Intel Network Card LPCI 7200S User Manual

NuDAQ® / NuIPC®  
PCI-7200 / cPCI-7200 / LPCI-7200S  
12MB/S High Speed  
Digital Input/ Output Card  
User’s Guide  
Recycled Paper  
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©Copyright 2003 ADLINK Technology Inc.  
All Rights Reserved.  
Manual Rev. 2.30: October 13, 2003  
Part No: 50-11102-101  
The information in this document is subject to change without prior notice in  
order to improve reliability, design, and function and does not represent a  
commitment on the part of the manufacturer.  
In no event will the manufacturer be liable for direct, indirect, special, incidental,  
or consequential damages arising out of the use or inability to use the product  
or documentation, even if advised of the possibility of such damages.  
This document contains proprietary information protected by copyright. All  
rights are reserved. No part of this manual may be reproduced by any  
mechanical, electronic, or other means in any form without prior written  
permission of the manufacturer.  
Trademarks  
NuDAQ, NuIPC, DAQBench are registered trademarks of ADLINK Technology  
Inc.  
Other product names mentioned herein are used for identification purposes  
only and may be trademarks and/or registered trademarks of their respective  
companies.  
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Customer Satisfaction is top priority for ADLINK TECHNOLOGY INC. If you  
need any help or service, please contact us.  
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Please email or FAX your detailed information for prompt, satisfactory, and  
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Questions  
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Table of Contents  
Chapter 1 Introduction.........................................1  
1.1 Applications......................................................................... 1  
1.2 Features ............................................................................... 2  
1.3 Specifications...................................................................... 2  
1.4 Software Supporting........................................................... 4  
1.4.1  
1.4.2  
1.4.3  
1.4.4  
1.4.5  
1.4.6  
1.4.7  
1.4.8  
1.4.9  
Programming Library .......................................................... 4  
PCIS-LVIEW: LabVIEW® Driver ........................................... 5  
PCIS-VEE: HP-VEE Driver ................................................... 5  
DAQBenchTM: ActiveX Controls ......................................... 5  
DASYLabTM PRO .................................................................. 5  
PCIS-DDE: DDE Server and InTouchTM ............................. 5  
PCIS-ISG: ISaGRAFTM driver............................................... 6  
PCIS-ICL: InControlTM Driver............................................... 6  
PCIS-OPC: OPC Server ........................................................ 6  
Chapter 2 Installation ..........................................7  
2.1 What Included ....................................................................... 7  
2.2 Unpacking ............................................................................. 8  
2.3 Device Installation for Windows Systems ............................. 8  
2.4 PCI-7200/cPCI-7200/LPCI-7200S’s Layout.......................... 9  
2.5 Hardware Installation Outline.............................................. 13  
2.6 Connector Pin Assignments................................................ 14  
2.6.1  
2.6.2  
2.6.3  
PCI-7200 Pin Assignments.................................................. 14  
cPCI-7200 Pin Assignments ................................................ 16  
LPCI-7200S Pin Assignments.............................................. 17  
2.7 8254 for Timer Pacer Generation........................................ 19  
2.8 LPCI-7200S PCI Bus Signaling........................................... 20  
2.9 Onboard Pull-ups and Terminations in digital input............ 20  
Chapter 3 Register Format.................................21  
3.1 I/O Registers Format........................................................... 21  
3.2 Digital Input Register (BASE + 10)...................................... 22  
3.3 Digital Output Register (BASE + 14)................................... 22  
3.4 DIO Status & Control Register (BASE + 18)....................... 22  
3.5 Interrupt Status & Control Register (BASE + 1C) ............... 24  
3.6 8254 Timer Registers (BASE + 0)....................................... 27  
Chapter 4 Operation Theory...............................29  
4.1 Direct Program Control ....................................................... 29  
4.2 Timer Pacer Mode............................................................... 30  
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4.3 External Clock Mode........................................................... 31  
4.4 Handshaking ....................................................................... 31  
4.5 Timing Characteristic .......................................................... 33  
Chapter 5 C/C++ Libraries..................................37  
5.1 Libraries Installation ............................................................ 37  
5.2 Programming Guide............................................................ 38  
5.2.1  
5.2.2  
Naming Convention ............................................................. 38  
Data Types .......................................................................... 38  
5.3 _7200_Initial........................................................................ 39  
5.4 _7200_Switch_Card_No ..................................................... 40  
5.5 _7200_AUX_DI ................................................................... 40  
5.6 _7200_AUX_DI_Channel.................................................... 41  
5.7 _7200_AUX_DO.................................................................. 41  
5.8 _7200_AUX_DO_Channel.................................................. 42  
5.9 _7200_DI............................................................................. 42  
5.10 _7200_DI_Channel ............................................................. 43  
5.11 _7200_DO........................................................................... 43  
5.12 _7200_DO_Channel ........................................................... 44  
5.13 _7200_Alloc_DMA_Mem .................................................... 45  
5.14 _7200_Free_DMA_Mem..................................................... 46  
5.15 _7200_Alloc_DBDMA_Mem ............................................... 46  
5.16 _7200_Free_DBDMA_Mem................................................ 47  
5.17 _7200_DI_DMA_Start......................................................... 47  
5.18 _7200_DI_DMA_Status ...................................................... 50  
5.19 _7200_DI_DMA_Stop ......................................................... 51  
5.20 _7200_DblBufferMode ........................................................ 51  
5.21 _7200_CheckHalfReady ..................................................... 52  
5.22 _7200_DblBufferTransfer.................................................... 52  
5.23 _7200_GetOverrunStatus ................................................... 53  
5.24 _7200_DO_DMA_Start ....................................................... 53  
5.25 _7200_DO_DMA_Status..................................................... 54  
5.26 _7200_DO_DMA_Stop ....................................................... 55  
5.27 _7200_DI_Timer.................................................................. 56  
5.28 _7200_DO_Timer................................................................ 57  
Chapter 6 Double Buffer Mode Principle ...........59  
Chapter 7 Limitations ........................................61  
Warranty.............................................................63  
Table of Contents ii  
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How to Use This Guide  
This manual is designed to help users use the PCI-7200, cPCI-7200, and  
LPCI-7200S. The functionality of PCI-7200, cPCI-7200, and LPCI-7200S are  
the same except that the cPCI-7200 has 4 auxiliary digital inputs and outputs.  
In this guide, “PCI-7200” represents PCI-7200, cPCI-7200, and LPCI-7200S if  
not specified.  
The manual describes how to modify various settings on the PCI-7200 card to  
meet application requirements. It is divided into seven chapters:  
Chapter 1  
Chapter 2  
Introduction  
Gives an overview of product features, applications, and  
specifications.  
Installation  
Describes how to install the PCI-7200. The layout of PCI-7200 is  
shown, and the installation procedures, pin assignment of  
connectors, and timer pacer generation are specified.  
Chapter 3  
Register Structure & Format  
Describes the low-level register structure and format of the  
PCI-7200.  
Chapter 4  
Chapter 5  
Operation Theory  
Describes how the PCI-7200 works.  
C/C++ & DLL Libraries  
Describes the high level C and DLL libraries to assist with  
programming in DOS and Windows environments.  
Chapter 6  
Chapter 7  
Double Buffer Mode Principle  
Describes the data buffer for double-buffered DMA DI  
operations.  
Limitations  
Describes three limitations on using PCI-7200.  
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1
Introduction  
The PCI-7200, cPCI-7200, and LPCI-7200S are PCI/CompactPCI/Low profile  
PCI form factor high-speed digital I/O cards, consisting of 32 digital input  
channels, and 32 digital output channels. High performance design and  
state-of-the-art technology make this card suitable for high-speed digital input  
and output applications.  
The PCI-7200 performs high-speed data transfers using bus-mastering DMA  
via the 32-bit PCI bus architecture. The maximum data transfer rates can be  
up to 12MB per second—very suitable for interfacing high-speed peripherals  
and your computer system.  
Several different digital I/O operation modes are supported:  
1. Direct Program Control: the digital inputs and outputs can be accessed  
and controlled by its corresponding I/O ports directly.  
2. Timer Pacer Mode: the digital input and output operations are handled by  
internal timer pacer clock and transferred by bus mastering DMA.  
3. External Clock Mode: the digital input operations are handled by an  
external input strobe signal (I_REQ) and transferred by bus mastering DMA.  
4. Handshaking: through the REQ and ACK signals, digital I/O data can utilize  
simple handshaking data transfer.  
1.1 Applications  
Interface to high-speed peripherals  
High-speed data transfers from other computers  
Digital I/O control  
Interface to external high-speed A/D and D/A converter  
Digital pattern generator  
Waveform and pulse generation  
BCD interface driver  
Introduction  
1
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1.2 Features  
The PCI-7200 high-speed DIO Card provides the following advanced features:  
32 TTL digital input channels  
32 TTL digital output channels  
Transfer up to 12M Bytes per second  
High output driving and low input loading  
32-bit PCI bus, Plug and Play  
On-board internal timer pacer clock  
Internal timer controls input sampling rate  
Internal timer controls digital output rate  
ACK and REQ for handshaking  
On-board 32-byte FIFO for both digital input and output  
Extra 2k double word digital input FIFO for cPCI-7200  
4 auxiliary digital input and output channels (cPCI-7200 only)  
Diode terminators for 32 input channels and control  
signals(cPCI-7200/LPCI-7200S)  
Multiple interrupt sources are selectable by software  
1.3 Specifications  
Digital I/O (DIO)  
z Number of DI Channels: 32 TTL compatible  
z Number of DO Channels: 32 TTL compatible  
z Data Transfer Mode  
Program I/O  
Internal timer pacer transfer  
External I_REG strobe input  
Handshake data transfer  
z Maximum Transfer Speed:  
3MHz (12MHz) by external clock, handshake or external strobe  
2MHz (8MHz) by internal timer pacer transfer  
z FIFO:  
z 8 words (32-bit) (for PCI-7200/LPCI-7200S)  
2k + 8 words (32-bit) (for cPCI-7200 Digital input channels)  
2
Introduction  
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z Input Voltage:  
Low: Min. 0V; Max. 0.8V  
High: Min. +2.0V  
z Input Load:  
Low: +0.5V @ -0.6mA max.  
