$0 %2$5' 32-bit microprocessor Base on AM3517 LCD, VGA, AV, S-video, serial port, Ethernet network, CAN, RS485, Audio In/Out, SD, CF, USB User Manual
COPYRIGHT AM3517 is trademark of TI Corporation. Sourcery G++ Lite for ARM GNU/Linux is trademark of Codesourcery. Microsoft, MS-DOS, Windows, Windows95, Windows98, Windows2000, Windows embedded CE 6.0 are trademarks of Microsoft Corporation. Rev Date Description 1.0 July 10,2010 Initial version 2.0 Dec 28,2010 Modified u-boot: Added NORFLASH support, Added TV/S-video output support 3.0 May 28,2011 Increased the support on wince6.
CONTENT 1 SYSTEM OVERVIEW................................................................................................................ 6 1.1 INTRODUCTION ........................................................................................................................ 6 1.2 SYSTEM MODULE .................................................................................................................... 8 1.3 ARCHITECTURE DIAGRAM ......................................................................
3.4.4.1 LED application development..................................................................................... 48 4 WINCE SYSTEM ...................................................................................................................... 50 4.1 WINCE SYSTEM OVERVIEW .................................................................................................. 50 4.1.1 Pre-compiled image ..................................................................................................
1 System Overview The document describes user how to develop with $0 ERDUG, the detailes for hardware specification, features, and software development. 1.1 Introduction SOC8200 is an industrial evaluation kit designed and manufactured by Embest Info&Tech Co.,LTD., SOC8200 is based on processor AM3517 of Texas Instrument (TI). Processor AM3715 is integrated with 600Mhz ARM Cortex-A8 Core which is dedicated using to Process industrial signal.
Fig1.
1.
1.3 Architecture Diagram The full system architecture diagram as follows: Fig1.
SOC8200 32-bit microprocessor Base on AM3517 LCD, VGA, AV, S-video, serial port, Ethernet network, CAN, RS485, Audio In/Out, SD, CF, USB User Manual
2.1.2 Hardware Features Processor AM3517 industrial applications processors NEON SIMD Coprocessor 600MHz ARM Cortex-A8 Core POWERVR SGX Graphics Accelerator (AM3517 only) 16KB I-Cache, 16KB D-Cache, 256KB L2-Cache, 112KB ROM, 64KB Share SRAM Memory 256MB DDR2 SDRAM, 32bit 256MB NAND Flash, 8bit 4MB NOR Flash, 16bit (driver has not provided at present) Signals Routed to Pins One 5-wire Debug serial port (RS232) One 5-wire serial port (TTL) Two USB 2.
SOC8200 32-bit microprocessor Base on AM3517 LCD, VGA, AV, S-video, serial port, Ethernet network, CAN, RS485, Audio In/Out, SD, CF, USB User Manual
2.2.2 Network interface SOC8200 is 10M/100M adaptive network interface PIN Description 1 GND 2 VCC_IO 3 TXN 4 TXP 5 GND 6 RXN 7 RXP 8 LED2/NINTSEL 9 LED1/REGOFF 10 GND 2.2.
20 GND 2.2.4 MMC Interface PIN Description 1 VCC_IO 2 MMC1_CLK 3 MMC1_CMD 4 MMC1_D0 5 MMC1_D1 6 MMC1_D2 7 MMC1_D3 8 MMC1_CD 9 MMC1_WP 10 GND 2.2.
2.2.6 Analog IO Interface PIN Description 1 CH7 2 CH6 3 CH5 4 CH4 5 CH3 6 CH2 7 CH1 8 CH0 9 GND 10 VCC_IO 2.2.7 Digital IO Interface PIN Description 1 CH7 2 CH6 3 CH5 4 CH4 5 CH3 6 CH2 7 CH1 8 CH0 9 GND 10 VCC_IO Table2.
2.2.
