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Hardware ManualS5U1C17602T1100SOFTWARE EVALUATION TOOL FOR S1C17602

Evaluation board/kit and Development tool important notice

1. This evaluation board/kit or development tool is designed for use for engineering evaluation, demonstration, or development purposes only. Do not use it for other purpose. It is not intended to meet the requirement of design for finished product.

2. This evaluation board/kit or development tool is intended for use by an electronics engineer, and it is not the product for consumer. The user should use this goods properly and safely. Seiko Epson dose not assume any responsibility and liability of any kind of damage and/or fire coursed by usage of it. User should cease to use it when any abnormal issue occurs even during proper and safe use.

3. The part used for this evaluation board/kit or development tool is changed without any notice. NOTICE No part of this material may be reproduced or duplicated in any form or by any means without the written permission of Seiko Epson. Seiko Epson reserves the right to make changes to this material without notice. Seiko Epson does not assume any liability of any kind arising out of any inaccuracies contained in this material or due to its application or use in any product or circuit and, further, there is no representation that this material is applicable to products requiring high level reliability, such as, medical products. Moreover, no license to any intellectual property rights is granted by implication or otherwise, and there is no representation or warranty that anything made in accordance with this material will be free from any patent or copyright infringement of a third party. When exporting the products or technology described in this material, you should comply with the applicable export control laws and regulations and follow the procedures required by such laws and regulations. You are requested not to use, to resell, to export and/or to otherwise dispose of the products (and any technical information furnished, if any) for the development and/or manufacture of weapon of mass destruction or for other military purposes. All brands or product names mentioned herein are trademarks and/or registered trademarks of their respective companies.

©SEIKO EPSON CORPORATION 2012, All rights reserved.

Table of Contents

S5U1C17602T1100 Hardware Manual EPSON i

Table of Contents

1. Features............................................................................................................................................. 1 2. Package Contents............................................................................................................................. 2 3. Part Names and Functions............................................................................................................... 3

3.1 Part names ................................................................................................................................. 3 3.2 Board dimensional diagram........................................................................................................ 4

3.2.1 CPU board dimensional diagram....................................................................................... 4 3.2.2 ICD board dimensional diagram ........................................................................................ 5

3.3 Main components ....................................................................................................................... 6 3.4 Individual component functions .................................................................................................. 7

3.4.1 ICD board .......................................................................................................................... 7 3.4.2 CPU board......................................................................................................................... 8

4. Block Diagram................................................................................................................................... 9 5. Operating Configuration and Startup Procedure ......................................................................... 10

5.1 Simple software development configuration ............................................................................. 10 5.2 SVT17602 independent operation .......................................................................................... 13 5.3 ICD board firmware update procedures.................................................................................... 14

6. Differences between the ICD Board and ICD Mini........................................................................ 15 7. I/O Ports........................................................................................................................................... 16 8. Switch Settings ............................................................................................................................... 18

8.1 SW5 settings ............................................................................................................................ 18 8.2 SW4 settings ............................................................................................................................ 19 8.3 SW7/SW8/SW9 (PAD1 to 12) settings...................................................................................... 20

9. CPU Board Key Input Circuit ......................................................................................................... 22 10. Infrared emitter LED/Photo-receiver Module.............................................................................. 23

10.1 Infrared unit emitting/receiving.................................................................................................. 24 10.2 Infrared photo-receiver module power supply switch................................................................ 24

11. LCD Panel ...................................................................................................................................... 25 11.1 LCD panel segment allocation.................................................................................................. 26

12. Serial Interfaces ............................................................................................................................ 27 13. Thermistor (RFC ch.0) .................................................................................................................. 28

13.1 Resistance sensor measurement DC oscillation mode ............................................................ 29 13.2 Resistance sensor measurement AC oscillation mode............................................................. 30

14. Humidity Sensor (RFC ch.1) ........................................................................................................ 31 14.1 Resistance sensor measurement AC oscillation mode............................................................. 32

Table of Contents

ii EPSON S5U1C17602T1100 Hardware Manual

14.2 Resistance sensor measurement DC oscillation mode ............................................................ 33 15. Illuminance Sensor ....................................................................................................................... 34

15.1 Illuminance sensor power supply switch................................................................................... 34 16. LEDs............................................................................................................................................... 35 17. Expansion Interfaces.................................................................................................................... 36

17.1 JICD connector ....................................................................................................................... 37 17.2 JEX connector ........................................................................................................................ 38 17.3 JEX2 connector ...................................................................................................................... 39 17.4 JEX/JEX2 connector dimensional diagram............................................................................. 40 17.5 JRIF connector ......................................................................................................................... 41 17.6 JRIF mounting diagram ............................................................................................................ 42 17.7 SPI port connector selection using analog switch..................................................................... 43

Appendix A Consumption Current Measurement Method for Individual IC................................ 44 Appendix B Consumption Current Measurement Method for Entire SVT17602 Board.............. 45

1. Features

S5U1C17602T1100 Hardware Manual EPSON 1

1. Features The S5U1C17602T1100 (SVT17602: Software Evaluation Tool for S1C17602) is an evaluation board for the S1C17602 MCU made by Seiko Epson.

The SVT17602 consists of a CPU board and an ICD board connected for software debugging, eliminating the need to connect a separate ICD debugging tool.

It also incorporates serial expansion ports to let users connect their own expansion boards.

<CPU board>

CPU S1C17602

Input power supply voltage +3.3 V DC (supplied through the ICD interface or by a CR2032 button cell)

CPU input clock OSC1: 32.768 kHz

OSC3: 6 MHz

Functions/devices • Reset switch

• Expansion interface connectors (P, UART, I2C, SPI)

• ICD board connector

• Thermistor

• Humidity sensor

• Illuminance sensor

• Key input (2 keys)

• Lever and push-switch

• Infrared emitters/photo-receiver module

• STN LCD panel (display size: 36 segments x 8 common B/W)

<ICD board>

PC interface USB 1.1

Power supply voltage USB bus power (onboard regulator output voltage: 3.3 V)

Functions/devices • Status display LED (3-color)

• Reset switch

• CPU board connector

2. Package Contents

2 EPSON S5U1C17602T1100 Hardware Manual

2. Package Contents The S5U1C17602T1100 package contains the following items.

(1) SVT17602 CPU board (main unit)................................................................................... 1

(2) SVT17602 ICD board ...................................................................................................... 1

(3) USB cable ........................................................................................................................ 1

(4) Coin cell (CR2032/3V) .................................................................................................... 1

(5) Warranty card........................................................................ 1 in English & 1 in Japanese

(6) Precautions............................................................................ 1 in English & 1 in Japanese

(7) Manual downloading instructions ......................................... 1 in English & 1 in Japanese

3. Part Names and Functions


3. Part Names and Functions 3.1 Part names The part names and functions are as shown below.

Figure 3.1 Upper side component names

Figure 3.2 Underside component names



3.2 Board dimensional diagram

3.2.1 CPU board dimensional diagram The CPU board dimensional diagram is shown below.

<Upper side>

Figure 3.3 CPU board dimensional diagram (upper side)

<Underside>

Figure 3.4 CPU board dimensional diagram (underside)



3.2.2 ICD board dimensional diagram The ICD board dimensional diagram is shown below.

<Upper side>

Figure 3.5 ICD board dimensional diagram (upper side)

<Underside>

Figure 3.6 ICD board dimensional diagram (underside)



3.3 Main components <CPU board>

CPU (U7)....................................................................S1C17602................................ SEIKO EPSON CORP.

Crystal oscillator (32.768 kHz) (X1) ..........................FC-255 ....................................EPSON TOYOCOM CORP.

Crystal oscillator (6 MHz) (X2)..................................MA-406...................................EPSON TOYOCOM CORP.

Reset switch (SW6) ....................................................SKQTLCE010 ........................ALPS

LCD panel ..................................................................Custom-made ..........................Epson custom-made component

Thermistor (R32) ........................................................103AP-2.................................. Ishizuka

Humidity sensor (R31)................................................C10-M53R .............................. SHINYEI TECHNOROGY

Illuminance sensor (U2)..............................................TPS856 ...................................TOSHIBA

Expansion board connector (JEX) ..............................SLW-110-01-G-D................... SAMTEC

Expansion board connector (JEX2) ............................SLW-105-01-G-D................... SAMTEC

Expansion board connector (JICD).............................PS-10SD-D4T1-1.................... JAE

Expansion board connector (JRIF) (not mounted) ......8913-020-178MS-A-F ............KEL

Key switch (SW1, SW2).............................................SKRAAKE010........................ALPS

Lever and push-switch (SW3) ....................................SLLB5.....................................ALPS

Infrared emitters (D1) .................................................AN333..................................... STANLEY

Infrared photo-receiver module (U1) ..........................PNA4702M............................. Panasonic

Battery holder (V1).....................................................BA2032SM .............................TAKACHI

Coin cell......................................................................CR2032(3V)

<ICD board>

USB mini-B connector................................................54819-0572 .............................molex

LED(RGB) .................................................................598-9920-307F........................Dialight

Reset switch (SW1) ....................................................SKRAAKE010........................ALPS



3.4 Individual component functions

3.4.1 ICD board The ICD board is a hardware tool (emulator) designed to make S1C17602 software development more efficient. It provides a simple S1C17602 software development configuration by controlling communications between the PC and the target IC (S1C17602) on the CPU board. Refer to Section 6 for detailed information on functional differences from the S5U1C17001H development tool ICD Mini, which supports all S1C17 core products.