High: +2.7V @ +20µA max.  
z Output Voltage:  
Low: Min. 0V; Max. 0.5V  
High: Min. +2.7V  
z Driving Capacity:  
Low: Max. +0.5V at 24mA (Sink)  
High: Min. 2.4V at -3.0mA (Source)  
Programmable Counter  
z Device: 82C54-10, with a 4MHz time base  
z Timer 0: DI clock source  
z Timer 1: DO clock source  
z Timer2: Base clock of Timer #0 and Timer #1  
z Pacer Output: 0.00046Hz to 2MHz  
General Specifications  
z Operating Temperature: 0ºC to 60ºC  
z Storage Temperature: -20ºC to 80ºC  
z Humidity: 5 to 95%, non-condensing  
z Connector:  
PCI-7200: one 37-pin D-type and one 40-pin ribbon connector  
cPCI-7200: one 100-pin SCSI-type connector  
LPCI-7200S: two 68-pin SCSI-type connectors  
z Dimension:  
PCI-7200: Compact size, only 148mm (L) X 102mm (H)  
cPCI-7200: Standard 3U CompactPCI form factor  
LPCI-7200S: Low Profile PCI, 167.64mm (L) X 64.41mm (H)  
z Power Consumption:  
PCI-7200: +5V @ 720 mA typical  
cPCI-7200: +5V @ 820 mA typical  
LPCI-7200S: +5V @ 500 mA typical  
z PCI signaling environment:  
PCI-7200:  
5V board supports a 5V PCI BUS  
cPCI-7200: 3U Eurocard form factor, CompactPCI compliant  
(PICMG 2.0 R2.1)  
LPCI-7200S: Universal board, supports a 3.3V or 5V PCI BUS  
Introduction  
3
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1.4 Software Supporting  
ADLINK provides versatile software drivers and packages for users’ different  
approach to building a system. We not only provide programming library for  
many Windows systems, but also provide drivers for many software packages  
including LabVIEW®, HP VEETM, DASYLabTM, InTouchTM, InControlTM  
ISaGRAFTM, etc.  
,
All software options are included in the ADLINK CD. Commercial software  
drivers require licenses. Without the software license, users can still install  
them and run the demo version for two hours for demonstration purpose.  
Please contact an ADLINK dealer to purchase licenses.  
1.4.1 Programming Library  
For customers writing customized programs, we provide function libraries for  
many different operating systems, including:  
DOS Library: Borland C/C++ and Microsoft C++ (function descriptions are  
included in this user’s guide).  
Windows 95 DLL: For VB, VC++, Delphi, BC5 (functions descriptions are  
included in this user’s guide).  
PCIS-DASK: Includes device drivers and DLLs for Windows 98,  
Windows NT, and Windows 2000. The DLL is compatible across  
Windows 98, Windows NT, and Windows 2000. All applications  
developed with PCIS-DASK are compatible across Windows 98,  
Windows NT, and Windows 2000. The developing environment can be VB,  
VC++, Delphi, BC5, or any Windows programming language that allows  
calls to a DLL. The PCIS-DASK user’s guide and function reference  
manual are on the CD. Please refer the PDF manual files under the  
\Manual_PDF\Software\PCIS-DASK  
following directory:  
PCIS-DASK/X: Includes device drivers and a shared library for Linux.  
The developing environment can be Gnu C/C++ or any programming  
language that allows linking to a shared library. The PCIS-DASK/X user's  
guide and function reference manual are on the CD  
\Manual_PDF\Software\PCIS-DASK-X  
(
).  
The above software drivers are shipped with the board. Please refer to the  
“Software Installation Guide” to install these drivers.  
4
Introduction  
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1.4.2 PCIS-LVIEW: LabVIEW® Driver  
PCIS-LVIEW contains VIs to interface with NI’s LabVIEW® software package.  
PCIS-LVIEW supports Windows 95/98/NT/2000. The LabVIEW® drivers are  
shipped free with the board. Users can install and use them without a license.  
For detailed information about PCIS-LVIEW, please refer to the user’s guide  
on the CD.  
\Manual_PDF\Software\PCIS-LVIEW  
(
)
1.4.3 PCIS-VEE: HP-VEE Driver  
PCIS-VEE includes the user objects, which are used to interface with the HP  
VEE software package. PCIS-VEE supports Windows 95/98/NT. The HP-VEE  
drivers are shipped free with the board. Users can install and use them without  
a license. For detailed information about PCIS-VEE, please refer to the user’s  
guide on the CD.  
\Manual_PDF\Software\PCIS-VEE  
(
)
1.4.4 DAQBenchTM: ActiveX Controls  
Customers who are familiar with ActiveX controls and VB/VC++ programming  
can use the DAQBench ActiveX Control components library for developing  
applications. DAQBench is designed under Windows NT/98. For more  
detailed information about DAQBench, please refer to the user’s guide on the  
CD.  
\Manual_PDF\Software\DAQBench\DAQBench Manual.PDF  
(
)
1.4.5 DASYLabTM PRO  
DASYLab is an easy-to-use software package that provides easy-setup  
instrument functions such as FFT analysis. Please contact ADLINK to get  
DASYLab PRO, which include DASYLab and ADLINK hardware drivers.  
1.4.6 PCIS-DDE: DDE Server and InTouchTM  
DDE stands for Dynamic Data Exchange specifications. The PCIS-DDE  
includes the PCI cards’ DDE server. The PCIS-DDE server is included on the  
ADLINK CD. It requires a license. The DDE server can be used conjunction  
with any DDE client under Windows NT.  
Introduction  
5
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1.4.7 PCIS-ISG: ISaGRAFTM driver  
The ISaGRAF WorkBench is an IEC1131-3 SoftPLC control program  
development environment. The PCIS-ISG includes ADLINK products’ target  
drivers for ISaGRAF under the Windows NT environment. The PCIS-ISG is  
included on the ADLINK CD. It requires a license.  
1.4.8 PCIS-ICL: InControlTM Driver  
PCIS-ICL is the InControl driver, which support the Windows NT. The  
PCIS-ICL is included on the ADLINK CD. It requires a license.  
1.4.9 PCIS-OPC: OPC Server  
PCIS-OPC is an OPC Server that can link with OPC clients. Many software  
packages on the market provide OPC clients. PCIS-OPC supports Windows  
NT. It requires a license.  
6
Introduction  
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2
Installation  
This chapter describes how to install the PCI-7200. Package contents and  
unpacking information are described. Because the PCI-7200 is a Plug and  
Play device, there are no more jumper or DIP switch settings for configuration.  
The interrupt number and I/O port address are assigned by the system BIOS  
during system boot up.  
2.1 What Included  
In addition to this User's Manual, the package includes the following items:  
PCI-7200 Digital I/O & Counter Card  
ACL-10437: 40-pin to 37-pin D-Sub cable  
or  
cPCI-7200 Digital I/O & Counter Module for 3U CompactPCI  
100-pin SCSI connector assembly  
or  
LPCI-7200S Low profile Digital I/O & Counter Card  
Two 68-pin SCSI connectors assembly  
ADLINK CD  
Software Installation Guide  
If any of these items is missing or damaged, contact the ADLINK dealer. Save  
the shipping materials and carton to ship or store the product in the future.  
Installation  
7
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2.2 Unpacking  
The PCI-7200 card contains sensitive electronic components that can be  
easily damaged by static electricity.  
The work area should have a grounded anti-static mat. The operator should be  
wearing an anti-static wristband, grounded at the same point as the anti-static  
mat.  
Inspect the card module carton for obvious damage. Shipping and handling  
may cause damage to the module. Be sure there is no shipping and handling  
damage on the module before proceeding.  
After opening the card module carton, extract the system module and place it  
only on a grounded anti-static surface component side up.  
Again inspect the module for damage. Press down on all the socketed IC's to  
make sure that they are properly seated. Do this only with the module place on  
a firm flat surface.  
Note:  
DO NOT APPLY POWER TO THE CARD IF IT HAS BEEN DAMAGED.  
You are now ready to install your PCI-7200.  
2.3 Device Installation for Windows Systems  
Once Windows 95/98/2000 has started, the Plug and Play function of  
Windows system will find the new NuDAQ/NuIPC cards. If this is the first time  
to installing NuDAQ/NuIPC cards in this system, Windows will require device  
information source. Please refer to the “Software Installation Guide” for the  
steps of installing the device.  
8
Installation  
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2.4 PCI-7200/cPCI-7200/LPCI-7200S’s Layout  
Figure 2.1(a) PCI-7200 Layout Diagram  
Installation  
9
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Figure 2.1(b) cPCI-7200 Layout Diagram  
10 Installation  
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CN1A  
CN1B  
Figure 2.1(c) LPCI-7200S Layout Diagram  
Installation 11  
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Figure 2.1(d) LPCI-7200S with standard PCI bracket Layout Diagram  
12 Installation  
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2.5 Hardware Installation Outline  
Hardware configuration  
These PCI cards (or CompactPCI, Low Profile PCI cards) are equipped with a  
Plug and Play PCI controller that requests base addresses and interrupts  
according to PCI standard. The system BIOS will install the system resource  
based on the PCI cards’ configuration registers and system parameters (which  
are set by system BIOS). Interrupt assignment and memory usage (I/O port  
locations) of the PCI cards can be assigned by system BIOS only. These  
system resource assignments are done on a board-by-board basis. It is not  
suggested to assign the system resource by any other methods.  
PCI slot selection  
The PCI and Low-Profile PCI cards can be inserted to any PCI slot without any  
configuration for system resource. CompactPCI peripheral slots are marked  
with a circle on the backplane. Please note that the PCI, CompactPCI, and  
Low-Profile PCI system board must provide bus-mastering capability to  
operate this board well.  
Installation Procedures  
1. Turn off the computer  
2. Turn off all accessories (printer, modem, monitor, etc.) connected to the  
computer  
3. Remove the cover from your computer  
4. Select a 32-bit PCI slot. PCI slot are short than ISA or EISA slots, and are  
usually white or ivory  
5. Before handling the PCI cards, discharge any static buildup on your body by  
touching the metal case of the computer. Hold the edge of the card and do  
not touch the components  
6. Position the board into the PCI selected slot.  
7. Secure the card in place at the rear panel of the system  
Running 7200UTIL.EXE  
The IRQ number and I/O port address can be configured by the system. Use  
7200UTIL.EXE  
the  
utility to displayed the above values. A testing program is  
included in this utility to check if the PCI-7200 can work properly. Refer to  
Section 5.2 for further information.  
Installation 13  
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2.6 Connector Pin Assignments  
2.6.1 PCI-7200 Pin Assignments  
The PCI-7200 comes equipped with one 37-pin D-Sub connector (CN2)  
located on the rear mounting plate and one 40-pin female flat cable header  
connector (CN1). The CN2 is located on the rear mounting plate; the CN1 is on  
front of the board. Refer section 2.4 PCI-7200‘s layout.  
