Chapter 1. Preface
Cautions
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
Solutions Corporation.
Trademarks
All brand or product names used in this manual are trademarks or registered trademarks of their respective companies or
organisations.
Copyright
© Renesas Solutions Corp. 2007. All rights reserved.
© Renesas Technology Europe Ltd. 2007. All rights reserved.
© Renesas Technology Corp. 2007. All rights reserved.
Website:
(Europe)
(Global)
Glossary
CPU
HEW
LCD
LIN
Central Processing Unit
PC
Program Counter
Renesas Starter Kit
Light Emitting Diode
High-performance Embedded Workshop
Liquid Crystal Display
RSK
LED
Local Interconnect Network
E8a Debug module
E8a
CD
Compact Disc
1
Chapter 2. Purpose
This Renesas Starter Kit is an evaluation tool for Renesas microcontrollers.
Features include:
•
•
•
•
•
Renesas Microcontroller Programming.
User Code Debugging.
User Circuitry such as Switches, LEDs and potentiometer(s).
User or Example Application.
Sample peripheral device initialisation code.
The Renesas Starter Kit board contains all the circuitry required for microcontroller operation.
2
Chapter 3. Power Supply
3.1. Requirements
This Renesas Starter Kit operates from a 3V to 5V power supply.
A diode provides reverse polarity protection only if a current limiting power supply is used.
All Renesas Starter Kit boards are supplied with an E8a debugger. This product is able to power the Renesas Starter Kit board with up to
300mA. When the Renesas Starter Kit is connected to another system then that system should supply power to the Renesas Starter Kit.
All Renesas Starter Kit boards have an optional centre positive supply connector using a 2.1mm barrel power jack.
Warning
The Renesas Starter Kit is neither under nor over voltage protected. Use a centre positive supply for this board.
3.2. Power – Up Behaviour
When the Renesas Starter Kit is purchased the Renesas Starter Kit board has the ‘Release’ or stand alone code from the example tutorial
code pre-programmed into the Renesas microcontroller. On powering up the board the user LEDs will start to flash. After 200 flashes, or
after pressing a switch the LEDs will flash at a rate controlled by the potentiometer.
3
Chapter 4. Board Layout
4.1. Component Layout
The following diagram shows the top layer component layout of the board.
Application Board Interface
Reset Switch
RS232 Serial
Power
LCD Display
JA5
JA1
Power LED
Microcontroller Pin Headers
(J1 to J4)
E8 Header
User LED
MCU
Power Connector
for LIN
LIN Connector
Boot LED
JA6
JA2
User/Boot Switch
User Switches
Application Board Interface
Potentiometer
Figure 4-1: Board Layout
4
4.2. Board Dimensions
The following diagram gives the board dimensions and connector positions. All through hole connectors are on a common 0.1” grid for easy
interfacing.
120.00mm
115.00mm
86.36mm
Short Board = 85 mm
50.80 mm
Corners x4
3mm radius
43.18 mm
35.56 mm
27.00mm
RV1
(POT)
SW
1
SW
2
SW
3
JA2
JA6
L
I
N
J4 - Applies to connector
with micriocontroller pin1
MC
U
J3
J1
E8
J2
JA5
Serial D9
SKT
JA1
R
E
S
45.00mm
Figure 4-2 : Board Dimensions
5
Chapter 5. Block Diagram
Figure 5-1 is representative of the CPU board components and their connectivity.
Power Jack Option
BOOT
Circuitry
Application Board
Interface
Boot mode pins
Microcontroller Pin
Headers
D-type
Latch
RESET pin
Microcontroller
E8
IRQ pins
LIN Connector,
Power Connector for LIN
ADC Input
I/O
Serial Connector Option
SW1
BOOT
SW3 SW2
RES
Switches
LCD Display
POWER: Green
BOOT: Orange
Potentiometer
Data x4
User LED x4
1Green, 1Orange, 2Red
Control x2
LEDs
Figure 5-1: Block Diagram
Figure 5-2 : Renesas Starter Kit Connections
6
Chapter 6. User Circuitry
6.1. Switches
There are four switches located on the board. The function of each switch and its connection are shown in Table 6-1.
Switch
RES
Function
Microcontroller
RESETn Pin9
When pressed, the board microcontroller is reset.
