CM1-86DX2 PC/104 Single Board Computer Technical Manual P/N 50-1Z149-1020 Rev 3.00 Advance Technologies. Automate the World.
Technical Manual CM1-86DX2 Document: 50-1Z149-1020 Copyright ©2014, 2015 ADLINK Technology, All rights reserved Trademarks MS-DOS, Windows, Windows 95, Windows 98, Windows NT and Windows XP are trademarks of Microsoft Corporation. PS/2 is a trademark of International Business Machines, Inc. Intel and Solid State Drive are trademarks of Intel Corporation. PC/104 is a registered trademark of the PC/104 Consortium. All other trademarks appearing in this document are the properties of their respective owners.
CM1-86DX2 Table of Contents 1 Introduction...................................................................................................................... 1 1.1 Overview ................................................................................................................................ 1 1.2 Features................................................................................................................................. 2 SoC .....................................................
100 Mbit Ethernet Connector (X7) ................................................................................. 24 Gbit Ethernet Connector (X6) ......................................................................................... 25 3.5 On-Board Power Supply ..................................................................................................... 25 Power Connector (X25) ..................................................................................................
CM1-86DX2 4.5 Programming Examples.......................................................... ............................................ 57 GPIOs on GPIO Port 1 (X17) ..........................................................................................57 RS-232 / RS-485 switching ............................................... .............................................57 Watchdog0 Example .......................................................................................................
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CM1-86DX2 1 Introduction 1.1 Overview The CM1-86DX2 is a PC/104 Single Board Computer (SBC) based on DMP’s Vortex86-DX2 single chip solution, featuring exceptionally high integration and a very good performance-to-power ratio. The board supports all peripherals needed for an embedded PC on a small 3.775" by 4.050" printed circuit board.
1.2 Features SoC Main Memory DMP Vortex86-DX2 @ max. 1 GHz X86 Processor Core Floating point unit support Embedded I/D L1 Cache (16K each) Embedded L2 Cache (256K 4-way) DDR2 Interface GPU Control Unit (VGA, 2D Graphic, UMA Architecture) Embedded 2MB Flash (BIOS storage) 1GB DDR2 Memory Down Extension slots 1x MiniPCIe slot with mSATA and USB capability (3.
CM1-86DX2 1.3 Block Diagram CM1-86DX2 Optional: 1GB DDR2-400 512MB DDR2-400 Memory Down LCD DS90C385A LCD to LVDS LVDS Inverter (Backlight) VGA PCIe JTAG VGA i210IT Ethernet I2C I2C 8x A/D Input GbE ETH ADC SATA Vortex86DX2 8x GPIO Optional: Option: SATA or mSATA 3x USB 2.0 RS232/485 2x COM PCIe Option: 4x COM mPCIe or mSATA LPT 1x USB 2.
Table 1-1: CM1-86DX2 Models (Continued) CM1-86DX2 PC/104 CPU board with DMP Vortex86-DX2, including heat sink, and 1GByte of memory. 802-0018-10 Operating temp. range: -20°C … +70°C CPU clock: 1 GHz Memory clock: 333 MHz CM1-86DX2 PC/104 CPU board with DMP Vortex86-DX2, including heat sink, and 1GByte of memory. 902-0018-10 Operating temp. range: -40°C … +85°C CPU clock: 800 MHz 702-0020-10 802-0020-10 902-0020-10 Memory clock: 300 MHz CM1-DX2 PC/104 CPU board with DMP Vortex86-DX2 incl.
CM1-86DX2 1.5 Specifications Electrical Specifications Table 1-3: Electrical Specifications +5 V DC Supply voltage: +5 V standby (only needed for suspend mode) Rise time: +12 V (only needed for LVDS display and expansion slots) < 10 ms Supply voltage tolerance: ± 5% Inrush current: 1.6 A Supply current: max. 1.7 A (Windows XP, PIcalc [lots of decimals of PI]) ; typical 1.
