Renesas Electronics You should use the Renesas Electronics products described in this document within the range specified by Renesas Electronics especially with respect to the maximum rating operating supply voltage range movement power voltage range heat radiation characteristics installation and other product characteristics Renesas Electronics shall have no liability for malfunctions or damages arising out of the use of Renesas Electronics products beyond such specified ranges Although Renesas Electronics endeavors to improve the quality and reliability of its products semiconductor products have specific characteristics such as the occurrence of failure at a certain rate and malfunctions under certain use conditions Further Renesas Electronics products
55. ns of these headers Some pins will require link resistors to be fitted in order to make the connection to the specified MCU pin These resistors are also documented in the tables highlighted in bold blue if they are fitted by default or normal text if they are not fitted as standard Table 7 1 below lists the connections of the application header JA1 Application Header JA1 JA1 B Pin Header Name MCU Pin Link Pin Header Name MCU Pin Link Required Required 1 CON_5V R27 2 OV 3 CON 3V3 R25 4 OV 5 CON AVCC R116 6 CON AVSS R153 7 CON AVREF R13 8 ADTRG Pi 3 A18 R247 9 ADPOT CN P1 15 Y19 R347 10 P1 9 AB18 R421 ti AN2 P1 10 Y17 R422 12 AN3 P1 11 AA18 R423 13 OPEN 14 OPEN P2 0 L21 P2 1 K22 15 P2 0 100 Set PX1 EN1 16 2 1 101 Set PX1 EN1 ET 1 P2 2 F21 P2 3 G20 17 P2 2 IO2 Set PX1 EN1 18 2 3 103 Set PX1 EN1 1 1 2 4 F19 2 5 22 19 P2 4 104 Set PX1_EN1 20 P2 5 105 Set PX1 EN1 1 1 2 6 20 P2 7 C22 21 P2 6 106 Set PX1_EN1 22 P2 7 107 Set PX1 EN1 1 1 23 IRQ3 P1 9 AB18 R114 24 OPEN R141 R140 25 SDAS Pi 7 B16 R209 26 JA1 SCL3 P1 6 A17 R208 Table 7 1 Application Header JA1 Connections R20UT3007EG0200 Rev 2 00 RENESAS Page 42 of 53 May 17 2015 RSK RZA1H 7 Headers Table 7 2 below lists t
56. o be accessed at different addresses on channel 3 on the MCU The logical address for IC34 is 0x40 and IC35 is 0x41 Table 5 3 details the signal connections to IC34 and Table 5 4 details the signal connections to IC35 Port Number Signal name Function 0 LED1 LED output control Output low ON output high OFF 1 LED2 LED output control Output low ON output high OFF 2 LED3 LED output control Output low ON output high OFF 3 NOR_A25 Bit 25 of NOR Flash Addressing 4 PMOD1_RST Reset line for PMOD Channel 1 5 PMOD2_RST Reset line for PMOD Channel 2 6 SD_CONN_PWR_EN Power supply enable for external SD card connection 7 SD_MMC_PWR_EN Power supply enable for MMC card connection Table 5 3 Port Expander IC34 Connection Details Port Number Signal name Function 0 PX1_ENO Multiplex control for LCD DV Data Lines Low LCD High DV 1 PX1_EN1 Multiplex control for Ethernet general Data Lines Low general High Ethernet 2 TFT_CS Chip select for TFT 3 PX1_EN3 Multiplex control for PWM timer channels and audio codec 1 14 serial ADC DAC I O lines 4 USB_OVR_CURRENT Signal from USB power controller indicating overcurrent condition 5 USB_PWR_ENA Enable USB power supply for channel 0 6 USB_PWR_ENB Enable USB power supply for channel 1 7 PX1_EN7 Multiplex control for Address bus line A18 A21 and sound generator outputs SGOUTO 4 Table 5 4 Port E