SW1/BOOT* Connects to an IRQ input for user controls.
The switch is also used in conjunction with the RES switch to place
INT0n Pin44
(Port 4, pin 5)
the device in BOOT mode when not using the E8A debugger.
Connects to an IRQ Interrupt input line for user controls.
SW2*
SW3*
INT1n Pin52
(Port 3, pin 6)
INT2n Pin53
(Port 3, pin 2)
Connects to a Key In Interrupt input line for user controls
Table 6-1: Switch Functions
*Refer to schematic for detailed connectivity information.
6.2. LEDs
There are six LEDs on the CPU board. The green ‘POWER’ LED lights when the board is powered. The orange BOOT LED indicates the
device is in BOOT mode when lit. The four user LEDs are connected to an IO port and will light when their corresponding port pin is set low.
Table 6-2, below, shows the LED pin references and their corresponding microcontroller port pin connections.
LED Reference
Colour
Microcontroller Port Pin function
Microcontroller Pin
Number
(As shown on silkscreen)
LED0
Green
Port 6.0
43
72
71
1
LED1
LED2
LED3
Orange
Red
Port 6.1
Port 6.2
Port 3.3
Red
Table 6-2: LED Port
6.3. Potentiometer
A single turn potentiometer is connected to AN8 (P1.0) of the microcontroller. This may be used to vary the input analog voltage value to
this pin between VREF and Ground.
7
6.4. Serial port
This RSK provides two serial ports to the user. The serial port 1 has already been configured for use. To use serial port 2 the user needs to
Description
TxD2
Fit for RS232
R34
R33
RxD2
Table 6-3: Serial Port settings
6.5. LCD Module
A LCD module is supplied to be connected to the connector ‘LCD’. This should be fitted so that the LCD module lies over ‘JA1’ and ‘JA5’.
Care should be taken to ensure the pins are inserted correctly into ‘LCD’ connector. The LCD module uses a 4 bit interface to reduce the
pin allocation. No contrast control is provided; this is set by a resistor on the supplied display module. The module supplied with the
Renesas Starter Kit only supports 5V operation.
J8
Pin
Circuit Net Name
Device Pin
Pin
Circuit Net Name
Device
Pin
1
3
5
7
9
Ground
-
2
4
6
8
5V Only
DLCDRS
DLCDE
-
No Connection
-
38
37
-
R/W (Wired to Write only)
No Connection
-
-
No Connection
No Connection
-
10 No Connection
12 DLCD5
-
11 DLCD4
13 DLCD6
42
40
41
39
14 DLCD7
Table 6-4: LCD Module Connections
8
6.6. Option Links
Table 6-5 below describes the function of the option links associated with Power configuration. The default configuration is indicated by
BOLD text.
Option Link Settings
Reference
Function
Power Source
Fitted
Alternative (Removed)
Related To
R10
Board can be powered from
PWR connector
Disable external power connector
R44, R45
R37
R44
R45
Microcontroller Power Supply Supply power to
Fit Low ohm resistor to measure
current.
-
Microcontroller
Power Source Configuration Connects external 5V supply Disconnects external 5V supply to the
R10, R45
to the RSK.
RSK.
Power Source
Connects regulated 3.3V
voltage source to Board_VCC
Disconnects regulated 3.3V voltage R10, R44
source from Board_VCC
Table 6-5: Power configuration links
Table 6-6 below describes the function of the option links associated with Clock configuration. The default configuration is indicated by
BOLD text.
Option Link Settings
Reference
Function
Main clock Oscillator
Configuration
Fitted
Alternative (Removed)
Disconnects external clock
connection to MCU
Related To
R46, R47,
R52
R42
Connects external clock to MCU
R46
R47
R52
R48
R53
Main clock Oscillator
Configuration
Connects external clock to MCU
Connects external clock to MCU
Connects external clock to MCU
Disconnects external clock
connection to MCU
R42, R47,
R52
Sub clock Oscillator
Configuration
Disconnects external clock
connection to MCU
R42, R46,
R52
Sub clock Oscillator
Configuration
Disconnects external clock
connection to MCU
R42, R46,
R47
Main clock Oscillator
Configuration
On board crystal (X1) is
connected to the CPU.
On board crystal (X2) is
connected to the CPU.
On board crystal (X1) is disconnected
from the CPU.
