826
This is the top-level wiki page for Sensoray's model 826, a versatile analog and digital I/O system on a PCI Express board. The board has 48 digital I/Os with edge detection, sixteen 16-bit analog inputs, eight 16-bit analog outputs, six 32-bit counter channels, a watchdog timer with fail-safe controller, and a flexible signal router.
- Related pages
- 826 counters - information about 826 counter channels and incremental encoder interfacing.
- 826 DIOs - information about 826 general-purpose digital I/Os.
- 826 ADC - information about the 826 analog input system.
- Please note
- Examples are intended to function as described, but this is not guaranteed. If you discover an error, please inform the webmaster.
- In code examples, error checking has been simplified or omitted for clarity. It is recommended to always perform error checking in your production software.
- C language examples depend on header file
826api.h
, which should be included at the top of your source code like this:
#include "826api.h"
DAC
Bipolar transfer functions
In the DAC bipolar output modes (±5 V, ±10 V), the actual voltage range extends slightly beyond the negative end of the indicated output range:
DAC data | Output (V) |
---|---|
0x0000 | -5.0002 |
0x0001 | -5.0 |
0x8000 | 0.0 |
0xFFFF | +5.0 |
DAC data | Output (V) |
---|---|
0x0000 | -10.0003 |
0x0001 | -10.0 |
0x8000 | 0.0 |
0xFFFF | +10.0 |
Specifying setpoint in Volts
- Is there a way to program the analog outputs using Volts units?
The following function will set a DAC output to the specified voltage (note: the function does not check for illegal voltage values that are outside the specified range):
int SetDacOutput(uint board, uint chan, uint range, double volts) { uint setpoint; switch (range) { // conversion is based on dac output range: case S826_DAC_SPAN_0_5: setpoint = (uint)(volts * 0xFFFF / 5); break; // 0 to +5V case S826_DAC_SPAN_0_10: setpoint = (uint)(volts * 0xFFFF / 10); break; // 0 to +10V case S826_DAC_SPAN_5_5: setpoint = (uint)(volts * 0xFFFF / 10) + 0x8000; break; // -5V to +5V case S826_DAC_SPAN_10_10: setpoint = (uint)(volts * 0xFFFF / 20) + 0x8000; break; // -10V to +10V default: return S826_ERR_VALUE; // invalid range } return S826_DacDataWrite(board, chan, setpoint, 0); // program DAC output and return error code }
Many applications use a particular, fixed DAC output range, and never change it. In such cases, the range can be "hard coded" when setting the DAC output. For example, if the application uses the ±10 V range:
// Program board0, dac0 output to -7.35 V int errcode = SetDacOutput(0, 0, S826_DAC_SPAN_10_10, -7.35); // hard-coded ±10 V range
Other applications may switch ranges dynamically. In such cases, if the current DAC output range is unknown (e.g., upon warm restart), you can call S826_DacRead
first to determine the range:
// Program board0, dac0 output to +0.573 V uint range, setpoint; S826_DacRead(0, 0, &range, &setpoint, 0); // Get the active range (and DAC data, which we ignore). SetDacOutput(0, 0, range, 0.573); // Now we can set the DAC output without changing the range.
Setpoint readback
The following function will return a DAC's programmed output voltage. Note that the returned volts
may not exactly match the value specified in the last SetDacOutput
call because the output voltage can only be programmed to discrete values.
int GetDacOutput(uint board, uint chan, double *volts) { uint range, setpoint; int errcode = S826_DacRead(board, chan, &range, &setpoint, 0); // Get DAC output range & setpoint. switch (range) { // Convert binary setpoint to volts: case S826_DAC_SPAN_0_5: *volts = setpoint * ( 5.0 / 0xFFFF); break; // 0 to +5V case S826_DAC_SPAN_0_10: *volts = setpoint * (10.0 / 0xFFFF); break; // 0 to +10V case S826_DAC_SPAN_5_5: *volts = (setpoint - 0x8000) * ( 5.0 / 0x7FFF); break; // -5V to +5V case S826_DAC_SPAN_10_10: *volts = (setpoint - 0x8000) * (10.0 / 0x7FFF); break; // -10V to +10V } return errcode; }
// Example usage: Read board0, dac0 programmed output voltage. double volts; if (GetDacOutput(0, 0, &volts) == S826_ERR_OK) printf("dac0 output is set to %f volts", volts); else printf("error reading dac0");
Control DAC voltage with an incremental encoder
This example shows how to use an incremental shaft encoder to control a DAC's output voltage.