CN2 is used for digital inputs (DI 0 to DI 15) and digital outputs (DO 0 to DO 15)  
The reminding digital I/O channels DI 16 to DI 31 and DO 16 to DO 31 are on  
CN1. The pin assignment of CN1 and CN2 is illustrated in the Figures 2.2 and  
2.3.  
Legend:  
DO n : Digital Output CH n  
DI n : Digital Input CH n  
GND : Ground  
ACK : ACK handshaking signal  
REQ : REQ handshaking signal  
I_TRG: Input signal to start DI data sampling  
O_TRG: Output signal can be controlled by software  
1
2
DI16  
DI17  
DI18  
DI19  
DI20  
DI21  
DI22  
DI23  
DI24  
DI25  
DI26  
DI27  
DI28  
DI29  
DI30  
DI31  
+5V  
DO16  
DO17  
DO18  
DO19  
DO20  
DO21  
DO22  
DO23  
DO24  
DO25  
DO26  
DO27  
DO28  
DO29  
DO30  
DO31  
GND  
3
4
5
6
7
8
9
10  
12  
14  
16  
18  
20  
22  
24  
26  
28  
30  
32  
34  
36  
38  
40  
11  
13  
15  
17  
19  
21  
23  
25  
27  
29  
31  
33  
35  
37  
39  
O_ACK  
O_REQ  
N/C  
O_TR1  
N/C  
N/C  
Figure 2.2 CN1 Pin Assignments  
14 Installation  
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1
2
3
DI 0  
DI 1  
DI 2  
DI 3  
20  
21  
DO0  
DO1  
DO2  
DO3  
DO4  
DO5  
22  
23  
24  
25  
4
5
DI 4  
DI 5  
DI 6  
6
7
26  
27  
8
DO6  
DO7  
DO8  
DO9  
DO10  
DI 7  
DI 8  
DI 9  
DI10  
DI11  
9
28  
29  
10  
11  
12  
13  
30  
31  
32  
DO11  
DO12  
DO13  
DO14  
DO15  
GND  
DI12  
DI13  
DI14  
DI15  
+5V  
14  
15  
16  
17  
33  
34  
35  
36  
37  
18  
19  
I_ACK  
I_REQ  
I_TRG  
Figure 2.3 CN2 Pin Assignments  
Installation 15  
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2.6.2 cPCI-7200 Pin Assignments  
(1)  
(2)  
(3)  
(51
(52
(53
(1) DO0  
(26) O_TRG (51) DO1  
(27) O_REQ (52) DO3  
(28) O_ACK (53) DO5  
(29) AUXIN2 (54) DO7  
(30) AUXIN3 (55) DO9  
(76) GND  
(77) GND  
(78) GND  
(79) AuxOut2  
(80) AuxOut3  
(81) GND  
(82) GND  
(83) GND  
(84) DIN1  
(85) DIN3  
(86) DIN5  
(87) DIN7  
(88) DIN9  
(89) DIN11  
(90) DIN13  
(91) DIN15  
(92) GND  
(93) DIN17  
(94) DIN19  
(95) DIN21  
(2) DO2  
(3) DO4  
(4) DO6  
(5) DO8  
(6) DO10  
(7) DO12  
(8) DO14  
(9) GND  
(31) +5Vout  
(32) +5Vout  
(33) GND  
(34) DIN0  
(35) DIN2  
(36) DIN4  
(37) DIN6  
(38) DIN8  
(39) DIN10  
(40) DIN12  
(41) DIN14  
(42) GND  
(43) DIN16  
(44) DIN18  
(45) DIN20  
(56) DO11  
(57) DO13  
(58) DO15  
(59) GND  
(60) DO17  
(61) DO19  
(62) DO21  
(63) DO23  
(64) DO25  
(65) DO27  
(66) DO29  
(67) DO31  
(68) GND  
(69) GND  
(70) GND  
(10) DO16  
(11) DO18  
(12) DO20  
(13) DO22  
(14) DO24  
(15) DO26  
(16) DO28  
(17) DO30  
(18) GND  
(19) +5Vout  
(20) +5Vout  
(48)  
(49)  
(50)  
(9
(21) AUXIN0 (46) DIN22  
(71) AuxOut0 (96) DIN23  
(72) AuxOut1 (97) DIN25  
(9
(1
(22) AUXIN1 (47) DIN24  
(23) I_TRG  
(48) DIN26  
(49) DIN28  
(50) DIN30  
(73) GND  
(74) GND  
(75) GND  
(98) DIN27  
(99) DIN29  
(100) DIN31  
(24) I_REQ  
(25) I ACK  
Figure 2.4 CN Pin Assignments  
16 Installation  
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2.6.3 LPCI-7200S Pin Assignments  
DIN0 A1 A35 GND  
DIN1 A2 A36 GND  
DIN2 A3 A37 GND  
DIN3 A4 A38 GND  
DIN4 A5 A39 GND  
DIN5 A6 A40 GND  
DIN6 A7 A41 GND  
DIN7 A8 A42 GND  
DIN8 A9 A43 GND  
DIN9 A10 A44 GND  
DIN10 A11 A45 GND  
DIN11 A12 A46 GND  
DIN12 A13 A47 GND  
DIN13 A14 A48 GND  
DIN14 A15 A49 GND  
DIN15 A16 A50 GND  
DIN16 A17 A51 GND  
DIN17 A18 A52 GND  
DIN18 A19 A53 GND  
DIN19 A20 A54 GND  
DIN20 A21 A55 GND  
DIN21 A22 A56 GND  
DIN22 A23 A57 GND  
DIN23 A24 A58 GND  
DIN24 A25 A59 GND  
DIN25 A26 A60 GND  
DIN26 A27 A61 GND  
DIN27 A28 A62 GND  
DIN28 A29 A63 GND  
DIN29 A30 A64 GND  
DIN30 A31 A65 GND  
DIN31 A32 A66 GND  
I_REQ A33 A67 I_ACK  
I_TRG A34 A68 5Vout  
Figure 2.5 CN1A Pin Assignments  
Installation 17  
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DOUT0 B1 B35 GND  
DOUT1 B2 B36 GND  
DOUT2 B3 B37 GND  
DOUT3 B4 B38 GND  
DOUT4 B5 B39 GND  
DOUT5 B6 B40 GND  
DOUT6 B7 B41 GND  
DOUT7 B8 B42 GND  
DOUT8 B9 B43 GND  
DOUT9 B10 B44 GND  
DOUT10 B11 B45 GND  
DOUT11 B12 B46 GND  
DOUT12 B13 B47 GND  
DOUT13 B14 B48 GND  
DOUT14 B15 B49 GND  
DOUT15 B16 B50 GND  
DOUT16 B17 B51 GND  
DOUT17 B18 B52 GND  
DOUT18 B19 B53 GND  
DOUT19 B20 B54 GND  
DOUT20 B21 B55 GND  
DOUT21 B22 B56 GND  
DOUT22 B23 B57 GND  
DOUT23 B24 B58 GND  
DOUT24 B25 B59 GND  
DOUT25 B26 B60 GND  
DOUT26 B27 B61 GND  
DOUT27 B28 B62 GND  
DOUT28 B29 B63 GND  
DOUT29 B30 B64 GND  
DOUT30 B31 B65 GND  
DOUT31 B32 B66 GND  
O_REQ B33 B67 O_ACK  
O_TRG B34 B68 5Vout  
Figure 2.6 CN1B Pin Assignments  
18 Installation  
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2.7 8254 for Timer Pacer Generation  
8254 Timer/Counter  
Timer 0  
CLK0  
GATE0  
Digital Input Timer Pacer  
OUT0  
“H”  
Timer 1  
Timer 2  
CLK1  
Digital Output Timer Pacer  
GATE1  
OUT1  
OUT2  
“H”  
4MHz Clock  
CLK2  
GATE2  
“H”  
Figure 2.7 8254 configuration  
The internal timer/counter 8254 on the PCI-7200 is configured as the above  
diagram (Figure 2.7). Users can use it to generate the timer pacer for both  
digital input and digital output triggers.  
The digital input timer pacer is from OUT0 (Timer 0), and the digital output  
timer pacer is from OUT1 (Timer 1). Besides, Timer 0 and Timer 2 can be  
cascaded together to generate more timer pacer frequencies for digital input.  
Also, Timer 2 can be cascaded with Timer 1 for digital output.  
pacer rate = 4MHz / ( C0 * C2)  
if Timer 0 & Timer 2 are cascaded  
pacer rate = 4MHz / C0  
if timer 0 & Timer 2 are not cascaded  
The maximum pacer signal rate of input and output are 4MHz/2 = 2Mhz. The  
minimum signal rate is 4MHz/65535/65535.  
For example, to get a pacer rate of 2.5kHz, set C0 = 40 and C2 = 40. That is  
2.5KHz = 4Mhz / (40 x 40)  
Installation 19  
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2.8 LPCI-7200S PCI Bus Signaling  
Low-Profile PCI is a new PCI card standard for space-constrained system  
designs. The new form factor maintain the same electrical protocols, PCI signals,  
and software drivers as standard PCI v2.2 expansion cards. However,  
Low-Profile PCI bus interface only supports 3.3V signaling. To support both 5V  
and 3.3V signaling, LPCI-7200S implements 5V I/O tolerant bus switches to  
achieve the I/O voltage transition. This allows LPCI-7200S to be used in both 5V  
and 3.3V systems.  
2.9 Onboard Pull-ups and Terminations in digital input  
The PCI-7200, cPCI-7200 and LPCI-7200S have 32 digital input channels.  
On-board pull-ups and terminations for digital input circuits may be needed for  
some applications. The pull-ups guarantee a fixed input state when  
external connections are floating. Schottky terminations can minimize  
undershoot/overshoot disturbances caused by reflection noise on high-speed  
bus lines. Table 2.1 lists the pull-ups and termination status of PCI-7200,  
cPCI-7200 and LPCI-7200S. Figure 2.8 is the illustration of the pull-up resistor  
and terminations on-board.  
Pull-up resistor  
None  
Terminations  
None  
PCI-7200  
Schottky diode clamped  
to ground & power  
Schottky diode clamped  
to ground & power  
cPCI-7200  
None  
LPCI-7200S  
10k  
Table 2.1 pull-ups and termination of PCI/cPCI-7200 and LPCI-7200S.  
VCC  
D-type  
Flip-Flop  
D
Q
Digital input  
GND  
Figure 2.8 Digital input pull-up resistor and termination circuit diagram.  