R42, R46
Sub clock Oscillator
Configuration
On board crystal (X2) is disconnected
from the CPU.
R47, R52
Table 6-6: Clock configuration links
9
Table 6-7 below describes the function of the option links associated with serial configuration. The default configuration is indicated by
BOLD text.
Option Link Settings
Reference
Function
Serial Port
Fitted
Connects serial port TXD1 to SERIAL
D-type connector.
Alternative (Removed)
Disconnects serial port TXD1 from
SERIAL D-type connector.
Enables RS232 Serial
Related To
R11
R22
Configuration
Serial Port
R21
R22
R25
R30
R33
R34
R38
R39
Disables RS232 Serial
Transceiver
-
Configuration
Serial Port
Transceiver
Connects serial port RXD1 to SERIAL Disconnects serial port RXD1 from
R11
R30
R25
Configuration
Serial Port
D-type connector.
SERIAL D-type connector.
Routes RS232 serial port Rx to
application connector (JA6)
Disconnects RS232 serial port Rx
from application connector (JA6)
Configuration
Serial Port
Routes RS232 serial port Tx to application Disconnects RS232 serial port Tx
Configuration
Serial Port
connector (JA6)
from application connector (JA6)
Disconnects serial port TXD2 from
SERIAL D-type connector.
Connects serial port RXD2 to SERIAL
D-type connector.
R34, R38,
R39
Configuration
Serial Port
Connects serial port TXD2 to SERIAL
D-type connector.
Disconnects serial port RXD2 from
SERIAL D-type connector.
R33, R38,
R39
Configuration
Serial Connector
Connects Alternate serial (CH2) to D
connector
Disconnects Alternate serial from D R33, R34,
connector.
R39
Disconnects Alternate serial from D R33, R34,
connector.
R38
Serial Connector
Connects Alternate serial (CH2) to D
connector
Table 6-7: Serial configuration links
Table 6-8 below describes the function of the option links associated with LIN configuration. The default configuration is indicated by
BOLD text.
Option Link Settings
Reference
Function
Fitted
Alternative (Removed) Related To
R3
LIN Interface
Connects RXD0 pin of the microcontroller to
the RXD pin of LIN transceiver
RXD0 can be used for
serial communication.
CLK0 can be used for
serial communication.
TXD0 can be used for
serial communication.
External supply can be
connected to VBAT.
LIN operates in Slave
mode
R7, R8
R7
LIN Interface
LIN Interface
LIN Interface
LIN Interface
Connects CLK0 pin of the microcontroller to
the NSLP pin of LIN transceiver
R3, R8
R8
Connects TXD0 pin of the microcontroller to
the TXD pin of LIN transceiver
R3, R7
R27
R5
Board_VCC supplies power to LIN.
-
-
LIN operates in Master mode
Table 6-8: LIN Configuration Links
10
Table 6-9 below describes the function of the option links associated with serial configuration. The default configuration is indicated by
BOLD text.
Option Link Settings
Reference
R36
Function
Fitted
Alternative (Removed)
PIN 57 disconnected from ADPOT
PIN 57 disconnected from AN8
CON_VREF can be used to supply the
reference voltage for Analog section.
UC_VCC can be used to supply the
reference voltage for Analog section.
Related To
R66
Analog configuration PIN 57 connected to ADPOT
Analog configuration PIN 57 connected to AN8 on JA5
Analog configuration UC_VCC supplies the reference
voltage for Analog section.
R66
R36
R40
R41
R41
Analog configuration CON_VREF supplies the reference
voltage for Analog section.
R40
Table 6-9: Analog configuration links
Table 6-10 below describes the function of the option links associated with other options. The default configuration is indicated by BOLD
text.
Option Link Settings
Reference
R49
Function
Fitted
Alternative (Removed)
PIN 76 disconnected from on JA1
PIN 76 disconnected from DA1
PIN 74 disconnected from AN1 on JA
PIN 74 disconnected from DA0
PIN 46 disconnected from INT3n
Related To
R58
Pin function select PIN 76 connected to AN0 on JA1
Pin function select PIN 76 connected to DA1 on JA1
Pin function select PIN 74 connected to AN1 on JA
Pin function select PIN 74 connected to DA0 on JA
Pin function select PIN 46 connected to INT3n on JA1
R58
R49
R56
R59
R59
R56
R63
R67
R67
Pin function select PIN 46 connected to RXD1 on JA6 PIN 46 disconnected from RXD1
Pin function select PIN 73 connected to AN2 on JA1
PIN 73 disconnected from AN2
R63
R57
R62
R62
Pin function select PIN 73 connected to CLK1 on JA6 PIN 73 disconnected from CLK1
R57
Table 6-10: Pin function configuration links
6.7. Oscillator Sources
A crystal oscillator is fitted on the board and used to supply the main/sub clock input to the Renesas microcontroller.