* The C17/C33 core selector switch (SW2) in Figure 3.7 should be set to “C17” at all times. Note that operation is not possible if this switch is set to “C33.”

Figure 3.7 C17/C33 core selector switch

ICD board Reset switch

Pressing the ICD board Reset switch (SW1) reboots the ICD board firmware and outputs a target reset signal (#RESET_OUT) to the CPU board. The connection required for communications is complete once the ICD board is physically connected to the CPU board. A wait status remains until this physical connection is made.

ICD board LED

This LED displays different colors to indicate the ICD board and target status.

(blue) Power on (before target and initial connection is established) (green) Target is in debugging mode. (red) Target is not connected or is not connected correctly.

Target is running a user program.



3.4.2 CPU board The CPU board is a simple target evaluation board on which the target CPU (S1C17602) is mounted. It also includes peripheral components and circuits such as an LCD panel, temperature/humidity/illuminance sensors, and infrared emitters/photo-receiver module and can be used to develop and evaluate control software for these components.

CPU board Reset switch

Press the CPU board Reset switch (SW6) to reset the CPU board.

Coin cell

The underside of the CPU board features a coin cell (CR2032) holder. Power is supplied by a coin cell if the CPU board is used on its own. When used connected to the ICD board, power is automatically supplied from the ICD board by the switching circuit on the CPU board, in which case power from the coin cell is automatically switched off.

4. Block Diagram


4. Block Diagram The block diagrams for the SVT17602 CPU and ICD boards are shown below.

Figure 4.1 CPU board block diagram

Figure 4.2 ICD board block diagram

5. Operating Configuration and Startup Procedure



The SVT17602 can be operated in accordance with commands executed on a PC debugger by connecting to a PC via the ICD board. The CPU board can also be used on its own without the ICD board or a PC. The corresponding connection configurations and startup procedures are described below.

5.1 Simple software development configuration The SVT17602 provides a simple S1C17602 software development configuration for the CPU board as a target by connecting to a PC via the ICD board and using in conjunction with the S1C17 development tools on the PC (e.g., GNU17 IDE, compiler, and debugger provided as part of the S5U1C17001C package).

Figure 5.1 Simple software development configuration

Simple software development configuration

In this operating configuration, the target CPU (S1C17602 on the CPU board) is controlled by commands executed on the debugger in the PC connected to the IC board. Commands issued by the debugger are sent via USB to the ICD board, where they are analyzed, then converted to S1C17602 debugging signals and sent to the CPU board. Programs and data can be downloaded from the PC debugger to the CPU board for debugging by starting and stopping program execution.

CPU operation mode

The target CPU (S1C17602 on CPU board) halts target program operations following a brk command or debug interrupt (e.g., forced break operations on the debugger) from the ICD board, then switches to debug mode (break state). This state allows commands to be executed from the PC debugger. The ICD board LED illuminates in green for debug mode. The target program is executed by the target CPU in a state called normal mode. The ICD board LED illuminates in red for normal mode.

Connections and startup

The connection and startup procedures for the simple software development configuration are described below.

(1) Connect the CPU board to the ICD board. (Connect the two JICD 10-pin connectors. Refer to Section 2 for the connection diagram.)

(2) Connect the PC to the ICD board using a USB cable.

(3) Install the appropriate USB driver from the driver install screen that appears on the PC monitor. (This step is performed for first-time use only and is not repeated for subsequent connections.) Refer to the following “Installing the USB driver” section for installation procedure specifics.

(4) Confirm that the ICD board LED changes from blue to green (indicating target debug mode).

(5) Launch IDE on the PC and run the program using GDB launched by IDE. Confirm that the LED changes to red (target in normal mode) while the program is running.



For detailed information on using the debugger and debugging commands, refer to the S5U1C17001C Manual (S1C17 Family C Compiler Package).

Note: Never disconnect the USB cable between the PC and ICD board while the debugger is running.

Installing the USB driver

(1) The following screen appears when the SVT17602 is connected to the host computer via a USB cable.

(2) Install the USB driver according to directions provided by the install wizard.

Specify “C:\EPSON\GNU17\utility\drv_usb” for the USB driver directory.

* This path specifies the path at which the IDE is installed.



The Device Manager appears as shown below once the USB driver is successfully installed.

Note: If the screen does not appear as shown above, re-install the USB driver.



5.2 SVT17602 independent operation The SVT17602 can be used as a CPU board by itself, without the ICD board or PC.

Independent operation

In this operating configuration, the S1C17602 on the CPU board operates in normal mode and runs the program written to internal flash memory. This means the user program must be downloaded to S1C17602 internal flash memory beforehand. (The SVT17602 is shipped with demo programs stored on internal flash memory.) For instructions on downloading user programs to internal flash memory, refer to the S5U1C17001C Manual (S1C17Family C Compiler Package).

Connections and startup

The procedures for operating the SVT17602 by itself are given below.

(1) Turn on the PC (only if turned off).

(2) With the CPU board connected to the ICD board, connect the PC to the ICD board using a USB cable.

(3) Launch the PC debugger and download the user program to S1C17602 internal flash memory. For instructions on downloading programs, refer to the S5U1C17001C Manual (S1C17Family C Compiler Package).

(4) Once the debugger has finished running, disconnect the USB cable to separate the ICD board from the PC.

(5) Remove the ICD board from the CPU board and insert the coin cell.

(6) Turn on the power control switch (SW5).

(7) Press the CPU board Reset switch. The S1C17602 on the CPU board executes the user program downloaded to flash memory.



5.3 ICD board firmware update procedures The SVT17602 allows the ICD board firmware to be updated using the PC debugger. The ICD board firmware is available from Seiko Epson, as required. (The update file has the file extension “.sa.”)

The firmware update procedure is described below.

Note: The USB driver must be installed before updating the firmware.

(1) Using a USB cable, connect the SVT17602 ICD board to the PC.

(2) Press the ICD board Reset switch (SW1).

(3) Launch the debugger from the command prompt.

>cd c:\EPSON\gnu17 (Specifies the path at which the gnu17 tool was installed.)

>gdb

(4) Enter the following commands once the debugger is running.

(gdb) target icd usb

(gdb) c17 firmupdate path\filename.sa

(For “path\filename.sa,” specify the name of the file to be updated.)

(5) The process is complete when the ICD board LED illuminates in green ( ).

(6) Press the ICD board Reset switch to restart the firmware.

6. Differences between the ICD Board and ICD Mini


6. Differences between the ICD Board and ICD Mini

Table 6.1 compares specifications for the S5U1C17001H (ICD Mini) S1C17 Family development tool and the SVT17602 ICD board. The SVT17602 includes an ICD Mini interface, however, note that the ICD board and ICD Mini cannot be connected at the same time. For detailed information on using the ICD Mini, refer to the S5U1C17001H User Manual.

Table 6.1 Comparison of ICD Board and ICD Mini Functions

Product S5U1C17000H (ICD Mini)

S5U1C17602T1100(SVT17602) ICD board

Core supported S1C17 core

Host interface USB1.1

Communication frequency with target (DCLK frequency)

4 kHz to 40 MHz

Independent flash writing function Yes No

Firmware update function Yes

Flash write power supply Yes No

Reset signal output to target Yes

Target system I/O compatible voltage 3.3 V, 1.8 V, voltage input from target (1.0 V to 5.0 V) 3.3 V

Target connector 4-pin 10-pin (including reset signal) *1

Flash write power supply connector *2 4-pin －

*1 For connection to the CPU board only.

*2 The S1C17602 does not require a separate power supply for flash writing.

7. I/O Ports


7. I/O Ports Table 7.1 lists S1C17602 ports and SVT17602 connection targets.

For detailed information on expansion interfaces and connectors, refer to Section 17.

Table 7.1 I/O port function list

Port Direction Multiplex Signal Connected to

P00 I/O REMC P00/REMO Infrared emitters (D1)

P01 I/O REMC P01/REMI Infrared photo-receiver module (U1)

P02 I/O Timer P02/EXCL0 Key input (SW1)

P03 I/O ADTRG P03/#ADTRG Lever & push-switch and expansion I/F (connector: JEX2)

P04 I/O SPI P04/SPICLK Switch IC (U13) → Expansion I/F (connector: JEX) or expansion I/F (connector: JRIF)

P05 I/O SPI P05/SDO Switch IC (U11) → Expansion I/F (connector: JEX) or expansion I/F (connector: JRIF)

P06 I/O SPI P06/SDI Switch IC (U9) → Expansion I/F (connector: JEX) or expansion I/F (connector: JRIF)

P07 I/O SPI P07/#SPISS Expansion I/F (connector: JEX2) and expansion I/F (connector: JRIF)

P10 I/O UART P10/SCLK0 Expansion I/F (connector: JEX)

P11 I/O UART P11/SOUT0 Expansion I/F (connector: JEX) and expansion I/F (connector: JRIF)

P12 I/O UART P12/SIN0 Expansion I/F (connector: JEX) and expansion I/F (connector: JRIF)

P13 I/O Timer/ADC P13/EXCL1/AIN7 Expansion I/F (connector: JEX2) and switch IC (U4) → LED (D5)

P14 I/O Timer/ADC P14/EXCL2/AIN6 Expansion I/F (connector: JEX)