Table 1-6: HALT Parameters (Continued) Vibration Step Stress Combined Environment The board was subject to vibration step stress with set points from 5 grams to 45 grams @ 20°C and vibration increasing by 5 grams with 15 minute dwells at each level of 2Hz to 5000Hz bandwidth The board was subject to thermal cycles from -90°C to +85°C at an average rate of 60°C per minute combined with vibration at set points of 8, 16, 24, 32, and 40 grams from the first to the fifth thermal cycle and 10-minute dwells at e
CM1-86DX2 CM1-86DX2_mech_dwg_top_b 30.03 1.60 42.23 Top 90 96 88.75 73.11 72.81 54.81 35.50 7.12 36.81 10 43 10.43 18.31 2.07 6.76 18.21 8.21 1.64 1 85.62 85 62 81.10 81 10 62.92 17.36 44.07 62.
Bottom CM1-86DX2_mech_dwg_bottom_a 17.05 96 53.95 CM1-86DX2_mech_dwg_top_b 74.07 4.05 70.45 50.15 40.10 18.60 13.90 23.35 3.50 20.20 56.
CM1-86DX2 2 Getting Started 2.1 Header and Jumper Locations Table 2-1 on page 9 provides descriptions of the headers and connectors on the module. The header and connector locations are shown in Figure 2-1 and Figure 2-2. See Chapter 3 for the signal definitions of the headers and connectors presented in this table.
Top Key: X1 - Utility X2, X3, X4, X5 - COM X6 - Gigabit Ethernet X7 - Fast Ethernet X8 - VGA X9 X16 X19 X23 X25 - PC/104 - JTAG - Parallel - Audio - ATX Power X16 C0 D0 CM1-86DX2_conn_top_b Figure 2-1: Header locations (top side) The yellow arrows next to the connectors in this illustration denote pin 1.
CM1-86DX2 Bottom Figure 2-2: Header locations (bottom side) The yellow arrows next to the connectors in this illustration denote pin 1.
2.2 LED Indicators The onboard LED indicators provide board status including error codes and Watchdog and Ethernet statuses. The MiniPCIe LEDs are located on bottom of the board, near the MiniPCIe connector. All other LEDs are located near the PC/104 connector on the top. Table 2-2: LED Name and Description LED Green LED shows error codes in terms of failure. WD (LED10, TOP) ETH0_LINK_ACT (LED3, TOP) Red LED lights up when Watchdog was triggered. Can only be reset by a power off sequence.
CM1-86DX2 2.3 Hardware Setup Be sure to observe the EMC security measures. Make sure you are always at the same potential as the module. Never connect or disconnect peripherals like HDDs, PCI, and ISA boards while the board's power supply is connected and switched on. Use the cable set provided by ADLINK Technology to connect the CM1-86DX2 to a VGA monitor. Connect either PS/2 or USB keyboard or mouse, respectively. Use the SATA cable to connect the hard disk.
14 Getting Started
CM1-86DX2 3 Module Description 3.1 Processor and Chipset (SoC: System on a Chip) The Vortex86DX2 is a high performance and fully static 32-bit x86 processor with the compatibility of running Windows, Linux, and most popular 32-bit Real-Time Operating Systems. It also integrates 32KB write through 4-way L1 cache, 256KB write-through/write-back 4-way L2 cache, PCIE bus in at 2.
3.2 Processor functional blocks The processor part in the Vortex86DX2 consists of the following components: CPU Core Northbridge Southbridge Graphics Controller for VGA or LVDS Ethernet Controller IDE / SD / SATA Controller 2x USB2.0 / USB1.1 Controller BIOS flash For further information, please refer to the datasheet of the DMP Vortex86DX2 SoC. 3.3 Graphics Controller This section lists the features of the Vortex86DX2 SoC integrated graphics engine.