Table 6-10 details the oscillators that are fitted and alternative footprints provided on this board:
Component
Crystal (X1)
Fitted
Fitted
20 MHz (HC/49U package)
Sub clock (X2)
32.768 kHz (90SMX package)
Table 6-10: Oscillator Configuration
6.8. Reset Circuit
The CPU Board includes a simple latch circuit that links the mode selection and reset circuit. This provides an easy method for swapping
the device between Boot Mode and Single chip mode. This circuit is not required on customers’ boards as it is intended for providing
easy evaluation of the operating modes of the device on the Renesas Starter Kit. Please refer to the hardware manual for more
information on the requirements of the reset circuit.
11
The Reset circuit operates by latching the state of the boot switch on pressing the reset button. This control is subsequently used to
modify the mode pin states as required.
The MODE pin should change state only while the reset signal is active to avoid possible device damage.
The reset is held in the active state for a fixed period by a pair of resistors and a capacitor. Please check the reset requirements carefully
to ensure the reset circuit on the customers’ board meets all the reset timing requirements.
6.9. LIN Interface
This Renesas Starter Kit has hardware LIN interface. The interface is available on connector ‘LIN’. The connector ‘J5’ functions as power
connector for LIN. The device can be operated either in ‘Master’ mode or ‘Slave’ mode. The device performs LIN communication in
cooperation with Timer RA and UART0.
For more details on LIN interface please refer to R8C/2C Group, R8C/2D Group Hardware Manual.
12
Chapter 7. Modes
This Renesas Starter Kit supports Boot mode and Single chip mode.
Details of programming the FLASH memory is described in the R8C/2C Group, R8C/2D Group Hardware Manual.
7.1. Boot mode
The Boot mode settings for this Renesas Starter Kit are shown in Table 7-1: Boot Mode pin settings below:
MODE
LSI State after Reset End
Low
Boot Mode
Table 7-1: Boot Mode pin settings
The software supplied with this Renesas Starter Kit supports Boot mode using an E8a and High-performance Embedded Workshop only.
However, hardware exists to enter boot mode manually, do not connect the E8a in this case. Press and hold the SW1/BOOT. The mode pin
is held in its boot state while reset is pressed and released. Release the boot button. The BOOT LED will be illuminated to indicate that the
microcontroller is in boot mode.
When neither the E8a is connected nor the board is placed in boot mode as above, the MODE pin is pulled high by a 4.7k resistor.
When an E8a is used the MODE pin is controlled by the E8A.
7.2. Single chip mode
Because the MODE pin is pulled high, this Renesas Starter Kit will always boot in Single chip mode when the E8a is not connected and the
boot switch is not depressed. Refer to R8C/2C Group, R8C/2D Group Hardware Manual for details of Single chip mode.
MODE
LSI State after Reset End
High
Single chip Mode
Table 7-2: Single chip Mode pin settings
13
Chapter 9. Headers
9.1. Microcontroller Headers
Table 9-1 to Table 9-4 show the microcontroller pin headers and their corresponding microcontroller connections. The header pins connect
directly to the microcontroller pins. * Marked pins are subject to option links.