P15 I/O Timer/ADC P15/EXCL3/AIN5 Key input (SW2) and expansion I/F (connector: JEX)

P16 I/O UART/ADC P16/SCLK1/AIN4 Switch IC

P17 I/O ADC P17/AIN3 Expansion I/F (connector: JEX)


P21 I/O ADC P21/AIN1 Illuminance sensor (U2) and expansion I/F (connector: JEX)


P23 I/O RFC P23/SENB0 Thermistor

P24 I/O RFC P24/SENA0 Thermistor

P25 I/O RFC P25/REF0 Thermistor

P26 I/O RFC P26/RFIN0 Thermistor

P27 I/O UART/RFC P27/SOUT1/RFIN1 Humidity sensor

P30 I/O UART/RFC P30/SIN1/REF1 Humidity sensor

P31 I/O I2C/RFC P31/SCL0/SENA1 Humidity sensor or expansion I/F (connector: JEX2)

P32 I/O I2C/RFC P32/SDA0/SENB1 Humidity sensor or expansion I/F (connector: JEX2)

P33 I/O I2C/RFC P33/SCL1/SCL0 Expansion I/F (connector: JEX)

P34 I/O I2C/RFC P34/SDA1/SDA0 Expansion I/F (connector: JEX)

P35 I/O FOUT/Memory P35/FOUT1/#BFR Expansion I/F (connector: JEX)

7. I/O Ports


Port Direction Multiplex Signal Connected to

P36 I/O TOUT/RFC P36/TOUT3 /RFCLKO

Lever & push-switch and expansion I/F (connector: JEX2)

P37 I/O TOUTN /LFRO/TOUT

P37/TOUTN3 /LFRO/TOUT4

Lever & push-switch and expansion I/F (connector: JEX2)

P40 I/O FOUT P40/FOUTH Expansion I/F (connector: JEX2) and switch IC (U4) → LED (D4)

P41 I/O Debugger P41/DSIO Expansion I/F (connector: JICD and JICDM)

P42 I/O Debugger P42/DST2 Expansion I/F (connector: JICD and JICDM)

P43 I/O Debugger P43/DCLK Expansion I/F (connector: JICD and JICDM)

8. Switch Settings


8. Switch Settings The underside of the SVT17602 has one side slide switch (SW5) and four DIP switches (SW4, SW7, SW8, SW9), as shown in Figure 8.1. The various switch settings are described below.

Figure 8.1 Switch locations (CPU board underside)

8.1 SW5 settings The SW5 switch is used to turn the power supply from the coin cell (CR2032) to the board on or off. The power supply from the coin cell is controlled via the circuit shown in Figure 8.2. This circuit helps minimize unnecessary battery power consumption by switching off the power supply when the board is not in use. (This switch is disabled when power is supplied by VDD_ICD from JICD as shown in Figure 8.2.)

Figure 8.2 Coin cell control switch circuit

8. Switch Settings


8.2 SW4 settings The SW4 switch is used to control the power supply to the infrared photo-receiver module (U1: PNA4702M), LED (D4, D5: SML-D12P8W, SML-D12V8W), and illuminance sensor (U2: TPS856). The power supply for the infrared photo-receiver module, LED, and illuminance sensor can be controlled via the circuit shown in Figure 8.3. This circuit minimizes unnecessary power consumption by switching off the power supply when the board is not in use.

* The infrared photo-receiver module is socket-mounted to permit removal if it is not needed.

Figure 8.3 Power supply switch (SW4) peripheral circuit

8. Switch Settings


8.3 SW7/SW8/SW9 (PAD1 to 12) settings The SW7, SW8, and SW9 switches are used to select external connections to allow enabling/disabling of the R/F converter (RFC) incorporated into the S1C17602 as well as differing RFC drive methods (DC/AC drive). Lands (PAD1 to 6) are also provided for inserting/removing the 0-Ω resistor between the pads for external connections linked to the RFC drive method selected by the switches. Lands (PAD7 to 12) also enable setting of the standard capacitance to 100 pF or 1,000 pF by inserting or removing the 0-Ω resistor between the pads.

Tables 8.1 and 8.2 give the RFC drive methods and standard capacitance for the various switch (SW7 to 9) and land (PAD1 to 12) settings. (The factory default settings are indicated in bold text in the tables below.)

* For detailed information on RFC drive method selection, refer to Sections 13 and 14 .

Table 8.1 RFC drive methods for SW7 to 9 settings

SW7 SW8 SW9

RFC I2C DC AC DC AC

RFC Ch.0 DC drive AC drive

RFC Ch.1 RFC I2C DC drive

(when SW7=RFC) AC drive

(when SW7=RFC)

Table 8.2 RFC drive methods and standard capacitance for PAD1 to 12 settings (when SW7=RFC)

PAD1 to 3 0-Ω resistor

PAD4 to 6 0-Ω resistor

PAD7 to 9 0-Ω resistor PAD10 to 12 0-Ω resistor

1 to 2 2 to 3 4 to 5 5 to 6 7 to 8 8 to 9 10 to 11 11 to 12

RFC Ch.0

AC drive

DC drive

Std capacitance 1,000 pF

Std capacitance 100 pF

RFC Ch.1

DC

drive AC

drive Std capacitance

1,000 pF Std capacitance

100 pF

8. Switch Settings


Figure 8.4 RFC function selector switch (SW7) and drive method selector switches (SW8, SW9) and PAD1 to 12

9. CPU Board Key Input Circuit


9. CPU Board Key Input Circuit Switches SW1 and SW2 on the SVT17602 CPU board are connected to the S1C17602 ports P02 and P15 as shown in Figure 9.1 below.

Figure 9.1 CPU board key input circuit

The input ports P02 and P15 are pulled up via a 47 kΩ resistance and normally maintained at High level (input = 1). Pressing the switch switches the port to Low level (input = 0).

10. Infrared emitter LED/Photo-receiver Module



The infrared emitters (AN333) and infrared photo-receiver module (PNA4702M) mounted on the SVT17602 CPU board are connected to the S1C17602 remote controller pins (P01/REMI and P00/REMO) as shown in Figure 10.1 below.

Figure 10.1 Infrared emitters/infrared photo-receiver module

Refer to the application note for detailed information on infrared emitters and infrared photo-receiver module control.



10.1 Infrared unit emitting/receiving Two SVT17602 units can be used as shown in Figure 10.2 to transmit and receive remote control signals.

Figure 10.2 Transmitting and receiving using two units

* As a guide, the maximum separation allowing transmission in this case is approximately 3 m with the photo-emitter LED and photo-receiver module facing each other with no intervening obstructions. Figure 10.3 shows the waveforms observed for transmitted/received waveforms (1) to (3) in Figure 10.1 in this case.

Figure 10.3 Infrared remote controller transmission waveforms

10.2 Infrared photo-receiver module power supply switch The power supply for the infrared photo-receiver module (PNA4702M) mounted on the SVT17602 can be turned on and off using switch SW4-1. Turning off this switch reduces unnecessary current consumption for the entire board when the infrared photo-receiver module is not in use.

* The infrared photo-receiver module is socket-mounted to permit removal if it is not needed.

11. LCD Panel


11. LCD Panel The S1C17602 features a segment LCD driver capable of driving a monochrome LCD panel of up to 288 segments (36 segments (SEG) x 8 common (COM)). The CPU board includes a segment-type LCD panel for evaluating functions of the LCD driver on the S1C17602 and is connected to the S1C17602 SEG/COM pins as shown in the diagram below.

Figure 11.1 LCD panel connection

11. LCD Panel


11.1 LCD panel segment allocation The segment allocation diagram for the SVT17602 LCD panel is shown below, together with the segment/common allocation chart for the LCD panel pin arrangement.

Figure 11.2 LCD panel segment allocation diagram

Figure 11.3 LCD panel segment/common allocation chart

Refer to the application note for detailed information on LCD panel control.

12. Serial Interfaces


12. Serial Interfaces The SVT17602 allows the use of three serial interfaces (UART x 2ch, SPI x 1ch, I2C x 2ch (1 master/1 slave)) incorporated into the S1C17602. The general input/output port pins on the S1C17602 double as serial port pins. Functions must be selected by selecting the analog switch via software and the DIP switch when they are used as serial ports.

The serial port input/output signals are shown in the table below.

Table 12.1 Serial port

Interface Signal (Port pin) I/O Connected to

SPICLK (P04) I/O Expansion I/F (JEX pin 13 or JRIF pin 8)

SDO (P05) O Expansion I/F (JEX pin 12 or JRIF pin 4)

SDI (P06) I Expansion I/F (JEX pin 11 or JRIF pin 3)

SPI

#SPISS (P07) I Expansion I/F (JEX2 pin 3 and JRIF pin 6)

SCLK0 (P10) I Expansion I/F (JEX pin 2)

SOUT0 (P11) O Expansion I/F (JEX pin 3 and JRIF pin 16)

UART ch.0

SIN0 (P12) I Expansion I/F (JEX pin 4 and JRIF pin 17)

SCLK1 (P16) I Check pin (TP9) and analog switch (U4, U6, U9, U11, U13) control

SOUT1 (P27) O Check pin (TP10) and humidity sensor control circuit (PAD4, PAD11)

UART ch.1

SIN1 (P30) I Check pin (TP11) and humidity sensor control circuit (PAD5)

SDL0 (P31) I/O SW7 → Expansion I/F (JEX2 pin 5) I2C (Master only) *1 SDA0 (P32) I/O SW7 → Expansion I/F (JEX2 pin 6)

SDL1/SDL0 (P33) I/O Expansion I/F (JEX pin 10) I2C (Master/Slave) *1 SDA1/SDA0 (P34) I/O Expansion I/F (JEX pin 9)

*1. The S1C17602 includes two I2C channels, one for the master function and one for the slave function. Master functions cannot be used for P33/P34 when the I2C master is used for P31/P32. Likewise, the master functions cannot be used for P31/P32 when the master is used for P33/P34.