CM1-86DX2 2D Features Directly access data through M-Bus High performance pipe-lined, one-cycle 64-bit 2D graphics engine 2D engine commands: BitBlt Rectangle Fill BitBlt Pattern Fill BitBlt Rectangle Copy from Source to Destination Support 256 Raster Operations Integrate 8x8 Pattern Registers Integrate 8x8 Mask Registers Support Rectangle Clip Support Color Expansion Support Enhanced Color Expansion Support Line Drawing with Style Pattern Support Line
Power Management Features Supports VESA Display Power Management Signaling (DPMS) compliant VGA monitor for power management Supports direct I/O command to force graphics accelerator into standby/suspend-off state Video Post-Processor Features Up/Down-Scaling De-Interlace (Bob and Weave mode) 3:2 Sequence Pull-Down Detection Color Space Enhance and Conversion Image Cropping (Source Rectangle) Sub-Picture (AI44 or AYUV) Blending with main video Video rotation Capture Featu
CM1-86DX2 VGA Header (X8) Connector type: DC10 pin header 2.54 mm Adapter cable: Article number 862-0008-11 Table 3-1: VGA Header Signals (X8) Pin Signal Pin Signal 1 Red 2 GND 3 Green 4 GND 5 Blue 6 VGA_DDC_CLK 7 HSYNC 8 VGA_DDC_DATA 9 VSYNC 10 GND LVDS Configuration The onboard voltage jumper headers allow you to select the display and backlight supply voltages. (See Table 3-4 on page 23 for Display and Backlight Voltage jumper signals.
LVDS Color Mapping 20 Module Description
CM1-86DX2 LVDS Header (X12) Connector type: Hirose DF14 30-pin header Adapter cable: n/a Table 3-2: LVDS Header Signals (X12) Pin Signal Pin Signal 1 VCC_LCD 2 VCC_LCD 3 GND 4 GND 5 LVDS_L3n 6 LVDS_L3p 7 LVDS_LCLKn 8 LVDS_LCLKp 9 GND 10 LVDS_L2n 11 LVDS_L2p 12 LVDS_L1n 13 LVDS_L1p 14 LVDS_L0n 15 LVDS_L0p 16 GND 17 n. c. 18 n. c. 19 n. c. 20 n. c. 21 GND 22 n. c. 23 n. c. 24 n. c. 25 n. c. 26 n. c. 27 n. c.
Backlight Header (X13) Connector type: Hirose DF13 8-pin header Adapter cable: n/a Table 3-3: Backlight Header Signals (X13) Pin Signal Pin Signal 1 +12 V 2 +12 V 3 +5 V 4 +5 V 5 EN 6 VCC* 7 GND 8 GND *This voltage can be selected using the jumper "Backlight", shown on next table. The maximum current on all supply pins is 1A.
CM1-86DX2 Display Voltage Jumpers (X22) Jumper LVDS and Backlight Power Supply Connector type: DC6 pin header 2.00 mm Use a 2 mm jumper between 1-3 or 3-5 to select the backlight voltage. Use a 2 mm jumper between 2-4 or 4-6 to select the display voltage. Table 3-4: LVDS and Backlight Voltage Jumper Signals (X22) Pin Signal (Backlight) Pin Signal (LVDS) 1 +12V 2 +3.3V 3 Backlight Voltage 4 Display Voltage 5 +5V 6 +5V Default jumper positions 3.
Features of the 10/100/1000 Mbit controller IEEE 802.3 compliant Auto Negotiation Audio-Video bridging IEEE 1588/802.1AS precision time synchronization IEEE 802.3Qav traffic shaper (with software extensions) Jumbo Frame support Interrupt moderation, VLAN support, IP checksum off load Four transmit and four receive queues Advanced cable diagnostics, auto MDI-X ECC – error correcting memory in packet buffers IEEE 802.
CM1-86DX2 Gbit Ethernet Connector (X6) Connector type: DC10 pin header 2.54 mm Adapter cable: Article number 862-0088-10 Table 3-6: Gbit Ethernet Header Signals (X6) Pin Signal Pin Signal 1 ETH1_MX0n 2 ETH1_MX0p 3 ETH1_MX1n 4 ETH1_MX1p 5 6 n. c. 7 ETH1_PE (Protection Earth for shielded Ethernet cables) ETH1_MX2n 8 ETH1_MX2p 9 ETH1_MX3n 10 ETH1_MX3p 3.5 On-Board Power Supply The on-board power supply generates all necessary voltages from the single supply voltage of 5 volts.