J1
Pin
1
Circuit Net Name
Device Pin
Pin
Circuit Net Name
Device Pin
LED3
PIN3
PIN5
1
2
PIN2
PIN4
2
3
3
4
4
5
5
6
MODE
6
7
CON_XCIN
RESETn
7
8
CON_XCOUT
CON_XOUT
CON_XOUT
PIN14
8
9
9
10
12
14
16
18
20
10
12
14
16
18
20
11 GROUND
13 VCC
11
12
14
16
18
15 TRCIOC
17 TRCIOA
19 PIN19
TRCIOB
TRCCLK
PIN20
Table 9-1: J1
J2
Pin
1
Circuit Net Name
Device Pin
Pin
Circuit Net Name
Device Pin
PIN21
Wn
21
23
25
27
29
31
33
35
37
39
2
PIN22
Vn
22
24
26
28
30
32
34
36
38
40
3
4
5
Wp
6
Vp
7
Un
8
TRIGb
9
Up
10
12
14
16
18
20
TRDCLK
CLK0
11 TRIGa
13 RXD0
15 PIN35
17 DLCDE
19 DLCD7
TXD0
TRISTn
DLCDRS
DLCD6
Table 9-2: J2
15
J3
Pin
1
Circuit Net Name
DLCD5
Device Pin
Pin
Circuit Net Name
DLCD4
Device Pin
41
43
45
47
49
51
53
55
57
59
2
42
44
46
48
50
52
54
56
58
60
3
LED0
TXD1
CLK2
TXD2
4
INT0n
RXD1_INT3n*
RXD2
TMR1
INT1n
AN11
5
6
7
8
9
10
12
14
16
18
20
11 TMR0
13 INT2n
15 AN10
AN9
17 ADPOT_AN8*
19 IO_6
IO_7
IO_5
Table 9-3: J3
J4
Pin
1
Circuit Net Name
Device Pin
Pin
Circuit Net Name
Device Pin
IO_4
IO_2
IO_0
AN6
AN4
61
63
65
67
69
71
73
75
77
79
2
IO_3
IO_1
AN7
AN5
AN3
LED1
62
64
66
68
70
72
74
76
78
80
3
4
5
6
7
8
9
10
12
14
16
18
20
11 LED2
13 AN2_CLK1*
15 CON_VREF
17 GROUND
19 UD
AN1_DA0*
AN0_DA1*
VCC
PIN80
Table 9-4: J4
16
9.2. Application Headers
Table 9-5 to Table 9-8 below show the standard application header connections. * Marked pins are subject to option links.
JA1
Pin
Header Name
Circuit Net
Name
Device
Pin
Pin
Header Name
Circuit Net
Name
Device
Pin
1
Regulated Supply 1
Regulated Supply 2
Analog Supply
Analog Reference
ADC0
CON_5V
---
2
Regulated Supply 1
Regulated Supply 2
Analog Supply
ADTRG
GROUND
---
3
CON_3V3
NC
---
---
77
76
73
74
65
63
61
59
46
2
4
GROUND
NC
---
---
---
74
70
76
64
62
60
58
---
80
5
6
7
CON_VREF*
AN0*
8
NC
9
10
12
14
16
18
20
22
24
26
ADC1
AN1*
AN3
11
13
15
17
19
21
23
25
ADC2
AN2*
ADC3
DAC0
DA0*
DAC1
DA1*
IO_1
IO_3
IO_5
IO_7
NC
IOPort0
IO_0
IOPort1
IOPort2
IO_2
IOPort3
IOPort4
IO_4
IOPort5
IOPort8
IO_6
IOPort7
2
IRQ3
INT3n
SDA
I C Bus (3rd pin)
IIC_SDA
IIC_SCL
SCL
Table 9-5: JA1 Standard Generic Header
JA2
Pin
Header Name
Circuit Net
Name
Device
Pin
Pin
Header Name
Circuit Net
Name
CON_XIN*
VSS1 (GND)
TXD0
Device
Pin
1
Reset
RESETn
9
2
External Clock Input
Regulated Supply 1
Serial Port
12
---
34
33
32
---
27
24
23
50
28
36
---
3
Interrupt
NC
---
---
44
52
79
29
26
25
51
31
53
---
4
5
WDT overflow
Interrupt
NC
6
7
INT0n
INT1n
UD
8
Serial Port
RXD0
RXD0
NC
9
Interrupt
10
12
14
16
18
20
22
24
26
Serial Port
11
13
15
17
19
21
23
25
Motor up/down
Motor control
Motor control
Motor control
Timer Output
Timer Input
Interrupt
Serial Port Handshake
Motor control
Motor control
Motor control
Timer Output
Timer Input
Up
Un
Vp
Vn
Wp
Wn
TMR0
TRIGa
INT2n
---
TMR1
TRIGb
TRISTn
---
Tristate Control
SPARE
SPARE
Table 9-6: JA2 Standard Generic Header
17
JA5
Pin
Pin Generic Header Name
CPU board
Device
Pin
Generic Header Name
CPU board
Device
Pin
Signal Name
Signal Name
1
AD4
AN4
69
2
AD5
AN5
68
3
AD6
AN6
---
67
---
---
57
55
17
15
18
---
---
---
4
AD7
AN7
---
66
---
---
56
54
16
---
30
---
---
---
5
CAN1TX
CAN2TX
AD8
6
CAN1RX
CAN2RX
AD9
7
---
8
---
9
AN8
AN10
TRCIOA
TRCIOC