57. o em o kr UN kag dao 46 81 COVENVIOW A DOE Va iit 46 8 2 ModeSupport ss ar A E SA ei loa 46 83 Compiler Restrictions ivive LOA UD rds ane vp 46 8 4 Debugger Support sss Ea eeu eel IN ia ae A ne eee 46 8 5 Address Space sita E leaves cand COJ i havi 47 9 Additional Information cccccccecceecceccecceeececceceaeececeaes 10 Appendix A Component Layout and Board Dimensions ENESAS RSK RZA1H R20UT3007EG0200 Rev 2 00 RENESAS STARTER KIT May 17 2015 1 Overview 1 1 Purpose This RSK is an evaluation tool for Renesas microcontrollers This manual describes the technical details of the RSK hardware The Quick Start Guide and Tutorial Manual provide details of the software installation and debugging environment 1 2 Features This RSK provides an evaluation of the following features e Renesas microcontroller programming e User code debugging e User circuitry such as switches LEDs and a potentiometer e Sample application e Sample peripheral device initialisation code The RSK board contains all the circuitry required for microcontroller operation R20UT3007EGO200 Rev 2 00 RENESAS Page 10 of 53 May 17 2015 RSK RZA1H 2 Power Supply 2 Power Supply 2 1 Requirements This RSK is supplied with a SEGGER JLink Lite debugger This board is supplied with a 5Vdc supply using a 5 0mm barrel power jack The board can operate with a supply of up to 12Vd
58. r and Power Settings Note e When evaluating OTG ensure to replace the default USB connector USBO D with a USB Micro AB connector e Connectors such as the one manufactured by Hirose Electric with part number ZX62R AB 5P can be used R20UT3007EGO200 Rev 2 00 May 17 2015 TENESAS Page 22 of 53 RSK RZA1H 5 12 Ethernet amp EEPROM 5 User Circuitry This RSK board is fitted with an Ethernet connection The connections from the Ethernet driver IC IC12 are detailed in Table 5 13 Refer to the RZ A1H board schematics for further information Signal Port Pin ET MDC P5 95 A7 ET MDIO P3 3 Multiplexed AA6 ET_IRQ P4 14 IRQ6 G19 ET RXCLK P3 4 Multiplexed Y5 ET RXD3 P2 11 Multiplexed E19 ET RXD2 P2 10 Multiplexed B22 ET RXD1 P2 9 Multiplexed C21 ET RXDO P2 8 Multiplexed D20 ET RXDV P3 6 Multiplexed ET RXER P3 5 Multiplexed 4 _ P2 2 Multiplexed F21 ET TXDO P2 4 Multiplexed F19 ET TXDI P2 5 Multiplexed E22 ET TXD2 P2 6 Multiplexed E20 ET TXD3 P2 7 Multiplexed C22 ET TXCLK P2 0 Multiplexed L21 ET TXER P2 1 Multiplexed K22 ET CRS P2 3 Multiplexed G20 RESET2 N Connected to reset circuit ET COL P1 14 AA19 This pin is connected to the MCU via link R105 Refer to section 6 1 8 for further details These pins are connected to the M
59. rrent point in time Advanced Settings for COM3 Use FIFO buffers requires 16550 compatible UART Select lower settings to correct connection problems Select higher settings for faster performance Receive Buffer Low 1 High 14 14 Transmit Buffer Low 1 0 High 16 16 COM Port Number COM1 use in use COM4 in use COMS in use COME in use COMB in use COM9 COMIO Figure 5 8 Device Manager Advanced Port Settings Click OK to complete the process R20UT3007EG0200 Rev 2 00 TEN ESAS Page 27 of 53 May 17 2015 RSK RZA1H 5 User Circuitry 5 17 Pmod Module Connectors A Pmod Compatible debug LCD module is supplied with the RSK and should be connected to the PMOD1 header Care should be taken when installing the LCD module to ensure pins are not bent or damaged The LCD module is vulnerable to electrostatic discharge ESD therefore appropriate ESD protection should be used The Digilent Pmod Compatible header uses a SPI interface Some RSKs will be provided with a monochrome display others will have a colour display Code for the appropriate display will be included in the product software support Connection information for the Digilent Pmod Compatible header is provided in Table 5 18 for Pmod connector 1 and Table 5 19 for Pmod connector 2 Please note that the connector numbering adheres to the Digilent Pmod standard