40 N/A 2.2.9 PC104 Interface 2.2.9.
36 GPIO157 37 GPIO162 38 SPI4_CS0 39 SPI4_SOMI 40 SPI4_SIMO 41 SPI4_CLK 42 GND 43 SPI1_CS3 44 SPI1_CS2 45 SPI1_SOMI 46 SPI1_SIMO 47 SPI1_CLK 48 GND 49 MMC2_D7 50 MMC2_D6 51 MMC2_D5 52 MMC2_D4 53 MMC2_D3 54 MMC2_D2 55 MMC2_D1 56 MMC2_D0 57 MMC_CMD 58 MMC2_CLK 59 GND 60 U3_DP 61 U3_DM 62 U4_DM 63 U4_DP 64 GND Table2.
2.2.9.
40 GND 2.2.10 Multifunctional Expansion Interface PIN Description 1 GND 2 TV_OUT1 3 GND 4 TV_OUT2 5 GND 6 VCC_IO 7 GND 8 MCBSP2_CLKX 9 MCBSP2_FSX 10 MCBSP2_DR 11 MCBSP2_DX 12 IIC2_SDA 13 IIC2_SCL 14 GND 15 SPI2_CLK 16 SPI2_SIMO 17 SPI2_SOMI 18 SPI2_CS0 19 SPI2_CS1 20 GND 2.2.
13 IIC2_SCL 14 GND 15 SPI2_CLK 16 SPI2_SIMO 17 SPI2_SOMI 18 SPI2_CS0 19 SPI2_CS1 20 GND 2.2.12 Power Interface PIN Description 1 VCC_5V 2 GND 2.2.
2.2.
COPYRIGHT SOC8200 ,CAN8200, SD8200-X,CAN8200-X,AU8200,VGA8200, USB8200-X,NET8200 ,ECOM-4,ECOM-8,E100 Module are trademarks of Embest Info&Tech Co.,LTD. AM3517 is trademark of TI Corporation. Sourcery G++ Lite for ARM GNU/Linux is trademark of Codesourcery. Microsoft, MS-DOS, Windows, Windows95, Windows98, Windows2000, Windows embedded CE 6.0 are trademarks of Microsoft Corporation. Rev Date Description 1.0 July 10,2010 Initial version 2.
1 System Overview The document describes user how to develop with SOC8200, the detailes for hardware specification, features, and software development. 1.1 Introduction SOC8200 is an industrial evaluation kit designed and manufactured by Embest Info&Tech Co.,LTD., SOC8200 is based on processor AM3517 of Texas Instrument (TI). Processor AM3715 is integrated with 600Mhz ARM Cortex-A8 Core which is dedicated using to Process industrial signal.
Digital output Control independently Table 3.
3.2 Linux System Quick Operation Windows System Environment Preparation In the course of system operation, when needs HyperTerminal in the PC, the Hyper Terminal configuration is as follows: Baud rate: 115200 Data bit: 8 Parity check: no Stop bit: 1 SOC8200 Hardware Environment Preparation Before booting the linux system, you should make sure the following labeled before turn on power: 1. Confirm that you have connected the LCD. (If you have bought the LCD) 2.
3.2.1 System boot methods 3.2.1.1 NAND Flash Boot You can use the jumper cap to choose the boot type, if connect the Place A, the board will boot image from SD card, otherwise the board will boot image from NAND Flash. The nand flash already has the solidified code of VGA display, user only need to connect the serial port and set the hyper terminal configuration. User can boot linux system from nand flash without connect the jumper cap. If customers do not use VGA, please refer to 【3.3.
OMAP34xx/35xx-GP ES1.0, CPU-OPP2 L3-165MHz AM3517EVM Board + LPDDR/NAND I2C: ready DRAM: 256 MB NAND: 256 MiB In: serial Out: serial Err: serial Die ID #796400000000000001543b2106011005 Net: davinci_emac_initialize Ethernet PHY: GENERIC @ 0x00 DaVinci EMAC Hit any key to stop autoboot: 3 When it starts to this here, the system will count down for 3 seconds. Then press any key, it will enter the u-boot shell. 3. U-boot parameter settings Input the following in bold type in the u-boot shell.