13. Thermistor (RFC ch.0)


13. Thermistor (RFC ch.0) The thermistor mounted on the SVT17602 CPU board is connected to the S1C17602 R/F converter (RFC) ch.0, as shown in Figure 13.1 below.

Figure 13.1 Thermistor (resistance sensor measurement DC oscillation mode) peripheral circuit



13.1 Resistance sensor measurement DC oscillation mode Figure 13.1 shows the default wiring configuration for the thermistor (103AP-2) mounted on the SVT17602 CPU board. This sensor is connected in resistance sensor measurement DC oscillation mode. (See Table 8.1 & 8.2 ⇒ “DC drive.”)

Up to two resistance sensors can be connected in resistance sensor measurement DC oscillation mode. In addition to the thermistor shown in Figure 13.1, a second resistance sensor can be connected at the J7 position. The default thermistor connected is socket-mounted to permit removal. The 103AP-2 connected in the default configuration can be removed to enable connection of another sensor for evaluation.

The default standard capacitance is 1,000 pF.

The standard capacitance affects the R/F conversion rate and accuracy. Increasing the standard capacitance increases conversion accuracy, while reducing capacitance increases conversion rate.

Refer to the application note for detailed information on controlling the thermistor connected in resistance sensor measurement DC oscillation mode.

* Refer to the S1C17602 technical manual for detailed information on resistance sensor measurement DC oscillation mode.



13.2 Resistance sensor measurement AC oscillation mode The SVT17602 RFC ch.0 can also be connected to a sensor in resistance sensor measurement AC oscillation mode, as shown in the circuit illustrated in Figure 13.2. (See Table 8.1 & 8.2 ⇒ “AC drive.”)

* Refer to the S1C17602 technical manual for detailed information on resistance sensor measurement AC oscillation mode.

Figure 13.2 Resistance sensor measurement AC oscillation mode peripheral circuit

14. Humidity Sensor (RFC ch.1)


14. Humidity Sensor (RFC ch.1) The humidity sensor mounted on the SVT17602 CPU board is connected to the S1C17602 R/F converter (RFC) ch.1 as shown in Figure 14.1 below.

Figure 14.1 Humidity sensor (resistance sensor measurement AC oscillation mode) peripheral circuit



14.1 Resistance sensor measurement AC oscillation mode Figure 14.1 shows the default wiring configuration for the humidity sensor (C10-M53R) mounted on the SVT17602 CPU board. This sensor is connected in resistance sensor measurement AC oscillation mode. (See Table 8.1 & 8.2 ⇒ “AC drive.”)

* SENA1 and SENB1 for RFC ch.1 of the S1C17602 are multiplexed with I2C. SW7 must be switched to “RFC” when using RFC. (See Table 8.1.)

The default humidity sensor (R31) connected is socket-mounted to permit removal. The C10-M53R connected in the default configuration can be removed to enable connection of another sensor for evaluation.

The default standard capacitance is 1,000 pF.

The standard capacitance affects the R/F conversion rate and accuracy. Increasing the standard capacitance increases conversion accuracy, while reducing capacitance increases conversion rate.

Refer to the application note for detailed information on controlling the humidity sensor connected in resistance sensor measurement AC oscillation mode.

* Refer to the S1C17602 technical manual for detailed information on resistance sensor measurement AC oscillation mode.



14.2 Resistance sensor measurement DC oscillation mode SVT17602 RFC ch.1 can also be connected to a sensor in resistance sensor measurement DC oscillation mode, as shown in the circuit illustrated in Figure 14.2. (See Table 8.1 & 8.2 ⇒ “DC drive.”)

* Refer to the S1C17602 technical manual for detailed information on resistance sensor measurement DC oscillation mode.

Figure 14.2 Resistance sensor measurement DC oscillation mode peripheral circuit

15. Illuminance Sensor


15. Illuminance Sensor The illuminance sensor mounted on the SVT17602 CPU board is connected to the S1C17602 AD converter as shown in Figure 15.1 below.

Figure 15.1 Illuminance sensor peripheral circuit

Refer to the application note for detailed information on illuminance sensor control.

15.1 Illuminance sensor power supply switch The power supply for the illuminance sensor (TPS856) mounted on the SVT17602 can be turned on and off using switch SW4-3. Turning off this switch reduces unnecessary current consumption for the entire board when the illuminance sensor is not in use.

16. LEDs


16. LEDs The SVT17602 CPU board includes a red LED (SML-D12V8W) and green LED (SML-D12P8W), as shown in Figure 16.1, which are controlled via the S1C17602 ports (P13, P16, P40).

SW4-2 is used on the SVT17602 to control the VDD supplied to the LEDs. SW4-2 must be turned on to use the LEDs.

The S1C17602 LED control ports (P13, P40) are connected to the LEDs via an analog switch IC, as shown in Figure 16.1. The analog switch IC is controlled by port P16 on the S1C17602.

Table 16.1 shows the LED status for the various port settings when SW4-2 is on.

Figure 16.1 LED peripheral circuit

Table 16.1 LED status chart for different port settings (when SW4-2 is on)

P16=High P16=Low

P13=High P13=Low P40=High P40=Low P13=High P13=Low P40=High P40=Low

Red LED (SML-D12V8W)

On (illuminated) OFF - - OFF OFF - -

Green LED (SML-D12P8W)

- - On

(illuminated)OFF - - OFF OFF

17. Expansion Interfaces


17. Expansion Interfaces The CPU board includes expansion interface connectors (JICD, JEX, JEX2) and an expansion connector mounting pattern (JRIF) to enable connection of an ICD board or user expansion boards.

*1: The S1C17602 includes two I2C channels, one for the master function and one for the slave function. The I2C from JEX cannot be used as master when the I2C (master only) from JEX2 is used. Likewise, the I2C (master only) from JEX2 cannot be used when the I2C from JEX is used as master.

Figure 17.1 Expansion interface connectors



17.1 JICD connector The JICD connector is used to connect the ICD board.

The connector specifications and pin layout are shown below.

Table 17.1 JICD connector pin layout and connector diagram

JICD connector

(Diagram on the right shows a connector side view.) Manufacturer: Japan Aviation Electronics Industry, Ltd. (JAE) Code: PS-10SD-D4T1-1 (female) <ICD board side> Manufacturer: Tyco Code: 9-103801-0 (male)

No. Name I/O Function

1 DCLK O On-chip debugger clock output port

2 GND - Power supply ground (Connecting to all pins is recommended.)


4 #RESET_OUT I Target reset signal input port

5 DSIO I/O On-chip debugger data input/output port

6 TGT_EN I Target enable signal input/output port

7 DST2 O On-chip debugger status signal output port

8 N.C - -

9 VCC (+3.3V) - +3.3 V power supply pin


Note: Make the connection so that the CPU board LCD panel surface and ICD board USB connector mounting surface face up. Note that connecting this connector incorrectly may damage both boards.

<CPU board side view>

<ICD board side view>

<ICD board> <CPU board>



17.4 JEX/JEX2 connector dimensional diagram The dimensional diagram for the JEX and JEX2 connectors described above is shown below.

(While JEX is 20-pin and JEX2 is 10-pin, the dimensions shown below are common to both JEX and JEX2 connectors.)

Figure 17.2 JEX/JEX2 connector dimensional diagram



17.5 JRIF connector The JRIF connector is used to connect a user expansion board.


Table 17.4 JRIF connector pin layout and connector diagram

JRIF connector

Manufacturer: KEL Corporation Code: 8913-020-178MS-A-F (not mounted) No. Name I/O Function

1 N.C - -

2 N.C - -

3 P06/SDI I/O | I General input/output port | SPI data input port

4 P05/SDO I/O | O General input/output port | SPI data output port


6 P07/#SPISS I/O | I General input/output port | SPI slave select input


8 P04/SPICLK I/O | I/O General input/output port | SPI external clock input/output port


10 N.C - -


12 N.C - -


14 N.C - -


16 P11/SOUT0 I/O | O General input/output port | UART ch0 data output port

17 P12/SIN0 I/O | I General input/output port | UART ch0 data input port

18 N.C - -

19 VDD (+3.3V) - +3.3 V power supply pin

20 VDD (+3.3V) - +3.3 V power supply pin

JRIF



17.6 JRIF mounting diagram The mounting diagram for the JRIF connector described above is shown below.

Figure 17.3 JRIF mounting diagram



17.7 SPI port connector selection using analog switch The S1C17602 SPI input/output signal is connected to both the JEX2 connector and the JEX or JRIF connector via the analog switch, as shown in Figure 17.4. The analog switch IC is controlled by the S1C17602 P16 port and is connected to JRIF when the P16 output is “High” and to JEX when “Low.”

The #SPISS signal is also connected to both the JEX2 and JRIF connectors.

Table 17.5 shows the correlation between SPI signals and expansion connectors for various analog switch control port (P16) statuses.