Power Connector (X25) Connector type: JST B15B-EH-A 15 pin Adapter cable: Article number 862-0044-10 Table 3-7: Power Connector Signals (X25) Pin Signal (standard) Signal (5V only) 1 +5V +5V 2 GND GND 3 +5V +5V 4 GND GND 5 +5V +5V 6 +5V Standby NC 7 GND GND 8 PSON# GND 9 PWROK NC 10 NC NC 11 GND GND 12 NC 14 +12V (only for PC104 slot and backlight power supply) +12V (only for PC104 slot and backlight power supply) GND GND 15 -12V (only for PC104 slot) NC 13 NC T
CM1-86DX2 3.6 IDE / SD / SATA Controller The integrated Serial ATA controller processes host commands and transfers data between the host and Serial ATA devices. With respect to the transfer rate, the integrated SATA controller supports first generation SATA (1.5 Gbit/s). The CM1-86DX2 provides one SATA connector (X11) for connecting a SATA disk drive or an optical SATA drive. The MicroSD-Card is driven as an IDE drive and has no hot-plug capability.
SATA Connector (X11) Connector type: SATA Adapter cable: n/a Table 3-8: SATA Connector Signals (X11) Pin Signal 1 GND 2 Data_TX+ 3 Data_TX- 4 GND 5 Data_RX- 6 Data_RX+ 7 GND MicroSD Connector (X18) Connector type: MicroSD Table 3-9: MicroSD Connector Signals (X18) Pin 28 Signal 1 D2 2 D3 3 CMD 4 VDD 5 CLK 6 GND 7 D0 8 D1 Module Description
CM1-86DX2 Utility Header (X1) The Utility header is shared with PS/2 mouse and keyboard, Speaker, Reset Switch, Power Button, and Battery. An adapter cable for the PS/2 devices is available. Connector type: IDC10 pin header 2.54 mm Adapter cable: Article number 862-0004-10 Table 3-10: PS/2 Keyboard and Mouse Signals (X1) Pin Signal Pin Signal 1 Speaker 2 Mouse Clock 3 Reset-In 4 Mouse Data 5 KB Data 6 KB Clock 7 GND 8 +VCC_PS2 9 Ext.
Power Button To power up/down the board, the signal Power Button must be pulled to GND. Table 3-12: Power Button Signals (X1) Pin Signal Pin Signal 1 Speaker 2 Mouse Clock 3 Reset-In 4 Mouse Data 5 KB Data 6 KB Clock 7 GND 8 +5V Standby 9 Ext. Battery 10 Power Button Reset Switch To reset the CPU using a reset switch, the Reset Switch signal must be pulled to GND.
CM1-86DX2 3.7 USB 2.0 Ports The Vortex-86DX2 contains one Enhanced Host Controller Interface (EHCI) host controller, which supports up to four USB 2.0 high-speed root ports. USB 2.0 allows data transfers up to 480Mb/s using the same pins as the four USB full-speed/low-speed ports. The Vortex-86DX2 contains port-routing logic that determines whether a USB port is controlled by the UHCI controller or by the EHCI controller. The CM1-86DX2 uses three of the four ports.
USB 2.0 Port 2 Header (X7)* Connector type: DC10 pin header 2.54 mm Adapter cable: Article number 862-0088-10 Table 3-16: USB Port 2 Signals (X7) Pin Signal Pin Signal 1 ETH0_TXp 2 ETH0_TXn 3 ETH0_RXp 4 ETH0_PE 5 NC 6 ETH0_RXn 7* USB2_p 8* USB2_n 9 +VCC_USB2 10 GND_USB2 *The CM1-86DX2-512 model does not offer the USB function on the X7 connector. 3.8 HD-Audio The High Definition (HD) Audio Controller communicates with the external HD Audio codec over the HD Audio Link.
CM1-86DX2 Audio Header (X23) Connector type: DC16 pin header, 2.
3.9 Serial Ports Each of the four serial ports is located on one dedicated IDC header (COM1-4.) The ports either work in RS232 or RS485 modes, selectable in the BIOS (modification required) or with a user application. Termination resistors for RS485 Mode must be set by a DIPSwitch (SW1 or SW2). To enable the transmitters of COM1 through COM4 in RS485 mode set the RTS# signal to ‘1’.