3.2 3.3 Test on RTC SOC8200 has a hardware clock, it is used to save and restore the system time, refer to the following test methods: 1. Set the system time at 5:55 p.m. on the March 24, 2010: [root@OMAP3EVM /]# date 032417552010 Wed Mar 24 17:55:00 UTC 2010 2. Write the system time into RTC: [root@OMAP3EVM /]# hwclock -w 3. Read RTC: [root@OMAP3EVM /]# hwclock Wed Mar 24 17:55:06 2010 0.000000 seconds The hardware clock RTC will be set to March 24 2010 and the system time is saved in the hardware clock.
2.After successful connection, PC will show a virtual network card as displayed in Fig 5.1: Fig 5.1 virtual network card 3. Set the IP address of the virtual network card, for example: Fig 5.2 IP Configuration 4. Set the IP network segment of SOC8200 board as the same as virtual network card: [root@OMAP3EVM /]# ifconfig usb0 192.168.1.105 [root@OMAP3EVM /]# ifconfig usb0 Link encap:Ethernet HWaddr CA:A3:26:97:50:A8 inet addr:192.168.1.105 Bcast:192.168.1.255 Mask:255.255.255.
5. Use the following command on the hyper terminal to test the SOC8200 board whether had connected successfully. [root@OMAP3EVM /]# ping 192.168.1.15 PING 192.168.1.15 (192.168.1.15): 56 data bytes 64 bytes from 192.168.1.15: seq=0 ttl=128 time=6.592 ms 64 bytes from 192.168.1.15: seq=1 ttl=128 time=0.549 ms 64 bytes from 192.168.1.15: seq=2 ttl=128 time=0.488 ms 64 bytes from 192.168.1.15: seq=3 ttl=128 time=0.458 ms The address of OTG should not the same as net, user may change it. 3.2 3.
3.2 3.7 Test on network The board has a 10/100M self-adapting network card DM9000; users can connect the board to the LAN and enter the following commands for a test: [root@OMAP3EVM /]# ifconfig eth0 192.192.192.201 eth0: attached PHY driver [Generic PHY] (mii_bus:phy_addr=ffffffff:00, id=7c0f1) [root@OMAP3EVM /]# PHY: ffffffff:00 - Link is Up - 100/Full [root@OMAP3EVM /]# ping 192.192.192.90 PING 192.192.192.90 (192.192.192.90): 56 data bytes 64 bytes from 192.192.192.90: seq=0 ttl=128 time=5.
Capture: Stream on... LCD shows the image collected by the camera. ( press ctrl+c to quit the test ) 3.2 3.9 Test on CAN If the user want to connect the CAN device, please use the CAN8200。 The steps for the CAN connection: 1. The steps for setting: Set the CAN baud rate as 125 k/bits, and enable the CAN devices. [root@OMAP3EVM bin]# /usr/bin/ip link set can0 type can bitrate 125000 triple-sampling on [root@OMAP3EVM bin]# /usr/bin/ip link set can0 up ti_hecc ti_hecc.1: setting CANBTC=0xc00a8 2.
Windows Embedded CE 6.0 R2 NCP 3. Umount the SD card. [root@OMAP3EVM /]# umount /mnt linux-2.6.24 3.2 3.12 Test on buzzer 1. Enable the buzzer: [root@OMAP3EVM /]# echo 1 > /sys/class/misc/beep/val 2. Off the buzzer: [root@OMAP3EVM /]# echo 0 > /sys/class/misc/beep/val 3.2 3.13 Test on AUDIO The board has audio input and output interface, and we have alsa-utils audio test tools in the filesystem, users can enter the following commands for a test: 1.
2.