Figure 17.4 SPI port connector selection circuit

Table 17.5 SPI signal and expansion connector correlation according to analog switch control port (P16) statuses

P16 = High output P16 = Low output

JEX JRIF JEX2 JEX JRIF JEX2

SPICLK Enabled Disabled - Disabled Enabled -

SDI Enabled Disabled - Disabled Enabled -

SDO Enabled Disabled - Disabled Enabled -

SPISS - Enabled Enabled - Enabled Enabled

Appendix A Consumption Current Measurement Method for Individual IC


Appendix A Consumption Current Measurement Method for Individual IC

The SVT17602 CPU board enables measurement of current consumed for just the S1C17602.

The current consumed by the S1C17602 itself can be measured by removing the jumper (J2) for VDD and VDD2 on the SVT17602 CPU board and inserting an ammeter between them, as shown in the circuit layout diagram in Figure A.1. The various S1C17602 ports must be set appropriately for the peripheral circuits.

Refer to the S1C17602 IC current consumed measuring application note for detailed information on the sampling software (software flow) used to set these ports and to measure the current consumed.

Figure A.1 Consumption current measurement circuit for individual SVT17602 IC

Appendix B Consumption Current Measurement Method for Entire SVT17602 Board


Appendix B Consumption Current Measurement Method for Entire SVT17602 Board

The SVT17602 CPU board enables measurement of current consumed for the entire SVT17602 board while powered by the coin cell.

Figure B.1 shows the SVT17602 CPU board coin cell peripheral circuit. To measure current consumed for the entire SVT17602 board, remove the resistor (R4) and replace with an ammeter.

(Note that the current through FET (Q1, Q2) shown in Figure B-1 may not reflect the current measured by this method.)

When seeking to reduce overall current consumption for the board, consider the current that flows through the external components listed below.

(1) Current through infrared photo-receiver module

(2) Current through sensors

You can eliminate the current (1) through the infrared photo-receiver module by removing the module from its socket when it is not being used.

You can eliminate the current (2) through the illuminance sensor by turning off the power supply switch (SW4-3) when the illuminance sensor is not being used. Just as for the infrared photo-receiver module, the current through the temperature and humidity sensors can be eliminated by removing the sensors from their sockets when they are not being used.

Refer to the SVT board current consumed measuring application note for detailed information on measuring overall current consumed by the board and for software examples that reduce overall board current consumption.

Figure B.1 Consumption current measurement circuit for entire SVT17602 board

+3V3

USBVCCUSB_VBUS

USBVCC +3V3

+3V3 +1V8

+3V3

+3V3 +3V3 +3V3

+3V3

+3V3

+3V3

+3V3

+3V3

VBUSON

C33DCLK

XRESET_OUTC33DSIOTGT_ENC33DST2

XRESET

LED01_0LED01_1LED01_2

USB_DMUSB_DP

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R1 OPENR1 OPEN

C12

4.7uF

C12

4.7uF

R5 22R5 22

U4

SN74LVC1G97

U4

SN74LVC1G97

IN11GND2IN03 Y 4VCC 5IN2 6

TP4

TH

TP4

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U1SN74LVC1G125

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1

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R3 0R3 0

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R247KR247K

FET1

TPC6103

FET1

TPC6103

D 1D 2G 3S4 D5 D6

C9

4.7uF

C9

4.7uF

R8100K

R8100K

C2

0.1uF

C2

0.1uF

R9 2.2KR9 2.2K

C5

0.1uF

C5

0.1uF

C100.1uFC100.1uF

C7 0.1uFC7 0.1uF

TP1

TH

TP1

TH

C4

22uF

C4

22uF

C1

0.1uF

C1

0.1uF

F1BLM21PG600SN1DF1BLM21PG600SN1D

TP8

PAD

TP8

PAD

TP5

TH

TP5

TH

R10 1.8KR10 1.8K

C11

4.7uF

C11

4.7uF

U7

S-1170B18UC

U7

S-1170B18UC

ON1VSS2NC3 VIN 4

VOUT 5

LED2

598-9920-307F

LED2

598-9920-307F

G1

R2

B3

AN 4

C6

0.1uF

C6

0.1uF

TP2

TH

TP2

TH

TP7

PAD

TP7

PAD

F2BLM21PG600SN1DF2BLM21PG600SN1D

CN1

PEC36DBAN

CN1

PEC36DBAN

DCLK1GND2GND3XRESET4DSIO5TGT_EN6DST27NC8VCC9VCC10

LED1

HBMGFRT825

LED1

HBMGFRT825

R 1

G 2

B 3B4

G5

R6

C8

4.7uF

C8

4.7uF

R6 22R6 22

TP6

TH

TP6

TH

R11 470R11 470

U6

S-1170B33UC

U6

S-1170B33UC

ON1VSS2NC3 VIN 4

VOUT 5

R7470KR7470K

TP3

TH

TP3

TH

CN254819-0572

CN254819-0572

VBUS 1D- 2D+ 3ID 4

GND 5FGND 6FGND 7FGND 8FGND 9

SW1SKRAAKE010SW1SKRAAKE010

1

2

3

4

U5 74LVC244U5 74LVC244

OE11

VCC20

I02I14I26I38

OE219

I417I515I613I711

O0 18O1 16O2 14O3 12O4 3O5 5O6 7O7 9

GND 10

Q1RN1104FQ1RN1104F

3

1

2

R41.5KR41.5K

U2 SN65240U2 SN65240

GND1C2GND3D4 GND 5B 6GND 7A 8

U3

S-1000N28

U3

S-1000N28

OUT 1

VDD 2NC3

VSS4

D6

D6

D10

D5

D7

A1

A13

A19

D2

A4

A8

A11

A12

A10

D14

D15

A3

A21

D14

A20

D4

A12

A15

D1

A9

D0

D3

D13

A18

D2

A17

A6

A9

A3

A5

D9

A7

A15

A22

A8

A6

A19

A1

A16D8

A2

D11D10

D3

A7

A18

D4

D7

D11

D8A10

D0

A11

A14

A14

A16

A17

A20

D1

D12

D15

A13

A5

A21

D12

A4

A2

D13

A22

D5

D9+3V3

+3V3

+3V3

+3V3+3V3

+3V3

+3V3

+3V3

+1V8+3V3

+3V3

+3V3

+1V8

USB_VBUS

+3V3

XRESET

LED01_0LED01_1LED01_2

TIMER

C33DST2

C33DSIO

SIO

SIO

P81P81

TGT_EN

C33DST2

XRESET

P10

P30

XRESET_OUT

C33DCLK

P12

TIMER

P31

P13

P32

P14

P11

P10P11P12P13P14P30P31P32

USB_DMUSB_DP

VBUSON

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R300R300

R19 33R19 33C16 0.1uFC16 0.1uF

C21

0.1uF

C21

0.1uF

R310R310

C17

9pF

C17

9pF

R24OPENR24OPEN

R18 0R18 0

R28OPENR28OPEN

U11TS5A3159A

U11TS5A3159A

NO 1

GND 2

NC 3COM4

V+5

IN6

C36

0.01uF

C36

0.01uF

R350R350

C18

9pF

C18

9pF

C26

0.01uF

C26

0.01uF

C22

0.1uF

C22

0.1uF

C40

1000pF

C40

1000pF

C20

1uF

C20

1uF

R23OPENR23OPEN

R174.7KR174.7K

C19

1uF

C19

1uF

C34

0.1uF

C34

0.1uF

R15

4.7K

R15

4.7K

R340R340

R27OPENR27OPEN

C14 0.1uFC14 0.1uF

C27

1000pF

C27

1000pF

R144.7K

R144.7K

R16OPEN

R16OPEN

C23

0.1uF

C23

0.1uF

C33

0.1uF

C33

0.1uF

C31

1uF

C31

1uF

C37

0.01uF

C37

0.01uF

CN3

9-103801-0

CN3

9-103801-0

1234

C38

1000pF

C38

1000pF

R330R330

U8 S29PL064JU8 S29PL064J

A0E1A1D1A2C1A3A1A4B1A5D2A6C2A7A2A8B5A9A5A10C5A11D5A12B6A13A6A14C6A15D6A16E6A17B2A18C3A19D4A20D3A21C4

XCEF1XOEG1XWEA4RY/XBYA3WP/ACCB3

XRESETB4

NC F6

VSS H6VSS H1

VCC G4

D0 E2D1 H2D2 E3D3 H3D4 H4D5 E4D6 H5D7 E5D8 F2D9 G2

D10 F3D11 G3D12 F4D13 G5D14 F5D15 G6

R26OPENR26OPEN

R201MR201M

C35

0.01uF

C35

0.01uF

R370R370

C28

1000pF

C28

1000pF

R134.7K

R134.7K

C130.1uF

C130.1uF

SW2

CHS-01B1

SW2

CHS-01B1

12

C24

0.01uF

C24

0.01uF

U9

S1C33E07

U9

S1C33E07

P00/SIN0/#DMAACK2E2P01/SOUT0/#DMAACK3F2P02/#SCLK0/#DMAEND2E3P03/#SRDY0/#DMAEND3F1P04/SIN1/I2S_SDOG2P05/SOUT1/I2S_WSF3P06/#SCLK1/I2S_SCKG1P07/#SRDY1/I2S_MCLKG3