20 Installation  
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3
Register Format  
3.1 I/O Registers Format  
The PCI-7200 occupies 8 consecutive 32-bit I/O addresses in the PC I/O  
address space. The cPCI-7200 occupies 9 consecutive 32-bit I/O addresses.  
Table 4.1 shows the I/O Map  
Address  
Read  
Write  
Base + 0  
Base + 4  
Base + 8  
Base + C  
Base + 10  
Counter 0  
Counter 1  
Counter 2  
Counter 0  
Counter 1  
Counter 2  
CLK Control CW0  
---  
---  
Digital Input Reg.  
Digital Output  
(Read-back)  
DIO Status & Control  
INT Status & Control  
Base + 14  
Digital Output Reg.  
Base + 18  
Base + 1C  
Base + 20  
(cPCI-7200  
only)  
DIO Status &Control  
INT Status & Control  
AUXDIO Reg.  
AUXDO Reg.  
Note:  
(1) I/O port is 32-bits wide  
(2) 8-bit or 16-bit I/O access is not allowed  
Register Format 21  
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3.2 Digital Input Register (BASE + 10)  
32 digital input channels can be read from this register  
Address: BASE + 10  
Attribute: READ Only  
Data Format:  
Byte  
7
6
5
4
3
2
1
0
Base +10  
Base +11  
Base +12  
Base +13  
DI7  
DI6  
DI5  
DI4  
DI3  
DI2  
DI1  
DI9  
DI17  
DI25  
DI0  
DI8  
DI16  
DI24  
DI15  
DI23  
DI31  
DI14  
DI22  
DI30  
DI13  
DI21  
DI29  
DI12  
DI20  
DI28  
DI11  
DI19  
DI27  
DI10  
DI18  
DI26  
3.3 Digital Output Register (BASE + 14)  
32 digital output channels can be written and read to/from this register  
Address: BASE + 14  
Attribute: READ/WRITE  
Data Format:  
Byte  
7
6
5
4
3
2
1
0
Base +14  
Base +15  
Base +16  
Base +17  
DO7  
DO6  
DO5  
DO4  
DO3  
DO2  
DO1  
DO0  
DO8  
DO15 DO14 DO13 DO12 DO11 DO10 DO9  
DO23 DO22 DO21 DO20 DO19 DO18 DO17 DO16  
DO31 DO30 DO29 DO28 DO27 DO26 DO25 DO24  
The digital output status can be read back through the same location (BASE +  
14)  
3.4 DIO Status & Control Register (BASE + 18)  
The data transfer mode of digital input is controlled and status is checked  
through this register.  
Address: BASE + 18  
Attribute: READ/WRITE  
Data Format:  
Byte  
7
6
5
4
3
2
1
0
Base +18 O_ACK DIN_EN I_TRG TRGPL I_FIFO  
I_TIME0 I_REQ  
I_ACK  
Base +19 ----  
Base +20 ----  
Base +21 ----  
I_OVER ----  
----  
----  
----  
O_TRG O_FIFO O_TIME1 O_REQ  
----  
----  
----  
----  
----  
----  
----  
----  
----  
----  
O_UND  
----  
22 Register Format  
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Digital Input Mode Setting:  
I_ACK: Input ACK Enable  
1: Input ACK is enabled (input ACK will be asserted after input data is  
read by CPU or written to input FIFO)  
0: Input ACK is disabled  
I_REQ: Input REQ Strobe Enabled  
1: Use I_REQ edge to latch input data  
0: I_REQ is disabled  
I_TIME0: Input Timer 0 Enable  
1: Input is sampled by falling edge of Counter 0 output (COUT0)  
0: Input Timer 0 is disabled  
I_FIFO: Input FIFO Enable Mode  
1: Input FIFO is enabled (input data is saved to input FIFO)  
0: Input FIFO is disabled  
TRGPOL: Input Trigger Polarity  
1: I_TRG is Rising Edge Active  
0: I_TRG is Falling Edge Active  
I_TRG: External Trigger Enable  
1: Wait until I_TRG signal is active, digital input sampling will begin  
after a rising or falling edge of I_TRG  
0: Start input sampling immediately (if input control register is set)  
DIN_EN: Digital Input Enable  
1: Digital Input Enable  
0: Digital Input Disabled, when this bit is set as 0, all digital input  
operation will be stopped  
Digital Output Mode Setting:  
O_ACK: Output ACK Enable  
1: Output ACK is enabled; the output circuit will wait for O_ACK after  
O_REQ strobe is asserted  
0: Output ACK is disabled  
O_REQ: Output REQ Enable  
1: Output REQ is enabled; an O_REQ strobe will be generated after  
output data is ready  
0: Output REQ is disabled  
O_TIME1: Output Timer 1 Enable  
1: Output Timer 1 is enabled; output data is moved from output FIFO  
to DO registers when output of Counter1 goes low  
0: Output Counter 1 is disabled  
O_FIFO: Output FIFO Enable  
1: Output FIFO is enabled (output data is moved from output FIFO)  
0: Output FIFO is disabled  
Register Format 23  
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O_TRG: Digital Output Trigger Signal  
This bit is used to control the O_TRG output of PCI-7200; the signal is  
on CN1 pin 36 of PCI-7200, CN1 pin 26 of cPCI-7200, CN2 pin 34 of  
LPCI 7200S when  
1: O_TRG 1 goes High (1)  
0: O_TRG 1 goes Low (0)  
Digital I/O FIFO Status:  
I_OVR: Input data overrun  
1: Digital Input FIFO is full (overrun) during input data transfer  
0: No input data overrun occurred  
Input data overrun occurred, the I_OVR bit is set when input FIFO is  
full and there is new input data coming in. This bit can be cleared by  
writing “1” to it.  
O_UND: Output data FIFO is underrun  
1: Output FIFO is empty during output data transfer  
0: No output data underrun occurred  
Output data underrun, the O_UND bit is set when output FIFO is  
empty and the output request for new data, this bit can be cleared by  
writing “1” to it.  
3.5 Interrupt Status & Control Register (BASE + 1C)  
The interrupt mode/status is set/checked through this register.  
Address: BASE + 1C  
Attribute: READ/WRITE  
Data Format:  
Byte  
Base +1C SI_TO  
Base +1D FIFOFF FIFOEF FIFORST REQ_NEG T1_T2 T0_T2 SI_T2  
7
6
5
4
3
2
1
0
SI_REQ SO_ACK T2_EN  
T1_EN T0_EN II_REQ IO_ACK  
SI_T1  
----  
----  
Base +1E ----  
Base +1F ----  
----  
----  
----  
----  
----  
----  
----  
----  
----  
----  
----  
----  
Interrupt Control:  
With the PCI-7200, interrupts can be triggered by many signal sources such as  
O_ACK, I_REQ, timer 0, timer 1, and timer 2. The following bits control the  
interrupt source:  
IO_ACK: Interrupt is triggered by O_ACK signal.  
1: O_ACK interrupt is enabled  
0: O_ACK interrupt is disabled  
II_REQ: Interrupt is triggered by I_REQ signal.  
1: I_REQ interrupt is enabled  
0: I_REQ interrupt is disabled  
24 Register Format  
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T0_EN: Interrupt is triggered by timer 0 output.  
1: Timer 0 interrupt is enabled  
0: Timer 0 interrupt is disabled  
T1_EN: Interrupt is triggered by timer 1 output.  
1: Timer 1 interrupt is enabled  
0: Timer 1 interrupt is disabled  
T2_EN: Interrupt is triggered by timer 2 output.  
1: Timer 2 interrupt is enabled  
0: Timer 2 interrupt is disabled  
Interrupt Status:  
The following bits are used to check interrupt status:  
SO_ACK: Status of O_ACK interrupt  
1: O_ACK Interrupt occurred  
0: No O_ACK interrupt  
SI_REQ: Status of I_REQ interrupt  
1: I_REQ Interrupt occurred  
0: No I_REQ Interrupt  
SI_T0: Status of timer 0 interrupt  
1: OUT0 (output of timer 0) Interrupt occurred  
0: No timer 0 Interrupt  
SI_T1: Status of timer 1 interrupt  
1: OUT1 (output of timer 1) Interrupt occurred  
0: No timer 1 Interrupt  
SI_T2: Status of timer 2 interrupt  
1: OUT2 (output of timer 2) interrupt occurred  
0: No timer 2 Interrupt  
Note: Writing “1” to the corresponding bit of the register can clear all  
interrupt statuses. In order to make the interrupt work properly, the  
interrupt service routine has to clear all the interrupt status before end  
of the ISR.  
Timer Configuration Control:  
The 8254 timer on the PCI-7200 can be configured as either timer 0 cascaded  
with timer 2 or timer 1 cascaded with timer 2. These configurations are  
controlled by the following bits:  
T0_T2: Timer 0 is cascaded with timer 2  
1: Timer 0 and timer 2 are cascaded together; output of timer 2  
connects to the clock input of timer 0.  
0: Not cascaded, the 4MHz clock is connected to the timer 0 clock  
input.  
Register Format 25  
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T1_T2: Timer 1 is cascaded with timer 2  
1: Timer 1 and timer 2 are cascaded together; output of timer 2  
connects to the clock input of timer 1.  
0: Not cascaded, the 4MHz clock is connected to the timer 1 clock  
input.  
I_REQ Polarity Selection:  
When the input sampling is controlled by the I_REQ signal only, the I_REQ  
can be programmed to be rising edge active or falling edge active.  
REQ_NEG: I_REQ trigger polarity  
1: latch input data on falling edge of I_REQ  
0: latch input data on rising edge of I_REQ  
FIFO Control and Status (cPCI-7200 only):  
The cPCI-7200 has an extra 2k samples digital input FIFO. The FIFO can be  
cleared and monitored by the following bits:  
FIFORST (Write only): Clear the on-board DI FIFO  
1: Write 1 to clear the data of the FIFO.  
0: No operation.  
FIFOEF (Read only): Empty flag of the DI FIFO  
1: DI FIFO is empty.  
0: DI FIFO is not empty.  
FIFOFF (Read only): Full flag of the DI FIFO  
1: DI FIFO is full.  
0: DI FIFO is not full.  
Note: The cPCI-7200 has 2 cascaded DI FIFOs. One is located in the PCI  
controller chip, the other one is on the PCI-7200 board. The above  
bits only control the on-board FIFO. In order to control the on-chip  
FIFO, please refer to the AMCC-5933 data book.  