3.2 3.14 Test on full-function serial port SOC8200-M has 3 serial port: Interface Type Encapsulati on Device nodes dBm Extended serial port 0 Full-function serial port Interface for DB9 /dev/ttySCMA0 RS232 Extended serial port 1 Full-function serial port Interface for IDC /dev/ttySCMA1 TTL Debug port Three-wire serial port Interface for IDC /dev/ttyS2 RS232 Test program 3 line com_norts 9 line com_rts 3 line com_norts 9 line com_rts System Integration 1.
Parity bit: None Control flow: Hardware DTR: On RTS: On 2. Test for communication: 1) Connect the extended serial port 0 and PC via 3-wire mode Input the following commands, the SOC8200 board will send data “1234567890 " to the PC. If the PC has send the data to SOC8200 board, the board will receive the data too. [root@OMAP3EVM ]# com_norts -d /dev/ttySCMA0 SEND: 1234567890 RECV: www.armkits.com RECV: www.armkits.com SEND: 1234567890 RECV: www.armkits.com RECV: www.armkits.
3.2 3.15 Test on digit output The pins 1 to 8 on the connector J6 can output the digit voltage 0V and 3.3V, the default the output 3.3v when reset the board. 1. Device introduce: [root@OMAP3EVM /]# cd /sys/class/misc/digital/ [root@OMAP3EVM digital]# ls dev out2 out4 out6 out8 power uevent out1 out3 out5 out7 outall subsystem As the above, the out1 has corresponding the pin1, the outall has corresponding the pins for 1 to 8. 2.
3.3 Linux Image Update SOC8200 supports MMC/SD boot or NAND boot; different start-up modes will have different method for updating the image. We will introduce the update of image under different start-up modes. 3.3.1 Update the image for SD card 3.3.1.1 Prepare 1 The formatting of MMC/SD card Recommend to use HP USB Disk Storage Format Tool: The software is download from: http://www.embedinfo.com/english/download/SP27213.exe.
This tool will delete all partition on the SD/MMC card. 2. Preparing the SD card file 1)Copy the all the file on the directory of disk/linux/image. 2) Depending on your display device LCD (4.3inch,7inch) or VGA, rename uImage_xx as uImage The foregoing “XX” mean your LCD inch, it is included 4.3inch, 7inch and VGA. 3.3.1.2 Update the image 1.
U-Boot 2009.11-svn ( 3 鏈?19 2010 - 16:14:31) OMAP34xx/35xx-GP ES1.0, CPU-OPP2 L3-165MHz AM3517EVM Board + LPDDR/NAND I2C: ready DRAM: 256 MB NAND: 256 MiB In: serial Out: serial Err: serial Die ID #796400000000000001543b2106011005 Net: davinci_emac_initialize Ethernet PHY: GENERIC @ 0x00 DaVinci EMAC Hit any key to stop autoboot: 3 When it starts to this here, the system will count down for 3 seconds. Then press any key, it will enter the u-boot command line mode. 2.
3.3.2 Update the image for NAND Flash 3.3.2.1 Prepare Use HP USB Disk Storage Format Tool 2.0.6 software to format the SD card, copy all files from the CD linux / image / to the SD card and depending on your display device LCD (4.3,7) or VGA, rename uImage_xx To uImage Notice:the foregoing “XX” mean your LCD inch, it is included 4.3inch, 7inch and VGA. 3.3.2.2 Update system image MLO WritetoNAND NANDNAND u-boot.bin Boot from SD uImage ramdisk.gz x-load.bin.ift_for_NAND flash-uboot.bin uImage ubi.
Update image for SD card: mmc init fatload mmc 0 80000000 flash-uboot.bin nand erase 80000 160000 nandecc sw nand write.i 80000000 80000 $filesize 3. The update of kernel boot image Input the following commands in the u-boot shell: Update image for SD card: mmc init fatload mmc 0 80000000 uImage nand erase 280000 300000 nandecc sw nand write.