P10/TM0/SIN0/#DMAEND0H1P11/TM1/SOUT0/#DMAEND1H2P12/TM2/#SCLK0/#DMAACK0J4P13/TM3/#SRDY0/#DMAACK1J2P14/TM4/SIN1H3

P20/SDCKED13P21/SDCLKD14P22/#SDCSC14P23/#SDRAS/TFT_CTL1C13P24/#SDCASB14P25/#SDWEB13P26/DQMLA13P27/DQMHB12

P30/CARD2/#DMAREQ0D1P31/CARD3/#DMAREQ1D3P32/CARD4/#DMAREQ2E4P33/CARD5/#DMAREQ3E1

P60/SIN2/DCSIO0/EXCL0L13P61/SOUT2/DCSIO1/EXCL1K12P62/#SCLK2/#ADTRG/CMU_CLKJ12P63/#SRDY2/WDT_CLK/#WDT_NMIK14P64/#WAIT/EXCL2K3P65/SDI/FPDAT8M2P66/SDO/FPDAT9M3P67/SPICLK/FPDAT10N1

P70/AIN0N6P71/AIN1M6P72/AIN2N7P73/AIN3M5P74/AIN4/EXCL5N5

P80/FPFRAMEP7P81/FPLINEL6P82/FPSHIFTL7P83/FPDRDY/TFT_CTL1/BCLKM7P84/DCSIO0/FPDAT11L8P85/DCSIO1M8

#RESETN13#NMIM13

BO

OT0

K13

BO

OT1

L5

VC

PN

4

DS

IO/P

34K

1D

CLK

/P35

L1D

ST2

/P36

K4

DS

T1/P

16/D

CS

IO0/

#SC

LK1/

TFT_

CTL

3J3

DS

T0/P

15/T

M5/

SO

UT1

/TFT

_CTL

0J1

DP

CO

/P17

/DC

SIO

1/#S

RD

Y1/

TFT_

CTL

2K

2

MC

LKI

P8

MC

LKO

P9

RTC

CLK

1P

2

RTC

CLK

OP

3

TES

T0M

4

BU

RN

INM

9

NC

P1

NC

P14

NC

A14

NC

A1

PLL

VS

SP

4

VS

SD

11V

SS

D6

VS

SD

5V

SS

D4

VS

SN

9V

SS

N3

VS

SE

11V

SS

E10

VS

SE

5V

SS

J11

VS

SJ1

0V

SS

J5V

SS

K11

VS

SK

10V

SS

K6

VS

SK

5

USBDP M14USBDM N14USBVBUS L14

PB3/FPDAT11/I2S_MCLK/CARD5 M1PB2/FPDAT10/I2S_SCK/CARD4 L3PB1/FPDAT9/I2S_WS/CARD3 L4PB0/FPDAT8/I2S_SDO/CARD2 L2

PA4/FPDAT11/TFT_CTL3/CARD1 P13PA3/FPDAT10/TFT_CTL2/CARD0 P12PA2FPDAT9/TFT_CTL1 L12PA1/FPDAT8/TFT_CTL0 N11PA0/TFT_CTL0 P11

P97/FPDAT7 M12P96/FPDAT6 N12P95/FPDAT5 N10P94/FPDAT4 M11P93/FPDAT3 M10P92/FPDAT2 P10P91/FPDAT1 L11P90/FPDAT0 L10

#RD A5#WRH/#BSH B4#WRL C5

#CE11/P56 A4#CE10/P57 B5#CE9/P55/CARD0 B2#CE8/P54/CARD1 A2#CE7/P53/SDA10 A10P52/BCLK/#CE6/CMU_CLK C4#CE5/P51/CARD1 B3#CE4/P50/CARD0 A3

D15/PC7 E14D14/PC6 C12D13/PC5 D12D12/PC4 E13D11/PC3 F12D10/PC2 E12D9/PC1 F13D8/PC0 F14D7 G13D6 G14D5 G12D4 H14D3 H13D2 H12D1 J14D0 J13

A24

/P40

/EX

CL4

/#S

DC

AS

C6

A23

/P41

/EX

CL3

/#S

DR

AS

A6

A22

/P42

/FP

DA

T8C

1A

21/P

43/F

PD

AT9

C3

A20

/P44

/FP

DA

T10

C2

A19

/P45

/FP

DA

T11

D2

A18

/P46

/TFT

_CTL

2B

1A

17/D

QM

HB

10A

16/D

QM

LC

11A

15A

11A

14A

12A

13B

6A

12C

7A

11/P

47A

7A

10B

7A

9C

8A

8A

8A

7D

9A

6B

8A

5D

10A

4A

9A

3C

9A

2B

9A

1C

10A

0/#B

SL

B11

VD

DD

7V

DD

N8

VD

DN

2V

DD

E7

VD

DE

6V

DD

F11

VD

DF1

0V

DD

H5

VD

DH

4V

DD

K7

VD

DG

11V

DD

G4

PLL

VD

DP

5

AV

DD

P6

VD

DH

L9V

DD

HD

8V

DD

HF5

VD

DH

F4V

DD

HH

11V

DD

HH

10V

DD

HK

9V

DD

HK

8V

DD

HG

10V

DD

HG

5V

DD

HE

9V

DD

HE

8

R22OPENR22OPEN

R210R210

C39

1000pF

C39

1000pF

R320R320

C30

1uF

C30

1uF

R25OPENR25OPEN

R360R360

C150.22uF

C150.22uF

U10SN74LVC1G97U10SN74LVC1G97

IN11GND2IN03 Y 4VCC 5IN2 6

R29OPENR29OPEN

C29

1000pF

C29

1000pF

R12100K

R12100K

TP9PADTP9PAD

TP11

PAD

TP11

PAD

XTAL1

FA-238

XTAL1

FA-238

IN1GND2 OUT 3GND 4

C25

0.01uF

C25

0.01uF

TP10PAD

TP10PAD

C32

0.1uF

C32

0.1uF

10

10

9

9

8

8

7

7

6

6

5

5

4

4

3

3

2

2

1

1

H H

G G

F F

E E

D D

C C

B B

A A

SEG35SEG34SEG33SEG32SEG31SEG30SEG29SEG28SEG27SEG26SEG25SEG24SEG23SEG22SEG21SEG20SEG19SEG18SEG17SEG16SEG15SEG14

SEG26SEG27SEG28SEG29SEG30SEG31SEG32SEG33SEG34SEG35COM7COM6COM5COM4COM3COM2COM1COM0

SEG0DCLKDST2DSIO

SE

G12

SE

G13

SE

G14

SE

G15

SE

G16

SE

G17

SE

G18

SE

G19

SE

G20

SE

G21

SE

G22

SE

G23

SE

G24

SE

G25

SEG

1

SEG

3SE

G4

SEG

2

SEG

5SE

G6

SEG

7SE

G8

SEG

9

SE

G11

SPICLKSDOSDI

P02

P03

P07

P10

P11

P12

P13

P14

P15

REF0RFIN0

RFIN1REF1P31/SENA1

SENA0

P37P36P35P34P33

P22P21P20P17

SE

G10

P40

P21P34

P37

P33

P40

P35

P03P07

P07

P15

P11

P14

P12

P13

P10

P32

P22

P11

P36

P12P17

P20

REMOREMI

SENA1

SENB1

COM2

SEG13

COM1

SEG12

COM0

SEG11SEG10SEG9SEG8SEG7SEG6SEG5SEG4SEG3SEG2SEG1SEG0COM7COM6COM5COM4COM3

SENB0

P32/SENB1

P31P32

P15

P02

P37P03

P36

P21

P13

P40

P31

P16

VDD

VDD

VDD

VDD_ICD

VDD

VDD

VDD

VDD

VDD

VDD

VDD

VDD

VDD

VDD

VDD

VDD

VDD

VDD2

VDD2AVDD

AVDD

AVDD

VDD2

AVDD2

VDD2 VDD2 VDD2

VDD

VDD

VDD

VDD

VDD

VDD

VDD

VDD

Title


teehS:etaD of

0.1A2

1 1

Title


teehS:etaD of

0.1A2

1 1

Title


teehS:etaD of

0.1A2

1 1

JICDM

JICD

電流測定用0Ω抵抗

電流測定用ジャンパーピン

JEX

JRIF

JEX2DCAC DC AC

アナログ電流測定用ジャンパーピン

注意：

　1.　　　　　　で囲んだ部分はアナログ部分なので　　配線は最短で行い、GNDでガードする。

　2.表面、裏面ともベタGNDとする。

　3.DSIO,DST2,DCLK,XRESET信号は、他の信号と分離し、　　GNDでガードする。

　4.C32～C35はマイコンの四隅に配置する。

　5.SW7はできるだけマイコンの端子の近くに配置する。

※PAD1,2,3間、PAD4,5,6間、PAD7,8,9間、PAD10,11,12間は2012の0Ω抵抗でショートさせて選択する。　PAD2-3間、PAD5-6間、PAD7-8間、PAD10-11間に0Ω抵抗を実装する。

I2C RFC

U7

S1C17602_QFP

U7

S1C17602_QFP

SE

G1

1S

EG

22

SE

G3

3S

EG

44

SE

G5

5S

EG

66

SE

G7

7S

EG

88

SE

G9

9S

EG

1010

SE

G11

11S

EG

1212

SE

G13

13S

EG

1414

SE

G15

15S

EG

1616

SE

G17

17S

EG

1818

SE

G19

19S

EG

2020

SE

G21

21S

EG

2222

SE

G23

23S

EG

2424

SE

G25

25

SEG26 26SEG27 27SEG28 28SEG29 29SEG30 30SEG31 31SEG32 32SEG33 33SEG34 34SEG35 35SEG36/COM7 36SEG37/COM6 37SEG38/COM5 38SEG39/COM4 39