60. t um i ee 18 58 SDRAM NORSFlaShis tct ete rec etr Aa e de 18 5 9 EE 19 5 10 D al QSPLElash eet 19 5 11 Universal Serial Bus 5 22 12 amp bte ideae erben ar ee Pep epe lol ebo ga a 23 5 193 EEDS xir pam tai rato kola bo na lada A 24 5 14 Reset Circuits css ti la ide e lento 24 5 15 AUdlQ i i iie et ako is 24 5 16 USB Serlal esu toka panate pa eapo 25 CS enne en nene enr sinn nr 28 5 18 TFT LCD Panel 29 DO AI DSi ote 31 5 20 Pin Multiplexing acti thi ates FGR SE ane oam Rd 32 6 TRETEN 33 Modifying the tt orita orto 33 6 2 Power Supply 39 63 Ethernet Configuratio oec ien te RE Aa 39 6 4 Jumper Link 40 6 5 MCU Boot and Oscillator Configuration ennemis 41 FAN PM CORN cm 42 FA Application Headers eT EN EA eem keen ci ee 42 8 VO EDEVEIOPMEN su a ch ote RUN EN quay UR S d
61. the MCU s pins are multiplexed some of the peripherals must be used exclusively Refer to RZ A1H Group Hardware Manual and RSK RZA1H schematics for further information Table 6 1 RSK Default Configuration by Function Primary Function Secondary Function See Section s Switches Various IRQ Analog lines on Application 6 1 1 headers LEDs Timer channel TIOCOB external bus chip 6 1 1 select CS3 Various SD switch and IRQ functions USB Serial RTS amp CTS handshaking 6 1 9 SP DIF LVDS Channel 0 6 1 2 SDRAM CAN Channel 2 timer channel TIOC1B 6 1 3 NOR FLASH Timer channel TIOC3A 6 1 4 NAND FLASH LVDS Channel 1 6 1 5 QSPI FLASH Bus Address Line AO 6 1 6 CAN Channel 1 Some Ethernet lines Misc Connector 6 1 7 CN15 Ethernet ADC Line for App header CAN channel 1 6 1 8 Audio Codec IRQ for port expander TFT Backlight 6 1 11 Control LVDS SP DIF 6 1 12 PMOD Interfaces Various SD Timer and Application Header 6 1 13 signals SD Card SD card interface 6 1 14 TFT Serial TXDO SD Card Write Protect 6 1 10 The primary and secondary functions depend on the port pin these two functions share A link resistor is a 0 surface mount resistor which is used to short or isolate parts of a circuit Option links are listed in the following sections detailing their function when fitted or removed Refer to the component placement diagram Figure 3 3 Figure 3 4 to locate the op
62. tion links and jumpers Bold blue text indicates the default configuration that the RSK is supplied with R20UT3007EG0200 Rev 2 00 May 17 2015 TENESAS Page 33 of 53 RSK RZA1H 6 Configuration 6 1 1 Switches Potentiometer and LED Table 6 2 details the option links associated with the user switches pot and LEDs MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove i Fit Remove R114 JA1 Pin23 R114 SW1 19 AB18 SW1 R192 R421 JA1 Pin10 R421 18 R162 R163 JA2 Pin23 R163 ewe ANIT R86 JA2 B Pin23 R420 R189 5 Pin10 R189 SW3 1 11 AA18 SW3 R423 Pin12 423 e POT 1 15 Y19 ADPOT R161 R347 JA1 Pin9 R347 R181 LEDO TA H2 LEDO R328 R164 JAS Pin14 R181 Table 6 2 Option Link configuration for user switches pot and LEDs Switch bank SW4 is used to control the functionality of the Ethernet connection Please refer to section 6 3 Ethernet Configuration on page 39 for further information Switch bank SW6 is used to control the boot options Please refer to section 6 5 MCU Boot and Oscillator Configuration on page 41 for further information 6 1 2 SP DIF Table 6 3 details the option links associated with SP DIF MCU Exclusive Function Header Connection Function Port Pin Signal Fit Remove dj Fit Remove 56 A9 SPDIF IN E R170 SP DIF 5 7 B9 SPDIF OUT R183 R182