3.4 Linux System Deveplopment This section will introduce how to establish a Linux system development platform run on SOC8200 hardware platform with the use of SOC8200 BSP. Details to be provided contain the formation of cross compilation environment, the generation of system image and demonstrate how to customize the system. For the SD card, After formatting and dividing into FAT and EXT3 under ubuntu system, the FAT needs reformatting under windows system, otherwise, start-up with SD card can be realized.
Users can put it into the barsrc file, and the adding of environment variable can be finished as the system starts. 3.4.2 system complie 3.4.2.1 Preparation The source code of each part of the system is under the linux/source of CD. Users can copy it to the system and unzip it before developing. For example: mkdir /home/embest/work cd /home/embest/work tar xvf /media/cdrom/linux/source/ x-loader-03.00.00.04.tar.bz2 tar xvf /media/cdrom/linux/source/ u-boot-03.00.00.04.tar.
When the above steps are finished, the current directory will generate the file x-load.bin.ift_for_NAND we need. 3.4.2.3 u-boot image generated cd u-boot-03.00.00.04/ make distclean make am3517_evm_config make When the above steps are finished, the current directory will generate the file u-boot.bin we need. 3.4.2.4 kernel image generated User may change linux-03.00.00.04/drivers/video/omap2/displays/ panel-sharp-lq043t1dg01.c, the default display is VGA.
cd linux-03.00.00.04/ cp arch/arm/configs/omap3_soc8200_defconfig .config make menuconfig The example that we use usb gadget to simulate usb mass storage device will be taken to introduce the system customization: 1.
3.4.3.3 Test Update kernel image file ulmage in SD card, copy file g_file_storage.ko to the SD card and reboot the system from SD. Execute the following commands to stimulate the SOC8200 into usb mass storage device for PC’s visit: root@DevKit8000:~# mount –t vfat /dev/mmcblk0p1 /mnt root@DevKit8000:~# cd /mnt root@DevKit8000:/mnt# insmod g_file_storage.
#define LED "/sys/class/leds/led/brightness" int main(int argc, char *argv[]) { int f_led; unsigned char i = 0; unsigned char dat; if((f_led = open(LED, O_RDWR)) < 0){ printf("error in open %s",LED); return -1; } for(;;){ i++; //dat = i&0x1 ? '1':'0'; //dat = (i&0x2)>>1 ? '1':'0'; dat = (i&0x4)>>2 ? '1':'0'; write(f_led, &dat, sizeof(dat)); usleep(300000); } } 2. Cross compilation arm-none-linux-gnueabi-gcc led_acc.c -o led_acc 3.
4 WinCE System 4.1 WinCE system Overview SOC8200 software system includes: pre-compiled images and applications and their corresponding static library, dynamic link library, header file and source code; cross compilation tools, auxiliary tools for development. Images, applications, Cross compilation tools used for generating image and application can be downloaded from Microsoft. Image, application, source code and auxiliary tools of SOC8200 can be found in the release CD or SD card of SOC8200.
Image Feature X-Loader To boot EBOOT To boot the operating system from the network (network card or RNDIS) EBOOT To boot the operating system with SD card To boot the operating system from the NAND Flash Windows Explorer Console Window CAB File Installer/Uninstaller Internet Explorer 6.0 Demonstrated operating system ActiveSync Power Management (Full) .NET Compact Framework 3.5 Hive-based Registry RAM and ROM File System Device Drivers 4.1.
SD/MMC/SDIO driver DM9000 network card driver USB OTG driver USB EHCI driver VRFB driver DSPLINKK/CMEMK driver GPIO keyboard driver PWM(TPS65930)driver ADC(TPS65930)driver ONENAND driver SMSC911X network card driver CAN driver Buzzer drive Backlight driver Power management module Battery driver Sleep / wake-up button driver Expansion of power management Flash Plug-in and Flash player Application module MP3/MPEG4/H264 DSP Hardware decoder BSPINFO(control panel) CETK 4.2 WinCE system quick start 4.2.