COM0 43COM1 42COM2 41COM3 40

TEST2 44CB 45CA 46

VC1 49VC2 48VC3 47

VSS 50

VD

D51

OS

C4

52O

SC

353

VS

S54

VD

155

OS

C1

57O

SC

256

#TE

ST

58#R

ES

ET

59P

00/R

EM

O60

P01

/RE

MI

61P

02/E

XC

L062

P03

/#A

DTR

G63

P04

/SP

ICLK

64P

05/S

DO

65P

06/S

DI

66P

07/#

SP

ISS

67P

10/S

CLK

068

P11

/SO

UT0

69P

12/S

IN0

70P

13/E

XC

L1/A

IN7

71P

14/E

XC

L2/A

IN6

72P

15/E

XC

L3/A

IN5

73

P16/SCLK1/AIN476P17/AIN377

VS

S74

AV

DD

75

P20/AIN278P21/AIN179P22/AIN080

P23/SENB082P24/SENA083P25/REF084P26/RFIN085

P27/SOUT1/RFIN187

VDD81

VSS86

P30/SIN1/REF188P31/SCL0/SENA189P32/SDA0/SENB190P33/SCL1/SCL091P34/SDA1/SDA092P35/FOUT1/#BFR93P36/TOUT3/RFCLKO94

95 P37/TOUTN3/LFRO/TOUT4P40/FOUTH96P41/DSIO97P42/DST298P43/DCLK99SEG0100

V G

U9TS5A3159A

V G

U9TS5A3159A

1 4

6

25

3

R32

103AP-2

R32

103AP-2

C27 0.1uFC27 0.1uF

VG

U6TS5A3159A

VG

U6TS5A3159A

14

6

2 5

3

PAD10PAD10

TP5GND3

TP5GND3

G

DS

Q2

FDC638APZ

G

DS

Q2

FDC638APZ

4

3

1256

R16

0

R16

0

R2

47K

R2

47K

X1

FC-255_32.768KHz

X1

FC-255_32.768KHz

R23

1K

R23

1K

TP2TP_VDD2TP2TP_VDD2

TP10P27

TP10P27

C25 0.1uFC25 0.1uF

R24

OPEN

R24

OPEN

C26 0.1uFC26 0.1uF

C12

3.3uF

C12

3.3uF

C39

100pF

C39

100pF

C13

0.1uF

C13

0.1uF

V G

U10TS5A3166

V G

U10TS5A3166

2 1

4

35

SW1

SKQTLCE010

SW1

SKQTLCE0101 2

C36 0.1uFC36 0.1uF

MA-406_6MHz

X2

MA-406_6MHz

X2

41

32

Q5

MMBTA42-TP

Q5

MMBTA42-TPC

E

B

R22

47K

R22

47K

PAD9PAD9

R12

47K

R12

47K

C29 0.1uFC29 0.1uF

R20

1K

R20

1K

C35

0.1uF

C35

0.1uF

SW4

CHS-04B

SW4

CHS-04B

12

43

5678

R27

2.2K

R27

2.2K

D3

CRS06_OPEN

D3

CRS06_OPEN

A K

R6

1K

R6

1K

TP4GND2

TP4GND2

R34

4.3K 0.1%

R34

4.3K 0.1%

C32

0.1uF

C32

0.1uF

C7

15pF

C7

15pF

C30

0.1uF

C30

0.1uF

C4

4.7uF

C4

4.7uF

-+V1

BA2032SM-+V1

BA2032SM

C38

1000pF

C38

1000pF

TP11

P30

TP11

P30

SW2

SKQTLCE010

SW2

SKQTLCE0101 2

F1

BLM18PG330SN1D

F1

BLM18PG330SN1D

C18

3.3uF

C18

3.3uF

J2

HWHP-2P

J2

HWHP-2P12

J3

JLS-2504

J3

JLS-2504

DCLK1GND2DSIO3DST24

C8

15pF

C8

15pF

U3

S-1000N18-M5V1G

U3

S-1000N18-M5V1G

NC 4VSS3 VDD2 OUT1 NC 5

J11

SLW-105-01-G-D

J11

SLW-105-01-G-D

P03/#ADTRG 2P07/#SPISS 3

GND 1

P31/SCL0 5P32/SDA0 6

P36/TOUT3/RFCLK0 7P37/TOUTN3/LFRO/TOUT4 8

P40/FOUTH 9VDD(+3.3V) 10

P13/EXCL1/AIN7 4

J10HWHP-2PJ10HWHP-2P

12

R13

47K

R13

47K

V G

U13TS5A3159A

V G

U13TS5A3159A

1 4

6

25

3

R18

1M

R18

1M

R5

0

R5

0

PAD11PAD11

J5

PS-10SD-D4T1-1

J5

PS-10SD-D4T1-1

DCLK1GND2GND3#RESET_OUT4DSIO5TGT_EN6DST27N.C8VDD(+3.3V)9VDD(+3.3V)10

R3

47K

R3

47K

R7

1K

R7

1K

C19

0.1uF

C19

0.1uF

D1

AN333

D1

AN333

A

K

R15

270

R15

270

TP3GND1

TP3GND1

SW9CAS-220BSW9CAS-220B

21 3

54 6

PAD4PAD4

D2

CRS06

D2

CRS06

AK

C14 0.1uFC14 0.1uF

TP6GND4

TP6GND4

Q3

MMBTA42-TP

Q3

MMBTA42-TP

C

E

B

C5

15pF

C5

15pF


213

546

R10

100K

R10

100K

C31 0.1uFC31 0.1uF

C9

0.1uF

C9

0.1uF

C2

4.7uF

C2

4.7uF

R14

240

R14

240

R19

470K

R19

470K

C37

0.1uF

C37

0.1uF

R33

10K 1%

R33

10K 1%

G

GV

U5SN74LVC1G97

G

GV

U5SN74LVC1G97

6

4

5 2

3

1

R11

47K

R11

47K

R28

33

R28

33

PAD5PAD5

PAD3PAD3

SW51K2SW51K2

2 1 3

R1

100

R1

100

C41

100pF

C41

100pF

V G

U11TS5A3159A

V G

U11TS5A3159A

1 4

6

25

3

PAD7PAD7

R8

1K

R8

1K

J9

2.54pitch-Through

J9

2.54pitch-Through

1122334455667788

1313

99101011111212

141415151616171718181919202021212222

R21

OPEN

R21

OPEN

C40

1000pF

C40

1000pF

R17

0

R17

0

C33

0.1uF

C33

0.1uF

C34

0.1uF

C34

0.1uF

R26

2.2K

R26

2.2K

C110.1uF C110.1uF

R36

2.2K

R36

2.2K

J1

HWHP-2P

J1

HWHP-2P1 2

TP1TP_VDD1TP1TP_VDD1

Q4

MMBTA42-TP

Q4

MMBTA42-TPC

E

B

R9

OPEN

R9

OPEN

VG

U4TS5A3159A

VG

U4TS5A3159A

14

6

2 5

3

C10

0.1uF

C10

0.1uF

C24 0.1uFC24 0.1uF

G

D S

Q1

FDC638APZ

G

D S

Q1

FDC638APZ

4

3

1256

R2510KR2510K

R35

2.2K

R35

2.2K

PAD12PAD12


21 3

54 6

TP7GND5

TP7GND5

U1PNA4702M

U1PNA4702M

Vout 1GND 2Vcc 3

C42

0.1uF

C42

0.1uF

R30

47K 1%

R30

47K 1%

F2

BLM18PG330SN1D

F2

BLM18PG330SN1D

TP8GND6

TP8GND6

C3

10uF

C3

10uFU2

TPS856

U2

TPS856

VCC1GND2GND3 GND 4GND 5OUT 6

C22 0.1uFC22 0.1uF

C200.1uF C200.1uF

J6

SLW-110-01-G-D

J6

SLW-110-01-G-D

GND 1P10/SCLK0 2P11/SOUT0 3

P12/SIN0 4P17/AIN3 5

VDD(+3.3V) 6P20/AIN2 7P21/AIN1 8

P34/SDA1/SDA0 9P33/SCL1/SCL0 10

P06/SDI 11P05/SDO 12

P04/SPICLK 13P22/AIN0 14

GND 15P35/FOUT1/#BFR 16P15/EXCL3/AIN5 17P14/EXCL2/AIN6 18

N.C 19VDD(+3.3V) 20

PAD2PAD2

D4

SML-D12P8W

D4

SML-D12P8W

A

K

R31

C10-M53R

R31

C10-M53R

C16

3.3uF

C16

3.3uF

C6

4.7uF

C6

4.7uF

C23 0.1uFC23 0.1uF

J4

8913-020-178MS-A-F

J4

8913-020-178MS-A-F

N.C. 1N.C. 2

P06/SDI 3P05/SDO 4

GND 5P07/#SPISS 6

GND 7P04/SPICLK 8

GND 9N.C. 10GND 11N.C. 12GND 13N.C. 14GND 15

P11/SOUT0 16P12/SIN0 17

N.C. 18VDD(+3.3V) 19VDD(+3.3V) 20

C28

0.1uF

C28

0.1uF

C21 0.1uFC21 0.1uF

SW3

SLLB5

SW3

SLLB5

CCW1COMCPUSHTCW2

PAD6PAD6

V G

U8TS5A3166

V G

U8TS5A3166

2 1

4

35

PAD1PAD1

PAD8PAD8

C15

0.1uF

C15

0.1uFTP9P16TP9P16

SW6

SKQTLCE010

SW6

SKQTLCE01012

R4

0

R4

0

V G

U12TS5A3166

V G

U12TS5A3166

2 1

4

35

D5

SML-D12V8W

D5

SML-D12V8W

A

K

J7HWHP-2PJ7HWHP-2P

12

R29

10M 1%

R29

10M 1%

C1

4.7uF

C1

4.7uF

J8

2.54pitch-Through

J8

2.54pitch-Through4444 4343 4242 4141 4040 3939 3838

3333

3737 3636 3535 3434

3232 3131 3030 2929 2828 2727 2626 2525 2424 2323

C17

0.1uF

C17

0.1uF

SVT17602 CPU Board

NO. Parts name Location Model number SPEC mfr1 CPU U7 S1C17602 TQFP14-100pin EPSON