63. uded herein Renesas Electronics does not assume any liability for infringement of patents copyrights or other intellectual property rights of third parties by or arising from the use of Renesas Electronics products or technical information described in this document No license express implied or otherwise is granted hereby under any patents copyrights or other intellectual property rights of Renesas Electronics or others You should not alter modify copy or otherwise misappropriate any Renesas Electronics product whether in whole or in part Renesas Electronics assumes no responsibility for any losses incurred by you or third parties arising from such alteration modification copy or otherwise misappropriation of Renesas Electronics product Renesas Electronics products are classified according to the following two quality grades Standard and High Quality The recommended applications for each Renesas Electronics product depends on the product s quality grade as indicated below Standard Computers office equipment communications equipment test and measurement equipment audio and visual equipment home electronic appliances machine tools personal electronic equipment and industrial robots etc High Quality Transportation equipment automobiles trains ships etc traffic control systems anti disaster systems anticrime systems and safety equipment etc Renesas Electronics products are neither inte
64. uds Renesas Eclipse Embedded Studio Integrated Debugging Environment EMC Electromagnetic Compatibility All trademarks and registered trademarks are the property of their respective owners Table of Contents uuo s m 10 1 1 dre cm SN M D UNE Nx NL A va kau ote 10 ka FENNOS er ron be uenia UM LEM dU DAL 10 2 Power UL die ette dnte 11 21 oss Md nd In cet ML HU EU ID UL 11 2 2 PowerUp Behaviour ai ee es PPP t E EU Ge D ER TOTE 11 9 Board WAY OU sss es eiie encantan ete ci cede ese eden e ene 12 34 GomponentLEayoUt uita NO DL cha ee ee a a AM 12 3 2 Board 20 d ah AN SD ANMALA 13 Queen eld pee EDEN 14 41 Internal RSK Connections sirere anana nnns ettet etn 14 42 Debugger Connections 2 AEA A di 15 5 User sprak al od raad a a teeters E A MU Ta o E raa Roa 16 51 POtentioMmeteras c estat d adt dat at CAN NAGAS ENO 16 52 Glock Circuits eoe oM ree LI Ir En 16 53 Video InpUt eatin viata en E ae 16 5 4 SWIICIHOS nci a e coti LA Tute D tes 16 55 sete d obti a ed an 17 5 62 Stute 17 SDIMMQG ss o hae op ald anlo et ra ecu a
65. umper is set to link pins 2 3 Table 6 19 Jumper Option descriptions R20UT3007EG0200 Rev 2 00 RENESAS Page 40 of 53 May 17 2015 RSK RZA1H 6 5 6 Configuration MCU Boot and Oscillator Configuration The six way DIP switch SW6 provides some configuration options for the RZ A1H MCU Switches 1 2 and 3 are used to set the boot mode of the RZ A1H Table 6 20 provides details of the available modes and the corresponding switch settings Due to pull up resistors in the circuit a 1 is produced when the corresponding switch position is OFF and a 0 is produced when it is ON MD_BOOTO