TRCCLK
---
10
12
14
16
18
20
22
24
AN9
AN11
TRCIOB
---
11
13
15
17
19
21
23
AD10
AD11
TIOC0A
TIOC0C
TCLKC
M2_Up
M2_Vp
M2_Wp
TIOC0B
M2_TRISTn
TCLKD
M2_Un
M2_Vn
M2_Wn
TRDCLK
---
---
---
---
---
Table 9-7: JA5 Optional Generic Header
JA6
Pin
Generic Header Name
CPU board
Device
Pin
Pin
Generic Header Name
CPU board
Device
Pin
Signal
Name
Signal Name
1
DMA
---
---
---
2
DMA
---
---
3
DMA
---
---
48
45
73
4
Standby (Open drain)
Host Serial
---
---
---
49
47
46
5
Host Serial
Serial Port
RS232TX*
RxD2
6
RS232RX*
TxD2
CLK2
RXD1*
7
8
Serial Port
9
Serial Port Synchronous
Serial Port Synchronous
Reserved
TXD1
10
12
14
16
18
20
22
24
26
Serial Port
11
13
15
17
19
21
23
25
CLK1*
Serial Port
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Synchronous
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Table 9-8: JA6 Optional Generic Header
18
Chapter 10. Code Development
10.1. Overview
Note: For all code debugging using Renesas software tools, the Renesas Starter Kit board must be connected to a PC USB port via an
E8a. An E8a is supplied with the Renesas Starter Kit product.
10.2. Mode Support
High-performance Embedded Workspace connects to the Microcontroller and programs it via the E8a. Mode support is handled
transparently to the user.
10.3. Breakpoint Support
High-performance Embedded Workshop supports breakpoints on the user code, both in RAM and ROM.
Double clicking in the breakpoint column in the code sets the breakpoint. Breakpoints will remain unless they are double clicked to remove
them.
20
10.4. Memory Map
00000h
SFR
002FFh
Reserved area
00400 h
Note: E8a Firmware area selected
Internal
RAM
via
HEW
00FFFh
Reserved area
02400 h
Internal
Emulator Firmware
Area
ROM
(Data Area)
02BFFh
0FFDCh
0FFE4h
Reserved area
04000h
Internal
Program
Area
Emulator
vector
)
0FFEFh
0FFF4h
( ROM
Emulator
vector
0FFDCh
0FFFFh
0FFFEh
0FFFFh
Fixed Vector Tables
13800h
13FFFh
Internal
ROM
Emulator Firmware
Area
13FFFh
FFFFFh
Expanded
Area
Figure 10-1 : Memory Map
21
Chapter 12. Additional Information
For details on how to use High-performance Embedded Workshop, refer to the High-performance Embedded Workshop manual available
on the CD or from the web site.
For information about the R8C/2D group microcontrollers, refer to the R8C/2C Group, R8C/2D Group Hardware Manual.
For information about the R8C/2D assembly language, refer to the R8C/Tiny Series Software Programming Manual.
Online technical support and information is available at:
Technical Contact Details
Europe: [email protected]
Japan:
General information on Renesas Microcontrollers can be found on the Renesas website at:
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Renesas Starter Kit for R8C/2D
User's Manual
Publication Date Rev.2.00 12.OCT.2007
Published by:
Dukes Meadow, Millboard Road, Bourne End Buckinghamshire
SL8 5FH, United Kingdom
©2007 Renesas Solutions Corp., Renesas Technology Europe Ltd. and Renesas Technology Corp.,
All Rights Reserved.
Renesas Starter Kit for R8C/2D
User's Manual
Dukes Meadow, Millboard Road, Bourne End Buckinghamshire SL8 5FH, United Kingdom
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