26 Register Format  
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3.6 8254 Timer Registers (BASE + 0)  
The 8254 timer/counter IC occupies 4 I/O address. Users can refer to Tundra's  
or Intel's data sheet for a full description of the 8254 features. Download the  
8254 data sheet from the following web site:  
Address  
Read  
Write  
Base + 0  
Base + 4  
Base + 8  
Base + C  
Counter 0  
Counter 1  
Counter 2  
---  
Counter 0  
Counter 1  
Counter 2  
CLK Control CW0  
Register Format 27  
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4
Operation Theory  
In PCI-7200, there are four data transfer modes can be used for digital I/O  
access and control, these modes are:  
1. Direct Program Control: the digital inputs and outputs can be read/written  
and controlled by its corresponding I/O port address directly.  
2. Internal Timer Pacer Mode: the digital input and output operations are  
paced by an internal timer pacer and are transferred by bus mastering DMA.  
3. External Clock Mode: the digital input operation is clocked by external  
I_REQ strobe and transferred by bus mastering DMA.  
4. Handshaking: through REQ and ACK signals, the digital I/O can have  
simple handshaking data transfers.  
4.1 Direct Program Control  
Digital I/O operations can be controlled by I/O port BASE+10 for digital input  
and BASE+14 for digital output.  
The I/O port address BASE is assigned by system BIOS, please refer to  
Section 5 for a more detailed description.  
The digital OUT operation is:  
outport (BASE+14, 0xAAAAAAAA) // (A : 0 to F)  
The digital IN operation is:  
value = inport (BASE+10)  
// The input status is save in the  
// value variable  
Operation Theory 29  
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4.2 Timer Pacer Mode  
The digital I/O access control is clocked by timer pacer, which is generated by  
an interval programming timer/counter chip (8254). There are three timers on  
the 8254. Timer 0 is used to generate timer pacer for digital input and timer 1 is  
used for digital output. The configuration is illustrated as below.  
8254 Timer/Counter  
Timer 0  
CLK0  
Digital Input Timer Pacer  
Digital Output Timer Pacer  
GATE0  
OUT0  
“H”  
Timer 1  
Timer 2  
CLK1  
GATE1  
OUT1  
OUT2  
“H”  
4MHz Clock  
CLK2  
GATE2  
“H”  
The operation sequences are:  
1. Define the frequency (timer pacer rate)  
2. The digital input data are saved in FIFO after a timer pacer pulse is  
generated. The sampling is controlled by timer pacer.  
3. The data saved in FIFO will be transferred to main memory of the computer  
system directly and automatically. This is controlled by bus mastering DMA  
control, this function is supported by PCI controller chip.  
The operation flow is show as following:  
8254 Timer/Counter  
1
Timer 0  
To Digital Input Trigger  
CLK0  
GATE0  
OUT0  
Latch Digital Input  
2
3
PC's Main Memory  
Bus mastering  
DMA data Transfer  
Digital Input FIFO  
30 Operation Theory  
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4.3 External Clock Mode  
The digital input is clocked by external strobe, which is from Pin 19 (I_REQ) of  
CN2 (PCI-7200), Pin 24 of CN1 (cPCI-7200), or PIN 33 of CN1A (LPCI-7200S).  
The operation sequence is very similar to the Timer Pacer Trigger. The only  
difference is the clock source.  
1. The external input strobe is generated from outside device, and goes  
through the Pin 19 (I_REQ) of CN2 to latch the digital input.  
2. The digital input data is saved in FIFO after an I/O strobe signal is coming in.  
3. The data saved in input FIFO will be transferred to main memory on your  
computer system directly. This is controlled by bus mastering DMA control,  
this function is supported by PCI.  
1
To Digital Input Trigger  
Latch Digital  
Input Data  
Pin 19 of CN2  
2
3
PC's Main Memory  
Bus mastering  
DMA data Transfer  
Digital Input FIFO  
4.4 Handshaking  
The PCI-7200 also supports a handshaking digital I/O transfer mode. That is,  
after input data is ready, an I_REQ is sent from an external device, and I_ACK  
will go high to acknowledge the data already accessed.  
I_REQ & I_ACK for Digital Input  
1. Digital Input Data is ready.  
2. An I_REQ signal is generated for digital input operation.  
3. Digital input data is saved to FIFO.  
4. An I_ACK signal is generated and sent to an outside device.  
5. If the FIFO is not empty and PCI bus is not occupied, the data will be  
transferred to main memory.  
Operation Theory 31  
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Digital Input DATA  
1
2
IN_REQ  
IN_ACK  
Latch Digital Input  
or Digital Output  
3
4
PC's Main Memory  
Bus mastering  
DMA data Transfer  
Digital Input FIFO  
5
O_REQ & O_ACK for Digital Output  
1. Digital Output Data is moved from PC memory to FIFO of PCI-7200 by using  
DMA data mastering data transfer.  
2. Move output data from FIFO to digital output circuit.  
3. Output data is ready.  
4. An O_REQ signal is generated and sent to outside device.  
5. After an O_ACK is captured, steps 2-5 will be repeated.  
** If the FIFO is not full, the output data is moved form PC‘s main memory to  
FIFO automatically.  
Digital Output DATA  
4
3
O_REQ  
Move Data to  
Digital Output  
O_ACK  
5
2
PC's Main  
Memory  
Bus mastering  
Digital Output FIFO  
DMA data Transfer  
1
32 Operation Theory  
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4.5 Timing Characteristic  
1. I_REQ as input data strobe (Rising Edge Active)  
t
h
l
t
IN_ I_REQ  
cyc  
t
valid data  
D10~DI31  
valid data  
s
t tn  
th 60ns  
ts 2ns  
tI 60ns  
tn 30ns  
tCYC 5 PCI CLK Cycle  
2. I_REQ as input data strobe (Falling Edge Active)  
t
h
l
t
IN_R I_REQ  
D10~DI31  
cyc  
t
valid data  
valid data  
s
t tn  
th 60ns  
ts 2ns  
tI 60ns  
tCYC 5 PCI CLK Cycle  
tn 30ns  
Operation Theory 33  
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3. I_REQ & I_ACK Handshaking  
t5  
IN I_REQ  
IN I_ACK  
t3  
t4  
valid data  
D10~DI31  
valid data  
t1  
t2  
t1 0ns  
t2 0ns  
t5 60ns  
t4 1 PCI CLK Cycle  
t3 2 PCI CLK Cycle  
Note: I_REQ must be asserted until I_ACK asserts, I_ACK will be asserted  
until I_REQ de-asserts.  
4. O_REQ as output data strobe  
t
h
Out O_REQ  
cyc  
t
valid data  
D00~D031  
valid data  
s
t
ts 19ns  
th 2 PCI CLK Cycles Tcyc 500ns  
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5. O_REQ & O_ACK Handshaking  
t3  
OUT
O_REQ  
2
t
OUT_
O_ACK  
valid data  
valid data  
DO0~Do31  
1
t
5 PCI CLK Cycle  
1 PCI CLK Cycle  
t3  
1
19ns  
t
t2  
Note: O_ACK must be de-asserted before O_REQ asserts, O_ACK can be  
asserted any time after O_REQ asserts, O_REQ will be reasserted  
after O_ACK is asserted.  
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5
C/C++ Libraries  
This chapter describes the software library for operating the card. Only  
functions in DOS library and Windows 95 DLL are described. Please refer to  
the PCIS-DASK function reference manual, which included on the ADLINK CD,  
for the descriptions of the Windows 98/NT/2000 DLL functions.  
The function prototypes and some useful constants are defined in the header  
LIB  
INCLUDE  
directory (Windows 95). For the  
files  
directory (DOS) and  
Windows 95 DLL, the developing environment can be Visual Basic 4.0 or  
above, Visual C/C++ 4.0 or above, Borland C++ 5.0 or above, Borland Delphi  
2.x (32-bit) or above, or any Windows programming language that allows calls  
to a DLL. C/C++, VB, and Delphi files are included.  
5.1 Libraries Installation  
Please refer to the “Software Installation Guide” for the detailed information  
about how to install the software libraries for DOS, or Windows 95 DLL, or  
PCIS-DASK for Windows 98/NT/2000.  
Device drivers and DLL functions of Windows 98/NT/2000 are included in the  
PCIS-DASK. Please refer to the PCIS-DASK user’s guide and function  
reference, which included on the ADLINK CD, for detailed programming  
information.  
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5.2 Programming Guide  
5.2.1 Naming Convention  
The functions of the NuDAQ PCI cards or NuIPC CompactPCI cards’ software  
drivers use full-names to represent the functions' real meaning. The naming  
convention rules are:  
In DOS:  
_7200_Initial()  
_{hardware_model}_{action_name}. e.g.  
.
All functions in the PCI-7200 driver are named with 7200 as {hardware_model}.  
But they can be used by PCI-7200, cPCI-7200 and LPCI-7200S.  
In order to recognize the difference between DOS library and Windows 95  
W
library, a capital " " is put on the head of each function name of the Windows  
W_7200_Initial()  
95 DLL driver (e.g.  
).  
5.2.2 Data Types  
Some data types are definded in Pci_7200.h (DOS) and Acl_pci.h (Windows  
95). These data types are used by NuDAQ Cards’ library. We suggest using  
these data types. The following table shows the data type names and their  
range.  
Type Name  
U8  
I16  
U16  
I32  
U32  
Description  
8-bit ASCII character  
16-bit signed integer  
16-bit unsigned integer  
32-bit signed integer  
32-bit single-precision  
floating point  
Range  
0 to 255  
-32768 to 32767  
0 to 65535  
-2147483648 to 2147483647  
0 to 4294967295  
F32  
32-bit single-precision  
floating point  
-3.402823E38 to 3.402823E38  
F64  
64-bit double-precision  
floating point  
Boolean logic value  
-1.797683134862315E308 to  
1.797683134862315E309  
TRUE, FALSE  
Boolean  
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5.3 _7200_Initial  
@ Description  
A PCI-7200 card is initialized according to the card number.  
Because the PCI-7200 is PCI bus architecture and meets the Plug and Play  
design, the IRQ and base_address (pass-through address) are assigned  
by system BIOS directly. Every PCI-7200 card has to be initialized by this  
function before calling other functions.  
Note: Because the configuration of PCI-7200 is handled by the system, there  
are no jumpers or DMA selection on the PCI boards that need to be set  
up by the users.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_Initial (U8 card_number, U16 *base_addresss, U8  
*irq_no)  
Visual Basic (Windows 95)  
W_7200_Initial (ByVal card_number As Byte,  
base_addresss As Integer, irq_no As Byte) As Long  
C/C++ (DOS)  
int _7200_Initial (U8 card_number, U16 *base_addresss,  
U8 *irq_no)  
@ Argument  
card_number: the card number to be initialized, only four cards can be  
initialized, the card number must be CARD_1, CARD_2, CARD_3 or  
CARD_4.  
base_address: the I/O port base address of the card, it is assigned by the  
system BIOS.  
irq_no: the system will give an available interrupt number to this card  
automatically.  