4.2.1.2 Boot from SD card Copy image files MLO、EBOOTSD.nb0、NK.bin From CD:\WinCE\image\ VGA_1024x768(lcd_800x480 or lcd_480x272)\SD directory to SD card. If users need to switch to SD card, need to start in SOC8200 J24 connected to the motherboard jump line on cap, electric start, the system immediately instead from MMC/SD start. the method to update the image from the SD card will be show in 【4.4.1 Update the image for SD card】 4.3 WINCE System Development 4.3.1 Development environment building 4.3.1.
All of these software or component system since there are dependent relationship with Suggestions listed in strict accordance with the installation, and installed in order default path. 4.3.2 system complie If the sample Windows Embedded CE 6.0 OS image in the CD of SOC8200 satisfies your applications, you just need to add it into your application and get the authorization of Microsoft Corporation. Otherwise, you will need to re-customize the system and rebuild the image.
Modify C:\wince600\platform\am35x_bsp\src\bsp_common\display\Lcd_cfg.h //------------------------------------------#define lcd_7inch 1 //#define lcd_43inch 1 //#define lcd_vga_1024x768 1 //-------------------------------------------For the VGA Modify C:\wince600\platform\am35x_bsp\src\bsp_common\display\Lcd_cfg.
In the system in the process of compiling, the user should be in the "solution" choice "in the box with AM35x_BSP_ARMV4I_Release". 4.3.2.3 System Customization Windows Embedded CE 6.0 consists of a number of independent modules. Each module provides specific functions, of which some modules can be divided into several components. Each component has specific feature, making OEM/ODM customize a stable and efficient version according to specific application.
Store->Storage Manager Storage Manager Control Panel Applet Core OS->CEBASE->File Systems and Data Store->Storage Manager Transaction-Safe FAT File System (TFAT) Core OS->CEBASE->File Systems and Data Store->Storage Manager Video/Image Compression Manager Core OS->CEBASE->Graphics and Multimedia Technologies->Media->Video Codecs and Renderers Console Window Core OS->CEBASE->Shell and Interface->Shell->Command Shell SD Memory Device Drivers->SDIO->SDIO Memory serial Device Drivers->USB Function Cl
MLO XLDRNAND.nb0 EBOOTSD.nb0 NK.bin from CD:\winCE\image\ VGA_1024x768(lcd_800x480或lcd_480x272)\NAND directory to SD card. 4.4.2.2 Image update (1) In SOC8200 J24 connected to the motherboard jump line, the position of the cap J24 10.1.2 have introduced in. Insert SD card restart your system. HyperTerminal will start printing the output information, at the same time press [SPACE] to enter the EBOOT menu. (2) Press [5] to enter the Flash manage menu.
4.5.1 The interface and demonstration of application The Application Programming Interface (API) used by SOC8200 application development employs the standard application interface of Windows Embedded CE 6.0. SOC8200 just has an additional GPIO interface based on standard API. 1. For interface definition of Windows Embedded CE 6.0 standard application, please refer to related help documents of MSDN Windows Embedded CE 6.0 API. 2. The example of the use of standard API is provided in the section of 7.2.
GPIO_DIR_INPUT Input mode GPIO_INT_LOW_HIGH Rising edge trigger mode GPIO_INT_HIGH_LOW Falling edge trigger mode GPIO_INT_LOW low level trigger mode GPIO_INT_HIGH high level trigger mode GPIO_DEBOUNCE_ENABLE Jumping trigger enable 3.
Appendix Appendix I Dimension Fig 2.
Appendix II Driver installation of Linux USB Ethernet/RNDIS Gadget 1. If you don’t install driver of Linux USB Ethernet/RNDIS Gadget, PC will find the new hardware and give you a hint on the screen, please select “From list or designated location”, then click “Next” 2.
3. When the following appears, select “Continue” 4.
Appendix III Linux Boot Disk Format How to create a dual-partition card for SOC8200 to boot Linux from first partition and have root file system at second partition. 一、Introduction This guide is meant for those looking to create a dual-partition card, booting from a FAT partition that can be read by the OMAP3 ROM bootloader and Linux/Windows, then utilizing an ext3 partition for the Linux root file system. 二、Details Text marked with [] shows user input.