CM1-86DX2 The maximum current on all supply pins is 0.5A. RS485/422 Termination Typically the RS485 cabling is done as a bus system with two or more devices on the bus. The cabling can be done in 4-wire mode (RX+, RX-, TX+, TX- using 4 independent wires) or 2-wire mode (RX+, TX+ and TX-, RX- are using 2 wires). In RS485 Mode the differential pairs should be terminated with 120 Ω if the device is located at the beginning or end of the bus.
3.10 LPT Interface (X19) The parallel port is located on an IC26 header. An adapter cable with standard DSUB-25 female connector is available. The parallel port is programmable in BIOS. Enter ADVANCED>CHIPSET>Southbridge Configuration>Serial/Parallel Port Configuration for access to the following settings. Table 3-19: BMC Service Connector (X24) LPT Parameter Possible Settings Base Address Disabled, 0x378 and 0x278 Mode BPP, EPP 1.9 and SPP, ECP, ECP and EPP 1.9, SPP, EPP 1.7 and SPP, ECP and EPP 1.
CM1-86DX2 3.11 MiniPCI-Express Interface (X10) Connector type: MiniPCIe/MiniCard socket/mSATA socket Table 3-21: MiniPCIe Interface (X10) Pin Signal Pin Signal 1 n.c. 2 3.3 V 3 n.c. 4 GND 5 n.c. 6 1.5 V 7 CLKREQ# 8 n.c. 9 GND 10 n.c. 11 PCIE1_CLK_n 12 n.c. 13 PCIE1_CLK_p 14 n.c. 15 GND 16 n.c. Mechanical Key 17 Reserved 18 GND 19 Reserved 20 n.c. 21 GND 22 PERST# 23 PCIE1_RX_n 24 3.3 V 25 PCIE1_RX_p 26 GND 27 GND 28 1.
MiniPCIe-Card-Mode Jumper Header (X20) The default setting is the automatic detection mode (shown below), where pins 3-4 are connected. To force mini card operation, pins 5-6 must be connected. The mSATA mode is forced by connecting pins 1-2 on the jumper block X20. Table 3-22: PCIe Mini Card Jumper Signals (X20) Pin 1 3 5 Signal +3.
CM1-86DX2 PC/104 Bus Connector (X14) Table 3-23: PC/104 Signals Pin Pin D C A B 1 IOCHCK# GND 2 D7 RSTDRV 3 D6 +5V 4 D5 IRQ9 5 D4 -5V 6 D3 DRQ2 7 D2 -12V 8 D1 0WS# 0 GND GND 9 D0 +12V 1 MEMCS16# SBHE# 10 IOCHRDY KEY 2 IOCS16# LA23 11 AEN SMEMW# 3 IRQ10 LA22 12 A19 SMEMR# 4 IRQ11 LA21 13 A18 IOW# 5 IRQ12 LA20 14 A17 IOR# 6 IRQ15 LA19 15 A16 DACK3# 7 IRQ14 LA18 16 A15 DRQ3 8 DACK0# LA17 17 A14 DACK1# 9 DRQ0 MEMR# 18 A13
3.13 BMC Service Connector (X24) This connector is only needed in case of updates of the BMC. For further information, please contact our support team. In most cases this connector is not needed by the user and is intended for production testing. X24 offers the opportunity to connect I2C devices to the CM1-86DX2. Table 3-24: BMC Service Connector (X24) Pin I2C0, X24 (3.
CM1-86DX2 The reference voltage is not intended to supply equipment other than low power equipment (Imax < 150 mA). The 8 analog channels are multiplexed through one conversion engine. So the sample rate is shared. This means the more channels that are active, the less the individual sample rate per channel will be. The GPIOs on X17 are 5V tolerant. So you can connect up to 5V to these GPIOs. X17 Connector type: Hirose, DF13_10P-1.25H X21 Connector type: Hirose, DF13_12P-1.
3.16 I2C Bus (X21) The CM1-86DX2 offers an I2C Bus for user applications. This Bus can be used to connect other devices which communicate over the I2C-Bus. The High-Level of this bus is 3.3V. Table 3-26: I2C Signals (X21) Pin 42 I2C0, X21 1 ADC_VCC (3.
CM1-86DX2 4 Using the Module 4.1 BIOS The CM1-86DX2 features an AMI BIOS. The default settings provide a “ready to run” system, even without a BIOS setup backup battery. The BIOS is located in flash memory and can be easily updated with software under DOS. All setup changes of the BIOS are stored in the CMOS RAM. The soldered battery will provide power to store that information for over two years without board activation.