@ Return Code  
ERR_NoError  
ERR_InvalidBoardNumber  
ERR_PCIBiosNotExist  
ERR_PCICardNotExist  
ERR_PCIIrqNotExist  
ERR_BaseAddressError  
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5.4 _7200_Switch_Card_No  
@ Description  
After initializing more than one PCI-7200 card, this function is used to select  
which card is currently used.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_Switch_Card_No (U8 card_number)  
Visual Basic (Windows 95)  
W_7200_Switch_Card_No (ByVal card_number As Byte) As  
Long  
C/C++ (DOS)  
int _7200_Switch_Card_No (U8 card_number)  
@ Argument  
card_number: The card number to be initialized, four cards can be  
initialized, the card number must be CARD_1, CARD_2, CARD_3, or  
CARD_4, but only one card is active.  
@ Return Code  
ERR_NoError  
ERR_InvalidBoardNoInit  
5.5 _7200_AUX_DI  
@ Description  
Read data from auxiliary digital input port of cPCI-7200 card. You can get all  
4 bits input data by using this function.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_AUX_DI (U32 *aux_di)  
Visual Basic (Windows 95)  
W_7200_DI (aux_di As Long) As Long  
C/C++ (DOS)  
int _7200_DI (U32 *aux_di)  
@ Argument  
aux_di: returns 4-bit value from auxiliary digital input port.  
@ Return Code  
ERR_NoError  
ERR_FunctionNotAvailable  
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5.6 _7200_AUX_DI_Channel  
@ Description  
Read data from the auxiliary digital input channel of cPCI-7200 card. There  
are 4 digital input channels on the cPCI-7200 auxiliary digital input port.  
When performing this function, the auxiliary digital input port is read and the  
value of the corresponding channel is returned.  
* channel means each bit of digital input port.  
@ Syntax  
Visual C++( Windows 95)  
int W_7200_AUX_DI_Channel (U8 di_ch_no, Boolean  
*aux_data)  
Visual Basic (Windows 95)  
W_7200_AUX_DI_Channel (ByVal di_ch_no As Byte,  
aux_data As Byte) As Long  
C/C++ ( DOS)  
int _7200_AUX_DI_Channel (U8 di_ch_no, Boolean  
*aux_data)  
@ Argument  
di_ch_no: the DI channel number, the value is between 0 and 3.  
aux_data: return value, either 0 or 1.  
@ Return Code  
ERR_NoError, ERR_InvalidDIChannel,ERR_FunctionNotAvailable  
5.7 _7200_AUX_DO  
@ Description  
Write data to auxiliary digital output port. There are 4 auxiliary digital outputs  
on the cPCI-7200.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_AUX_DO (U32 aux_do)  
Visual Basic (Windows 95)  
W_7200_AUX_DO (ByVal aux_do As Long) As Long  
C/C++ (DOS)  
int _7200_AUX_DO (U32 aux_do)  
@ Argument  
aux_do: value will be written to auxiliary digital output port.  
@ Return Code  
ERR_NoError  
ERR_FunctionNotAvailable  
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5.8 _7200_AUX_DO_Channel  
@ Description  
Write data to auxiliary digital output channel (bit). There are 4 auxiliary digital  
output channels on the cPCI-7200. When performing this function, the  
digital output data is written to the corresponding channel.  
* channel means each bit of digital input port  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_AUX_DO_Channel (U8 do_ch_no, Boolean aux_data)  
Visual Basic (Windows 95)  
W_7200_AUX_DO_Channel (ByVal do_ch_no As Byte, ByVal  
aux_data As Byte) As Long  
C/C++ (DOS)  
int _7200_AUX_DO_Channel (U8 do_ch_no, Boolean aux_data)  
@ Argument  
do_ch_no: the auxiliary DO channel number, the value is between 0 and 3.  
aux_data: either 0 (OFF) or 1 (ON).  
@ Return Code  
ERR_NoError  
ERR_InvalidDOChannel  
ERR_FunctionNotAvailable  
5.9 _7200_DI  
@ Description  
This function is used to read data from digital input port. There are 32-bit  
digital inputs on the PCI-7200. Use this function to get all 32 inputs data from  
_7200_DI.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DI (U32 *di_data)  
Visual Basic (Windows 95)  
W_7200_DI (di_data As Long) As Long  
C/C++ (DOS)  
int _7200_DI (U32 *di_data)  
@ Argument  
di_data: returns all 32-bit value from digital port.  
@ Return Code  
ERR_NoError  
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5.10 _7200_DI_Channel  
@ Description  
This function is used to read data from digital input channels (bit). There are  
32 digital input channels on the PCI-7200. When performs this function, the  
digital input port is read and the value of the corresponding channel is  
returned.  
* channel means each bit of digital input port.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DI_Channel (U8 di_ch_no, Boolean *di_data)  
Visual Basic (Windows 95)  
W_7200_DI_Channel (ByVal di_ch_no As Byte, di_data As Byte)  
As Long  
C/C++ (DOS)  
int _7200_DI_Channel (U8 di_ch_no, Boolean *di_data)  
@ Argument  
di_ch_no: the DI channel number, the value has to be set within 0 and 31.  
di_data: return value, either 0 or 1.  
@ Return Code  
ERR_NoError  
ERR_InvalidDIChannel  
5.11 _7200_DO  
@ Description  
This function is used to write data to the digital output port. There are 32  
digital outputs on the PCI-7200.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DO (U32 do_data)  
Visual Basic (Windows 95)  
W_7200_DO (ByVal do_data As Long) As Long  
C/C++ (DOS)  
int _7200_DO (U32 do_data)  
@ Argument  
do_data: value will be written to digital output port  
@ Return Code  
ERR_NoError  
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5.12 _7200_DO_Channel  
@ Description  
This function is used to write data to digital output channels (bit). There are  
32 digital output channels on the PCI-7200. When performing this function,  
the digital output data is written to the corresponding channel.  
* channel means each bit of digital input port  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DO_Channel (U8 do_ch_no, Boolean do_data)  
Visual Basic (Windows 95)  
W_7200_DO_Channel (ByVal do_ch_no As Byte, ByVal do_data As  
Byte) As Long  
C/C++ (DOS)  
int _7200_DO_Channel (U8 do_ch_no, Boolean do_data)  
@ Argument  
do_ch_no: the DO channel number, the value has to be set within 0 and 31.  
do_data: either 0 (OFF) or 1 (ON).  
@ Return Code  
ERR_NoError  
ERR_InvalidDOChannel  
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5.13 _7200_Alloc_DMA_Mem  
@ Description  
Contact Windows 95/98 system to allocate a block of contiguous memory  
for single-buffered DMA transfer. This function is only available in Windows  
95/98.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_Alloc_DMA_Mem (U32 *buff, U32 *handle, U32  
buf_size, U32 *actual_size)  
Visual Basic (Windows 95)  
W_7200_Alloc_DMA_Mem (buff As Long, handle As Long, ByVal  
buf_size As Long, actual_size As Long ) As Long  
@ Argument  
buff: The start address of the user buffer for DMA data transfer. This buffer  
will be attached to the DMA memory allocated by this function. When using  
this DMA memory handle as an argument of the W_7200_DI_DMA_Start  
function, DI data will be copied to this buffer. When using this DMA memory  
handle as an argument of the W_7200_DO_DMA_Start function, the data  
stored in this buffer will be the DO data.  
handle: The handle of system DMA memory returned from system. Use this  
handle in _7200_DI_DMA_Start or _7200_DO_DMA_Start.  
buf_size: Bytes to allocate. Please be careful, the unit of this parameter is  
BYTE, not SAMPLE.  
actual_size: The actual size system allocate for DMA memory. The unit is  
BYTE. If system is not able to get a block of contiguous memory of specified  
buf_size, it will allocate a block of memory as large as it can. In this case,  
this function returns ERR_SmallerDMAMemAllocated, and actual_size  
denotes the actual size of allocated memory.  
@ Return Code  
ERR_NoError  
ERR_SmallerDMAMemAllocated  
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5.14 _7200_Free_DMA_Mem  
@ Description  
Releases system DMA memory. This function is only available in Windows  
95/98.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_Free_DMA_Mem (U32 handle)  
Visual Basic (Windows 95)  
W_7200_Free_DMA_Mem (ByVal handle As Long ) As Long  
@ Argument  
handle: The handle of system DMA memory to release.  
@ Return Code  
ERR_NoError  
5.15 _7200_Alloc_DBDMA_Mem  
@ Description  
Contact Windows 95/98 system to allocate a block of contiguous memory as  
circular buffer for double-buffered DMA DI transfer. This function is only  
available in Windows 95/98 version. For double-buffered transfering, please  
refer to Section 6 “Double Buffered Mode Principle”.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_Alloc_DBDMA_Mem (U32 *buff,U32 *handle, U32  
buf_size, U32 *actual_size)  
Visual Basic (Windows 95)  
W_7200_Alloc_DBDMA_Mem (buff As Long, handle As Long, ByVal  
buf_size As Long, actual_size As Long) As Long  
@ Argument  
buff: There is a dummy buffer attached to the DMA memory this function will  
allocate. But this buffer needs to have size equal to or more than buf_size  
bytes.  
handle: The handle of system DMA memory returned from system. Use this  
handle in _7200_DI_DMA_Start.  
buf_size: Bytes to allocate. This is the half size of circular buffer in byte.  
That is, this is the size of each half buffer in byte.  
actual_size: The actual DMA memory size system allocate for each half  
buffer. If system is not able to get a block of contiguous memory of specified  
buf_size, it will allocate a block of memory as large as it can. In this case,  
this function returns ERR_SmallerDMAMemAllocated, and actual_size  
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denotes the actual size of allocated memory for each half of circular buffer.  
@ Return Code  
ERR_NoError  
ERR_SmallerDMAMemAllocated  
5.16 _7200_Free_DBDMA_Mem  
@ Description  
Releases a system’s circular buffer DMA memory. This function is only  
available in Windows 95/98. For double-buffered transfer principle, please  
refer to Section 6 “Double Buffered Mode Principle”.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_Free_DBDMA_Mem (U32 handle)  
Visual Basic (Windows 95)  
W_7200_Free_DBDMA_Mem (ByVal handle As Long ) As Long  
@ Argument  
handle: The handle of system DMA memory to release.  