MD_BOOT1 MD_BOOT2 JP18 Boot Mode SW6 1 SW6 2 SW6 3 0 0 SHORT Boot mode 0 CS0 space 16 bit booting ON ON Boots the LSI from memory bus width 16 bits connected to the CSO space Uses NOR flash 1 23 0 1 s SHORT Boot mode 1 CS0 space 32 bit booting ON OFF Boots the LSI from memory bus width 32 bits connected to the CSO space Not supported on RSK 1 0 1 ii Boot mode 3 serial flash booting OFF ON OFF Boots the LSI from the serial flash memory connected to the SPI multi I O bus space The only way of booting this LSI chip is from channel 0 P9 2to P9 5 in this mode Uses QSPI flash IC26 only 1 1 0 Boot mode 4 5 booting OFF OFF ON Boots the LSI from the NAND flash memory with the SD controller The only way of booting this LS
66. urce to the RSK when PWR_SEL jumper is set to link pins 2 3 Table 6 16 PWR_SEL Header Configuration There are 2 headers available that can be used to measure the current taken by the MCU during operation JP4 can be used to measure the MCU core current and JP6 can be used to measure current drawn by the MCU port pins by shorting them via a current meter In order to use these functions it is necessary to remove links R24 and R26 respectively Table 6 17 provides a summary JP4 MCU Core Current Measurement Remove R24 and short JP4 with meter to measure MCU core current JP6 MCU Port Pins Current Measurement Remove R26 and short JP6 with meter to measure MCU port pin current Table 6 17 MCU Current Measurement Headers 6 3 Ethernet Configuration Table 6 18 below details the options configurable for the Ethernet function via the 8 way DIP switch SW4 SW4 LAN Strap Option Off On Signal name 1 Auto MDI X Enable 1 0 ET CRS 2 Q Autoneg Enable 1 0 RXCLK 3 Phy 0 1 ET RXDO 4 Phy 0 1 ET_RXD1 5 Full Half 1 0 ET_RXD2 6 Autoneg EN 1 0 ET_RXD3 7 MII RMII 1 0 ET_RXER 8 Fast J Std JK 1 0 ET_TXCLK Table 6 18 Ethernet configuration via SW4 R20UT3007EG0200 Rev 2 00 ESAS Page 39 of 53 May 17 2015 RSK RZA1H 6 Configuration 6 4 Jumper Link Configuration Table 6 19 describes the jumper link option configurations available
67. xpander IC35 Connection Details 5 6 CAN There are two CAN channels which connect to the MCU as listed in Table 5 5 MCU CAN Signal Function Port Pin CAN CTX1 CAN Channel 1 Transmit P5 10 B7 CAN CRX1 CAN Channel 1 Receive P5 9 2 CAN Channel 2 Transmit P7 J3 CAN CRX2 CAN Channel 2 Receive 7 2 H1 Table 5 5 CAN Connection R20UT3007EGO200 Rev 2 00 ESAS Page 17 of 53 May 17 2015 RSK RZA1H 5 User Circuitry 5 7 SD MMC The RSK board provides an SD MMC card socket CN1 The connections are detailed in Table 5 6 Signal Function dr Port Pin NAF1 TRACED1 SMWP1 Write Protect P3 9 W20 NAFO TRACEDO SMCD Card Detect P3 8 V19 NAF5 SMCMD Command I O P3 13 R22 NAF4_SMCLK Clock _12 T22 NAF3 TRACED3 SMDO Data 0 P3 11 21 NAF2 TRACED2 SMD1 Data 1 P3 10 T20 NAF7 SMD2 Data 2 P3 15 R20 NAF6 TRACECLK SMD3 Data 3 P3 14 R21 P4 0 FRE 4 Data 4 P4 0 P20 P4 1 FCLE MMCD5 Data 5 P4 1 P22 P4 2 FALE MMCD6 Data 6 P4 2 P21 P4 3 FWE MMCD7 Data 7 P4 3 N22 Table 5 6 SD MMC Connection Note that it is not possible to boot from an SD card that is connected to the SD MMC connector CN1 This is because the connector utilises channel 1 of the SD controller integrated in the RZ A1H MCU For further information refer to the hardware manual table 3 1 5 8 SDRAM NOR Flash The RSK board provides 32MByte SDRAM IC24 and 16MByte
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