2 LCD44pin (22pin×2column)36SEG×8COM

3 IC socket J8,J9 643654-1 SIP,22pin AMP4 Analog switch U8,U10,U12 TS5A3166DCKR SC-70 Texas Instruments5 Analog switch U4,U6,U9,U11,U13 TS5A3159ADCKR SC-70 Texas Instruments6 Reset IC U3 S-1000N18-M5V1G SOT-23-5,1.8V detection SII7 Universal logic U5 SN74LVC1G97DCKR SC-70 Texas Instruments8 Thermistor R32 103-AP-2 ISHIZUKA9 Humidity sensor R31 C10-M53R Shinei10 Photo IC U2 TPS856 TOSHIBA11 Photodiode U1 PNA4702M Panasonic12 infrared-emitting diode D1 AN333 STANLEY13 Transistor Q3,Q4,Q5 MMBTA42-TP SOT-23 MCC14 MOS FET Q1,Q2 FDC638APZ FAIRCHILD15 schottky diode D2,D3(non-connection) CRS06 3516,1A,20V,0.36V TOSHIBA16 LED D4 SML-D12P8W green,1608 ROHM17 LED D5 SML-D12V8W red,1608 ROHM18 filter F1,F2 BLM18PG330SN1D 1608,33O,3A,0.025O MURATA19 crystal oscillator X2 MA-406 6MHz 16pF 6MHz EPSON TOYOCOM

20 crystal oscillator X1 FC-255 32.768kHz±5ppM 12.5pF 32.768kHz EPSON TOYOCOM

21 Pin header J3(JICDM) JLS-2504 1-column,4-pole,right angle Hirosugi22 Connector J5(JICD) PS-10SD-D4T1-1 2-column,10-pole,right angle JAE23 Connector J4(JRIF)(non-connection) 8913-020-178MS-A-F SMT,20-pole KEL24 Connector J6(JEX) SLW-110-01-G-D 2-column,20-pole SAMTEC25 Connector J11(JEX2) SLW-105-01-G-D 2-column,10-pole SAMTEC26 Jumper pin J1,J2,J7,J10 HWHP-2P 2-pole,terminal part: 6mm MAC827 Jumper socket J1,J2 MJS-0605B black Hirosugi28 battery holder V1 BA2032SM SMT,CR2032 Takachi29 tact switch SW1,SW2,SW6 SKQTLCE010 side push ALPS30 lever & push switch SW3 SLLB510100 ALPS31 slide switch SW5 1K2 09.10290.01 eao32 DIP switch SW4 CHS-04B SMT,4-pole COPAL33 jumper switch SW7,SW8,SW9 CAS-220B 2 circuit COPAL34 IC socket R31,R32 300-032-050 2 pin 3M35 battery CR2032

SVT17602 SVT17602 CPUboard_BOMlist 1/2

36 USB cable USB-ECOM515 A-miniB,1.5m ELECOM37 test terminal LC-33-G-RED red MAC838 test terminal LC-33-G-BLACK black MAC839 laminated ceramic capacitor C1,C2,C4,C6 C1608JB0J475K 1608,4.7uF±10%,6.3V TDK

40

laminated ceramic capacitor

C9,C10,C11,C13,C14,C15,C17,C19,C20,C21,C22,C23,C24,C25,C26,C27,C28,C29,C30,C31,C32,C33,C34,C35,C36,C37,C42

GRM219F11H104ZA01D

2012,0.1uF+80/-20%,50V

MURATA

41 laminated ceramic capacitor C3 EMK316F106ZL-T 3216,10uF+80/-20%,16V Taiyo Yuden Co., Ltd.42 laminated ceramic capacitor C5,C7,C8 C1608CH1H150J 1608,15pF±5%,50V TDK43 laminated ceramic capacitor C12,C16,C18 C1608JB0J335K 1608,3.3uF±10%,6.3V TDK44 film condenser C38,C40 ECH-U1C102GX5 1608,1000pF±2%,16V Panasonic45 film condenser C39,C41 ECH-U1C101GX5 1608,100pF±2%,16V Panasonic

46 chip resistor R2,R3,R11,R12,R13,R22,R30

RK73H2ATTD4702F 2012,47K,1%,0.125W KOA

47chip resistor

R4,R5,R16,R17,PAD2-3,PAD5-6,PAD7-8,PAD10-11

RK73Z2ATTD2012,0,2A

KOA

48 chip resistor R1 RK73H2ATTD1000F 2012,100,1%,0.125W KOA

49 chip resistor R6,R7,R8,R20,R23

RK73H2ATTD1001F 2012,1K,1%,0.125W KOA

50 chip resistor R10 RK73H2ATTD1003F 2012,100K,1%,0.125W KOA51 chip resistor R18 RK73H2ATTD1004F 2012,1M,1%,0.125W KOA52 chip resistor R14 RK73H2ATTD2400F 2012,240,1%,0.125W KOA53 chip resistor R15 RK73H2ATTD2700F 2012,270,1%,0.125W KOA54 chip resistor R19 RK73H2ATTD4703F 2012,470K,1%,0.125W KOA55 chip resistor R25,R33 RK73H2ATTD1002F 2012,10K,1%,0.125W KOA56 chip resistor R26,R27,R35,R36 RK73H2ATTD2201F 2012,2.2K,1%,0.125W KOA57 chip resistor R28 RK73H2ATTD33R0F 2012,33,1%,0.125W KOA58 chip resistor R29 RK73H2ATTD1005F 2012,10M,1%,0.125W KOA59 chip resistor R34 RG2012P-432-B-T1 2012,4.3K,0.1%,0.1W SUSUMU CO.,LTD60 chip resistor R9,R21,R24 - - -

SVT17602 SVT17602 CPUboard_BOMlist 2/2

International Sales Operations

AMERICA EPSON ELECTRONICS AMERICA, INC. 214 Devcon Drive, San Jose, CA 95112, USA Phone: +1-800-228-3964 FAX: +1-408-922-0238 EUROPE EPSON EUROPE ELECTRONICS GmbH Riesstrasse 15, 80992 Munich, GERMANY Phone: +49-89-14005-0 FAX: +49-89-14005-110

ASIA EPSON (CHINA) CO., LTD. 7F, Jinbao Bldg., No.89 Jinbao St., Dongcheng District, Beijing 100005, CHINA Phone: +86-10-8522-1199 FAX: +86-10-8522-1125 SHANGHAI BRANCH 7F, Block B, Hi-Tech Bldg., 900 Yishan Road, Shanghai 200233, CHINA Phone: +86-21-5423-5577 FAX: +86-21-5423-4677 SHENZHEN BRANCH 12F, Dawning Mansion, Keji South 12th Road, Hi-Tech Park, Shenzhen 518057, CHINA Phone: +86-755-2699-3828 FAX: +86-755-2699-3838 EPSON HONG KONG LTD. Unit 715-723, 7/F Trade Square, 681 Cheung Sha Wan Road, Kowloon, Hong Kong. Phone: +852-2585-4600 FAX: +852-2827-4346 EPSON TAIWAN TECHNOLOGY & TRADING LTD. 14F, No. 7, Song Ren Road, Taipei 110, TAIWAN Phone: +886-2-8786-6688 FAX: +886-2-8786-6660 EPSON SINGAPORE PTE., LTD. 1 HarbourFront Place, #03-02 HarbourFront Tower One, Singapore 098633 Phone: +65-6586-5500 FAX: +65-6271-3182 SEIKO EPSON CORP. KOREA OFFICE 5F, KLI 63 Bldg., 60 Yoido-dong, Youngdeungpo-Ku, Seoul 150-763, KOREA Phone: +82-2-784-6027 FAX: +82-2-767-3677 SEIKO EPSON CORP. MICRODEVICES OPERATIONS DIVISION IC Sales & Marketing Department 421-8, Hino, Hino-shi, Tokyo 191-8501, JAPAN Phone: +81-42-587-5814 FAX: +81-42-587-5117

Hardware ManualS5U1C17602T1100

First Issue January, 2009 DDocument code: 411637901a

Revised: December 2012 in JAPAN

software evaluation tool for s1c17602 … · no part of this material may be reproduced or...

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