@ Return Code  
ERR_NoError  
5.17 _7200_DI_DMA_Start  
@ Description  
The function will perform digital input N times with DMA data transfer by using  
one of the following four sampling modes:  
1. pacer trigger (internal timer trigger)  
2. external rising edge I_REQ  
3. external falling edge I_REQ  
4. I_REQ & I_ACK handshaking  
It will take place in the background which will not stop until the Nth input data is  
transferred or your program execute _7200_DI_DMA_Stop function to stop  
the process.  
After executing this function, it is necessary to check the status of the  
operation by using the function _7200_DI_DMA_Status. The PCI-7200 Bus  
mastering DMA is different from traditional PC style DMA. Its description is as  
follows:  
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Bus Mastering DMA mode of the PCI-7200:  
PCI bus mastering offers the highest possible speed available on the  
PCI-7200. When the function _7200_DI_DMA_Start is executed, it will enable  
PCI bus master operation. This is conceptually similar to DMA (Direct Memory  
Access) transfers in a PC but it is really PCI bus mastering. It does not use an  
8237-style DMA controller in the host computer and therefore isn't blocked in  
64k max groups. PCI-7200 bus mastering works as follows:  
1. To set up bus mastering, first do all normal PCI-7200 initialization necessary  
to control the board in status mode. This includes testing for the presence of  
the PCI BIOS, determining the base addresses, slot number, vendor and  
device ID's, I/O, or memory, space allocation, etc. Please make sure the  
PCI-7200 is plugged in a bus master slot, otherwise this function will not be  
workable.  
2. Load the PCI controller with the count and 32-bit physical address of the  
start of previously allocated destination memory, which will accept data.  
This count is the number of bytes (not long words) transferred during the bus  
master operation and can be a large number up to 64 million (2^26) bytes.  
Since PCI-7200 transfers are always long words, this equals 16 million long  
words (2^24).  
3. After the input sampling is started, the input data is stored in the FIFO of PCI  
controller. Each bus mastering data transfer continually tests if any data in  
the FIFO and then blocks transfer, the system will continuously loop until the  
conditions are satisfied again but will not exit the block transfer cycle if the  
block count is not complete. If there is momentarily no input data, the  
PCI-7200 will relinquish the bus temporarily but returns immediately when  
more input data appears. This operation continues until the whole block is  
done.  
4. This operation proceeds transparently until the PCI controller transfer byte  
count is reached. All normal PCI bus operations applied here, such as a  
receiver that cannot accept the transfers, higher priority devices requesting  
the PCI bus, etc. Remember that only one PCI initiator can have bus  
mastering at any one time. However, review the PCI priority and "fairness"  
rules. Also study the effects of the Latency Timer. Additionaly, be aware that  
the PCI priority strategy (round robin rotated, fixed priority, custom, etc.) is  
unique to each host PC and is explicitly not defined by the PCI standard.  
You must determine this priority scheme for your own PC (or replace it).  
The interrupt request from the PCI controller can be optionally set up to  
indicate that this loanword count is complete although this can also be  
determined by polling the PCI controller.  
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@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DI_DMA_Start (U8 mode, U32 count, U32 handle,  
Boolean wait_trg, U8 trg_pol, Boolean clear_fifo, Boolean  
disable_di)  
Visual Basic (Windows 95)  
W_7200_DI_DMA_Start(ByValmodeAsByte, ByValcountAsLong,  
ByVal handle As Long, ByVal wait_trg as Byte, ByVal trg_pol  
As Byte, ByVal clear_fifo As Byte, ByVal disable_di As Byte)  
As Long  
C/C++ (DOS)  
int _7200_DI_DMA_Start (U8 mode, U32 count, U32 *di_buffer,  
Boolean wait_trig, U8 trig_pol, Boolean clear_fifo, Boolean  
disable_di)  
@ Argument  
mode: Digital Input trigger modes  
DI_MODE0: Internal timer pacer (TIME 0)  
DI_MODE1: External signal I_REQ rising edge  
DI_MODE2: External signal I_REQ falling edge  
DI_MODE3: I_REQ & I_ACK handshaking  
count: For non-double-buffered DI, this parameter denotes the number of  
digital input samples to read. For double-buffered DI, it is the size of circular  
buffer (in samples, not in bytes).  
handle (Win95): The handle of system DMA memory. In Windows 95,  
before calling _7200_DI_DMA_Start, depending on using double-buffer  
mode  
or  
not,  
either  
_7200_Alloc_DMA_Mem  
or  
_7200_Alloc_DBDMA_Mem must be called to allocate a contiguous DMA  
memory and get the handle.  
di_buffer (DOS): If double buffer mode is disabled, this is the start address  
of the memory buffer to store the DI data. If double buffer mode is enabled,  
this memory buffer is actually of no use. But the buffer size still must be  
larger than the number of count (count*4 bytes). Use this buffer as transfer  
buffer in _7200_DblBufferTransfer to make use of this buffer.  
**This memory should be double-word alignment.  
wait_trig: The waiting status of trigger  
DI_NONWAITING: the input sampling will be start immediately  
DI_WAITING: the input samples waiting rising or falling edge trigger  
to start DI  
trig_pol: trigger polarity  
DI_RISING: rising edge trigger  
DI_FALLING: falling edge trigger  
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clear_fifo:  
0: retain the FIFO data  
1: clear FIFO data before perform digital input  
disable_di:  
0: digital input operation still active after DMA transfer complete  
1: disable digital input operation immediately when DMA transfer  
complete  
@ Return Code  
ERR_NoError  
ERR_BoardNoInit  
ERR_InvalidDIOMode  
ERR_InvalidDIOCnt  
ERR_NotDWordAlign  
ERR_DMATransferNotAllowed  
5.18 _7200_DI_DMA_Status  
@ Description  
Since the _7200_DI_DMA_Start function is executed in background, users  
can issue this function to check its operation status. This function only works  
when double-buffer mode is set as disable.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DI_DMA_Status (U8 *status, U32 *count)  
Visual Basic (Windows 95)  
W_7200_AD_Status (status As Byte, count As Long ) As Long  
C/C++ (DOS)  
int _7200_AD_DMA_Status (U8 *status, U32 *count)  
@ Argument  
status:status of the DMA data transfer  
0: DI_DMA_STOP: DMA is completed  
1: DI_DMA_RUN: DMA is not completed  
count: the numbers of DI data which has been transferred.  
@ Return Code  
ERR_NoError  
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5.19 _7200_DI_DMA_Stop  
@ Description  
This function is used to stop the DMA data transferring. After executing this  
function, the _7200_DI_DMA_Start function is stopped. The function returns  
the number of the data which has been transferred, no matter if the digital  
input DMA data transfer is stopped by this function or by the DMA terminal  
count, ISR.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DI_DMA_Stop (U32 * count)  
Visual Basic (Windows 95)  
W_7200_DI_DMA_Stop ( count As Long ) As Long  
C/C++ (DOS)  
int _7200_DI_DMA_Stop (U32 *count)  
@ Argument  
count: the number of DI data which has been transferred.  
@ Return Code  
ERR_NoError  
ERR_BoardNoInit  
5.20 _7200_DblBufferMode  
@ Description  
This function is used to enable or disable double buffer mode for DMA DI  
operation.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DblBufferMode (Boolean db_flag)  
Visual Basic (Windows 95)  
W_7200_DblBufferMode (ByVal db_flag As Byte) As Long  
C/C++ (DOS)  
int _7200_CheckHalfReady (Boolean db_flag)  
@ Argument  
db_flag:  
1: double buffer mode enabled  
0: double buffer mode disabled  
@ Return Code  
ERR_NoError  
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5.21 _7200_CheckHalfReady  
@ Description  
When you use _7200_DI_DMA_Start to sample digital input data and  
double buffer mode is set as enable. Users must use  
_7200_CheckHalfReady to check data ready (data half full) or not in the  
circular buffer, and using _7200_DblBufferTransfer to get data.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_CheckHalfReady (Boolean * halfReady)  
Visual Basic (Windows 95)  
W_7200_CheckHalfReady (halfReady As Byte) As Long  
C/C++ (DOS)  
int _7200_CheckHalfReady (Booelan *halfReady)  
@ Argument  
halfReady: 1 (TRUE) or 0 (FALSE)  
@ Return Code  
ERR_NoError  
5.22 _7200_DblBufferTransfer  
@ Description  
Use this function to copy the input data in the circular buffer to the transfer  
buffer. It copies half of the circular buffer, either first half or second half, to  
the transfer buffer.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DblBufferTransfer (U32 *userBuffer)  
Visual Basic (Windows 95)  
W_7200_DblBufferTransfer (userBuffer As Long) As Long  
C/C++ (DOS)  
int _7200_DblBufferTransfer (U32 *userBuffer)  
@ Argument  
userBuffer: the start address of the transfer buffer. The  
W_7200_DblBufferTransfer function copies half of the circular buffer to  
userBuffer.  
@ Return Code  
ERR_NoError, ERR_NotHalfReady  
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5.23 _7200_GetOverrunStatus  
@ Description  
When using _7200_DI_DMA_Start to convert Digital I/O data with double  
buffer mode enabled, and not using _7200_DblBufferTransfer to move  
converted data then double buffer overrun will occur. Use this function to  
check overrun count.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_GetOverrunStatus (U32 * overrunCount)  
Visual Basic (Windows 95)  
int W_7200_GetOverrunStatus (overrunCount As Long) As Long  
C/C++ (DOS)  
int _7200_GetOverrunStatus (U32 *overrunCount )  
@ Argument  
overrunCount: number of overruns.  
@ Return Code  
ERR_NoError  
5.24 _7200_DO_DMA_Start  
@ Description  
The function will perform digital output N times with DMA data transfer by  
using the following four sampling modes:  
1. Pacer trigger (internal timer trigger, TIME 1)  
2. Internal timer pacer with O_REQ enabled  
3. O_REQ & O_ACK handshaking  
It takes place in the background which will not be stop until the Nth  
conversion has been completed or the program executes the  
_7200_DO_DMA_Stop function to stop the process. After executing this  
function, it is necessary to check the status of the operation by using the  
function _7200_DO_DMA_Status.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DO_DMA_Start (U8 mode, U32 count, U32 handle,  
Boolean repeat)  
Visual Basic (Windows 95)  
W_7200_DO_DMA_Start(ByValmodeAsByte, ByValcountAsLong,  
ByVal handle As Long, ByVal repeat as Byte) As Long  
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C/C++ (DOS)  
int _7200_DO_DMA_Start (U8 mode, U32 count, U32 *do_buffer,  
Boolean repeat)  
@ Argument  
mode: Digital output trigger modes  
DO_MODE_0: Internal timer pacer (TIME 1)  
DO_MODE_1: Internal timer pacer with O_REQ enable  
DO_MODE_2: O_REQ & I_REQ handshaking  
count: the sample number of digital output data (in samples, not in bytes)  
handle (Win 95): the handle of system DMA memory. In Windows 95,  
before calling W_7200_DO_DMA_Start, W_7200_Alloc_DMA_Mem must  
be called to allocate a contiguous DMA memory and get the handle of it.  