So you know your starting point. Make sure to write down the number of bytes on the card (in this example, 2021654528).
8、Print the partition record to check your work Command (m for help): [p] Disk /dev/sdc: 2021 MB, 2021654528 bytes 255 heads, 63 sectors/track, 245 cylinders Units = cylinders of 16065 * 512 = 8225280 bytes Device Boot Start End Blocks Id System 9、Create the FAT32 partition for booting and transferring files from Windows Command (m for help): [n] Command action e extended p primary partition (1-4) [p] Partition number (1-4): [1] First cylinder (1-245, default 1): [(press Enter)] Using default value 1
Disk /dev/sdc: 2021 MB, 2021654528 bytes 255 heads, 63 sectors/track, 245 cylinders Units = cylinders of 16065 * 512 = 8225280 bytes Device Boot /dev/sdc1 * /dev/sdc2 Start 1 7 End Blocks Id System 6 409626 c W95 FAT32 (LBA) 61 1558305 83 Linux 13、Save the new partition records on the SD Card This is an important step. All the work up to now has been temporary. Command (m for help): [w] The partition table has been altered! Calling ioctl () to re-read partition table.
32768, 98304, 163840, 229376, 294912 Writing inode tables: done Creating journal (8192 blocks): done Writing superblocks and filesystem accounting information: In ubuntu is formatted good FAT and EXT3 double division, FAT division in window to need to format a, otherwise it may appear not SD card from the start
Appendix IV TFTP Server Build 1, installation client $>sudo apt-get install tftp-hpa $>sudo apt-get install tftpd-hpa 2, installation inet $>sudo apt-get install xinetd $>sudo apt-get install netkit-inetd 3, server configuration First of all, in the root directory, and build a tftpboot attribute to any user both: $>cd / $>sudo mkdir tftpboot $>sudo chmod 777 tftpboot Secondly, in the/etc/inetd conf. Add: $>sudo vi /etc/inetd.
Appendix V WinCE related resources links 1. Visual Studio 2005 SP1 Update for Vista (if applicable) http://download.microsoft.com/download/c/7/d/c7d9b927-f4e6-4ab2-8399-79a2d5cdfac9/VS80sp 1-KB932232-X86-ENU.exe 2. Windows Embedded CE 6.0 Platform Builder Service Pack 1 http://www.microsoft.com/downloads/details.aspx?familyid=BF0DC0E3-8575-4860-A8E3-290A DF242678&displaylang=en 3. Windows Embedded CE 6.0 R2 http://www.microsoft.com/downloads/details.
Appendix VI Expansion Board The customer can evaluate the AM3517 via SOC8200 expansion board(SOC8200-M), to experience the AM3517 processor. The customer can use single board computer and function Interface board to add the product functions, thus reducing product development cycles, achieve faster time to market.
· 1 road, USB 2.
Appendix VII Interface Board For the convenience of our customers rapid customization product, TianMo introduced based on SOC8200 motherboard interface board, is mainly will each function modular, Each module can be through the copper column set up to, and then through the line connected to SOC8200 motherboard. There is ECOM-4 / ECOM-8 (shown below Fig),need to connect the E100 communication board to use . The interface board not retail, 100PCS minimum.
Technical support & Warranty Service Embest Info&Tech Co.,LTD., established in March of 2000, is a global provider of embedded hardware and software. Embest aims to help customers reduce time to market with improved quality by providing the most effective total solutions for the embedded industry.
2. The situations listed below are not included in the range of our free maintenance service, Embest will charge the service fees with discretion: A. Can’t provide valid Proof-of-Purchase, the identification label is tour up or illegible, the identification label is altered or doesn’t accord with the actual products; B. Don’t follow the instruction of the manual in order to damage the product; C.