The use of inappropriate values on any of the following advanced settings below may cause system to malfunction. “IDE Configuration” defines which parts of the controller are activated and what settings are used. The recommended settings are shown below.
CM1-86DX2 Recommended IDE settings for booting Windows: IDE Operate Mode [Native Mode] Standard IDE Compatible [Disabled] Recommended IDE settings for booting Linux: IDE Operate Mode [Native Mode] Standard IDE Compatible [Enabled] Using the Module 45
46 Using the Module
CM1-86DX2 PCIPnP Using the Module 47
48 Using the Module
CM1-86DX2 Boot screen If more than one drive is attached to the CM1-86DX2, you can select from the first “Boot Settings” screen the boot order the drives are scanned for a bootable OS image. The allows you to configure the boot behavior for a graphically enhanced BIOS SETUP UTILITY.
Chipset screen 50 Using the Module
CM1-86DX2 Using the Module 51
52 Using the Module
CM1-86DX2 Security screen Using the Module 53
Exit screen 4.2 SEMA functions The onboard Microcontroller implements power sequencing and SEMA functionality. The microcontroller communicates through the System Management Bus with the SoC. The following functions are available: 54 Total operating hours counter Counts the time the module has been run in minutes. On-time minutes counter Counts the seconds since last system start.
CM1-86DX2 The SEMA Tools are available for Windows and Linux. SEMA functionality can also be used in applications. Refer to the SEMA software manual and technical manual on the ADLINK web site for more information. Board Specific SEMA functions Voltages The BMC of the CM1-86DX2 implements a Voltage Monitor and samples several Onboard Voltages. The Voltages can be read by calling the SEMA function, “Get Voltages”. The function returns a 16-bit value divided in Hi-Byte (MSB) and Lo-Byte (LSB).
Exception Blink Codes In the case of an error, the BMC shows a blink code on the STATUS-LED. This error code is also reported by the BMC Flags register. The Exception Code is not stored in the Flash storage and is cleared when the power is removed. Therefore, the “Clear Exception Code”-Command is not supported.
CM1-86DX2 4.5 Programming Examples The following programming examples are provided based on a Linux operating system. If other operating systems are used, some header files could be unnecessary or they may have different names. The "iopl()" function is a Linux specific function and defined inside the iopl.h header file. In Windows XP, a tool called "porttalk" can be used instead.
#set direction of RS232/485 mode switch GPIOs to output dir_reg=$(./dx2_gp 3 d g) echo "RAW Value for dir_reg: 0x$dir_reg" dir_reg=$(printf %02x $((0x$dir_reg|0xc0))) echo "new Value for dir_reg: 0x$dir_reg" ./dx2_gp 3 d $dir_reg #set RS485 mode: output=1 data_reg=$(./dx2_gp 3 i 1) echo "RAW Value for data_reg: 0x$data_reg" data_reg=$(printf %02x $((0x$data_reg&0x3F))) echo "new Value for data_reg: 0x$data_reg" .
CM1-86DX2 outb(0xC5, WDT0_DATA); //set time counter register: 0x3b, 0x3a, 0x39 outb(0x3b, WDT0_INDEX); //D23...D16 outb((wdog_time >> 16) & 0xFF, WDT0_DATA); outb(0x3a, WDT0_INDEX); //D15...D8 outb((wdog_time >> 8) & 0xFF, WDT0_DATA); outb(0x39, WDT0_INDEX); //D7...
//set time counter register: 0xac, 0xab, 0xaa outb((wdog_time >> 16) & 0xFF, 0xac); //D23...D16 outb((wdog_time >> 8) & 0xFF, 0xab); //D15...D8 outb(wdog_time & 0xFF, 0xaa); //D7...