Also W_7200_Alloc_DMA_Mem will attach a buffer to DMA memory. The  
DO data is stored in the buffer attached to this handle.  
do_buffer (DOS): the start address of the memory buffer to store the DO  
data.  
** This memory should be double-word alignment  
repeat: The digital output will be continuous or only one shot.  
CONTINUOUS:  
_7200_DO_DMA_STOP is called.  
ONE_SHOT : digital output only one-shot.  
@ Return Code  
digital  
output  
will  
be  
continuous  
until  
ERR_NoError  
ERR_InvalidDIMode  
ERR_InvalidBoardNumber  
ERR_BoardNoInit  
ERR_InvalidDIOCnt  
ERR_NotDWordAlign  
ERR_DMATransferNotAllowed  
5.25 _7200_DO_DMA_Status  
@ Description  
Since the _7200_DO_DMA_Start function is executed in background, users  
can issue the function _7200_DO_DMA_Status to check its operation  
status.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DO_DMA_Status (U8 *status, U32 * count)  
Visual Basic (Windows 95)  
W_7200_DO_Status ( status As Byte, count As Long ) As Long  
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C/C++ (DOS)  
int _7200_DO_DMA_Status (U8 *status , U32 *count)  
@ Argument  
status: status of the DMA data transfer.  
0: DO_DMA_STOP: DMA is completed  
1: DO_DMA_RUN: DMA is not completed  
count: the amount of DO data which has been transferred.  
@ Return Code  
ERR_NoError  
5.26 _7200_DO_DMA_Stop  
@ Description  
This function is used to stop the DMA DO operation. After executing this  
function, the _7200_DO_DMA_Start function is stopped. The function  
returns the number of the data which has been transferred, regardless if the  
digital output DMA data transfer is stopped by this function or by the DMA  
terminal count ISR.  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DO_DMA_Stop (U32 *count)  
Visual Basic (Windows 95)  
W_7200_DO_DMA_Stop (count As Long) As Long  
C/C++ (DOS)  
int _7200_DO_DMA_Stop (U32 *count)  
@ Argument  
count: the number of digital output data which has been transferred.  
@ Return Code  
ERR_NoError  
ERR_BoardNoInit  
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5.27 _7200_DI_Timer  
@ Description  
This function is used to set the internal timer pacer for digital input. There are  
two configurations for the internal timer pacer:  
1. Non-cascaded (One COUNTER 0 only)  
8254 Timer/Counter  
4MHz Input  
Counter 0  
CLK0  
GATE0  
OUT0  
Digital Input Trigg  
Timer pacer frequency = 4Mhz / C0  
2. Cascaded (TIME2 cascaded with COUNTER0)  
8254 Timer/Counter  
Counter 0  
CLK0  
GATE0  
OUT0  
Digital Input Trigg  
Counter 1  
CLK1  
GATE1  
OUT1  
4MHz Input  
Counter 2  
CLK2  
OUT2  
GATE2  
Timer pacer frequency = 4Mhz / (C0 * C2)  
@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DI_Timer (U16 c0, U16 c2, Boolean mode)  
Visual Basic (Windows 95)  
W_7200_DI_Timer ( ByVal c0 As Integer, ByVal c2 As Integer,  
ByVal mode As Byte ) As Long  
C/C++ (DOS)  
int _7200_DI_Timer (U16 c0, U16 c2, Boolean mode)  
@ Argument  
c0: frequency divider of Counter #0. Valid value ranges from 2 to 65535.  
c2: frequency divider of Counter #2. Valid value ranges from 2 to 65535.  
Note: Since the Integer type in Visual Basic is a signed integer. Its range is  
within -32768 and 32767. In Visual Basic, to set c0 or c2 to a value  
larger than 32767, set it as the intended value minus 65536. For  
example, to set c0 as 40000, set c0 as 40000-65536=-25536.  
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mode: TIMER_NONCASCADE or TIMER_CASCADE  
@ Return Code  
ERR_NoError  
ERR_InvalidBoardNumber  
ERR_InvalidTimerMode  
ERR_BoardNoInit  
5.28 _7200_DO_Timer  
@ Description  
This function is used to set the internal timer pacer for digital output. There  
are two configurations for the internal timer pacer:  
1. Non-cascaded (One COUNTER 0 only)  
8254 Timer/Counter  
4MHz Input  
Counter 1  
CLK0  
GATE0  
OUT0  
Digital Output Trigg  
Timer pacer frequency = 4Mhz / C1  
2. Cascaded (TIME2 cascaded with COUNTER0)  
8254 Timer/Counter  
Counter 0  
CLK0  
GATE0  
OUT0  
Counter 1  
CLK1  
GATE1  
OUT1  
Digital Input Trigg  
4MHz Input  
Counter 2  
CLK2  
OUT2  
GATE2  
Timer pacer frequency = 4Mhz / (C1 * C2)  
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@ Syntax  
Visual C++ (Windows 95)  
int W_7200_DO_Timer (U16 c1, U16 c2, Booelan mode)  
Visual Basic (Windows 95)  
W_7200_DO_Timer (ByVal c1 As Integer, ByVal c2 As Integer,  
ByVal mode As Byte) As Long  
C/C++ (DOS)  
int _7200_DO_Timer (U16 c1, U16 c2, Boolean mode)  
@ Argument  
c1 : frequency divider of Counter #1  
c2 : frequency divider of Counter #2  
Note : Since the Integer type in Visual Basic is a signed integer. Its range is  
within -32768 and 32767. In Visual Basic, to set c1 or c2 to a value  
larger than 32767, set it as the intended value minus 65536. For  
example, to set c0 as 40000, set c0 as 40000-65536=-25536.  
mode: TIMER_NONCASCADE or TIMER_CASCADE  
@ Return Code  
ERR_NoError  
ERR_InvalidBoardNumber  
ERR_InvalidTimerMode  
ERR_BoardNoInit  
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6
Double Buffer Mode Principle  
The data buffer for a double-buffered DMA DI operation is logically a circular  
buffer divided into two equal halves. The double-buffered DI begins when the  
device starts writing data into the first half of the circular buffer (Figure 6-1a).  
After device begins writing to the second half of the circular buffer, users can  
copy the data from the first half into the transfer buffer (Figure 6-1b). Users  
now can process the data in the transfer buffer according to application needs.  
After the board has filled the second half of the circular buffer, the board  
returns to the first half buffer and overwrites the old data. Users now can copy  
the second half of the circular buffer to the transfer buffer (Figure 6-1c). The  
data in the transfer buffer is again available for process. The process can be  
repeated endlessly to provide a continuous stream of data to applications  
(Figure 6-1d).  
a
b
Incoming DMA  
input data  
>
> >  
Circular Buffer  
Transfer Buffer  
c
d
>
>
>
>
> > >  
Empty Buffer  
Untransferred Data  
Transferred Data  
Figure 6-1  
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The PCI-7200 double buffer mode functions were designed according to the  
principle described above. If using _7200_DblBufferMode() to enable double  
buffer mode, _7200_DI_DMA_Start() will perform double-buffered DMA DI.  
Call _7200_CheckHalfReady() to check if data in the circular buffer is half-full  
and ready for copying to the transfer buffer. Then call  
_7200_DblBufferTransfer() to copy data from the ready half buffer to the  
transfer buffer.  
In Windows 95, W_7200_Alloc_DBDMA_Mem() is needed to allocates a  
contiguous DMA memory for the circular buffer. The buf_size argument of  
W_7200_Alloc_DBDMA_Mem() is the half size of circular buffer in byte, that is,  
the size of each half buffer in byte. The DMA memory is referenced by the  
return parameter handle. This memory is system memory; users are not  
allowed to access it directly.  
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7
Limitations  
The 12MB/sec data transfer rate can only be possibly achieved in systems  
where the PCI-7200 card is the only device using the bus, but the speed can  
not be guaranteed due to the limited FIFO depth.  
The PCI-7200 supports three input clock modes, internal clock, external clock,  
and handshaking modes. The first two modes cannot guarantee the input data  
integrity in high-speed data rate because of the limited FIFO depth and  
PCI-bus latency variation. The handshaking mode is the only mode that data  
integrity can be guaranteed. During handshaking, expect 12 MB/sec data rate  
on average, but the speed is not guaranteed.  
The guaranteed data rate with internal clock or external clock mode is  
1MB/sec on systems where PCI-7200 card is the only device using the bus.  
The largest transfer size (in bytes) PCI-7200 can perform is 64MB.  
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Warranty Policy  
Thank you for choosing ADLINK. To understand your rights and enjoy all the  
after-sales services we offer, please read the following carefully:  
1.  
Before using ADLINK’s products please read the user manual and follow  
the instructions exactly.  
2.  
3.  
When sending in damaged products for repair, please attach an RMA  
application form.  
All ADLINK products come with a two-year guarantee, repaired free of  
charge.  
The warranty period starts from the product’s shipment date from  
ADLINK’s factory.  
Peripherals and third-party products not manufactured by ADLINK  
will be covered by the original manufacturers’ warranty.  
End users requiring maintenance services should contact their local  
dealers. Local warranty conditions will depend on local dealers.  
4.  
This warranty will not cover repair costs due to:  
a. Damage caused by not following instructions.  
b. Damage caused by carelessness on the users’ part during product  
transportation.  
c. Damage caused by fire, earthquakes, floods, lightening, pollution,  
other acts of God, and/or incorrect usage of voltage transformers.  
d. Damage caused by unsuitable storage environments (i.e. high  
temperatures, high humidity, or volatile chemicals.  
e. Damage caused by leakage of battery fluid.  
f. Damage from improper repair by unauthorized technicians.  
g. Products with altered and/or damaged serial numbers.  
h. Other categories not protected under our guarantees.  
5.  
6.  
Customers are responsible for shipping costs to transport damaged  
products to our company or sales office.  
To ensure the speed and quality of product repair, please download a  
Damaged products with attached RMA forms receive priority.  
For further questions, please contact our FAE staff.  
Product Warranty/Service 63  
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