CM1-86DX2 #define #define #define #define #define #define #define ADC_AUX_CHS ADC_BASE_ADDR+0 // AUX channel register ADC_CTRL_REG ADC_BASE_ADDR+1 // ADC control register ADC_STATUS ADC_BASE_ADDR+2 // ADC status register ADC_DATA ADC_BASE_ADDR+4 // ADC data register ADC_READY_MASK 0x01 ADC_CH_MASK 0xFF // bits[15:13] represent the ADC channel ADC_VAL_MASK 0x07FF // bits[10:0] represent the result value // SB function 0 addresses and offsets // base address of 32 bit wide On-Chip Device Control Register in
} adc_channel = (unsigned char)strtol(argv[1], NULL, 16); if( adc_channel < 0 || adc_channel > 7 ) { usage(); return 3; } adcChannel = 0x00 | (1 << adc_channel); // set the selected ADC channel int i=0; for( i=17 ; i>0 ; --i ) {// Get the 16'th value as a valid one // This is necessary to flush the FIFO / *################################################################## ########## # 2. power down temperature sensor on SB function 0 --> ON_CHIP_CTRL_REG[31] = 1 # 2a.
CM1-86DX2 outb( adcChannel, ADC_AUX_CHS ); // ################################################################### ############# / *################################################################## ############## 5.
4.
CM1-86DX2 Instruction Counter Registers Table 4-6: Instruction Counter Registers Address range (hex) Description 0493 – 0490 Instruction Counter Register 0497 – 0494 User Instruction Counter Register 0498 UIC Start Register 0499 UIC Stop Register Timer/Counter Registers Table 4-7: Timer/Counter Registers Address range (hex) Description 0040 Timer / Counter 0 Count Register 0041 Timer / Counter 1 Count Register 0042 Timer / Counter 2 Count Register 0043 Timer / Counter Control Register I
Watchdog0 Control Registers These registers are accessible only with the indirect addressing of registers 0022h/0023h, as shown in Table 4-13. (See also Watchdog0 Example.
CM1-86DX2 System Control Register Table 4-15: System Control Register Address range (hex) 0092 Description System Control Register DOS 4Gpage Access Registers Table 4-16: DOS 4Gpage Access Registers Address range (hex) Description 00E3 – 00E0 D4GA1 Control and Source Address Register 00E7 – 00E4 D4GA1 Destination Address Register 00EB – 00E8 D4GA2 Control and Source Address Register 00E7 – 00E0 D4GA2 Destination Address Register Spare Registers Table 4-17: Spare Registers Address range (hex) 00
4.
CM1-86DX2 4.10 Contact Information Table 4-20: Technical Support Contact Information Method Contact Information Ask an Expert http://www.adlinktech.com/AAE/ Web Site http://www.adlinktech.com Standard Mail Contact us should you require any service or assistance. ADLINK Technology, Inc. Address: 9F, No.166 Jian Yi Road, Zhonghe District New Taipei City 235, Taiwan ᄅؑקխࡉ৬ԫሁ 166 ᇆ 9 ᑔ Tel: +886-2-8226-5877 Fax: +886-2-8226-5717 Email: service@adlinktech.com Ampro ADLINK Technology, Inc.
Table 4-20: Technical Support Contact Information (Continued) ADLINK Technology, Inc. (French Liaison Office) Address: 15 rue Emile Baudot, 91300 Massy CEDEX, France Tel: +33 (0) 1 60 12 35 66 Fax: +33 (0) 1 60 12 35 66 Email: france@adlinktech.com ADLINK Technology Japan Corporation Address: ࠛ101-0045 ᮾி㒔༓௦⏣༊⚄⏣㘫෬⏫ 3-7-4 ⚄⏣ 374 ࣅࣝ 4F KANDA374 Bldg. 4F, 3-7-4 Kanda Kajicho, Chiyoda-ku, Tokyo 101-0045, Japan Tel: +81-3-4455-3722 Fax: +81-3-5209-6013 Email: japan@adlinktech.com ADLINK Technology, Inc.
CM1-86DX2 4.10.2 Getting Help Should you have technical questions that are not covered by the respective manuals, please contact our support department at http://askanexpert.adlinktech.com/AAE/Answers.aspx Please allow one working day for an answer. 4.10.3 Returning Products for Repair To return a product to ADLINK Technology for repair, you need to get a Return Material Authorization (RMA) number first. Please print the RMA Request Form from http://www.adlinktech.com/lippert/rma.
72 Using the Module