Connecting to a VFD
In motor-control applications it's common to use a DAC to generate the control voltage for a variable-frequency drive (VFD). When doing this, it's essential to properly wire the ground signals so as to avoid noise and disruptive ground loops. In particular:
- Connect the VFD analog ground to an 826 GND pin, which is the analog reference for the DAC output signal.
- Do not connect the VFD analog ground net to anything else (e.g., chassis ground).
The recommended wiring shown below uses the DAC's signal ground (826 GND) as analog reference and avoids ground loops and thus ensures accurate, problem-free motor control:
Linux Demo Sine Wave Generator counter error (-15)
The Linux sine wave generator demo may experience a timeout and exit with an error code -15 (S826_ERR_FIFOOVERFLOW). This occurs because the priority of the demo thread may be too low for the sample time. Linux is not a RTOS and the process (or interrupt) may be delayed and not complete the DAC output in the specified time.
Older version of the demo will exit when S826_ERR_FIFOOVERFLOW occurs. Later versions of the demo, however, will print an error code and continue outputting the sine wave.
In any case, if the DAC output sampling time requirements are very small and need to be precise, it is recommended to run the process at a higher priority. You may also consider using a low-latency or rt kernel.
To run the demo at a higher priority:
"nice -n 19 ./s826demo"
For Ubuntu low-latency kernel:
"sudo apt-get install linux-lowlatency linux-headers-lowlatency"
For Ubuntu rt kernel:
"sudo apt-get install linux-rt linux-headers-rt"
In extreme high performance cases, you may consider using the raw DAC write command (S826_DacRawWrite) instead of S826_DacDataWrite. You must make sure to understand the DAC ranges before doing so. This should normally not be necessary as S826_DacDataWrite is only marginally slower.
Short-circuit protection
The board's DAC devices do not have output short-circuit protection. However, each DAC automatically limits its output current to 38 mA. Consequently, a DAC can tolerate intermittent output shorts and will not be damaged as long as the DAC device does not overheat.
DAC accuracy specification
Resolution and monotonicity are both 16 bits minimum.
PARAMETER | CONDITIONS | VALUE | UNITS | ||
---|---|---|---|---|---|
MIN | TYP | MAX | |||
Integral Nonlinearity | ±2 | LSB | |||
Differential Nonlinearity | ±1 | LSB | |||
Gain Error | ±4 | ±20 | LSB | ||
Gain Temperature Coefficient | ±2 | ppm/°C | |||
Unipolar Zero-Scale Error | 5V unipolar range, 25°C 10V unipolar range, 25°C 5V unipolar range 10V unipolar range |
±80 ±100 ±140 ±150 |
±200 ±300 ±400 ±600 |
µV µV µV µV | |
V_offset Temperature Coefficient | All unipolar ranges | ±2 | µV/°C | ||
Bipolar Zero Error | All bipolar ranges | ±2 | ±12 | LSB |
Watchdog timer and fail-safe system
Activating safemode with an E-stop contact
An external emergency stop (E-stop) switch can be used to force analog and digital outputs to fail-safe states. To implement this, you must convert the E-stop signal to active-low TTL/CMOS and apply it to DIO47, so that DIO47 will be driven low when the E-stop button is pressed. The following schematic shows a robust, reliable way to do this for a 24V E-stop contact. This circuit ensures that safemode will be activated if the E-stop pushbutton is pressed, or 24VDC power is lost, or the relay coil opens.
Typically, the application program will configure the fail-safe system during initialization, before I/O operations begin. This is done by programming the analog and digital safemode states, and then "arming" the system by enabling DIO47 to trigger safemode operation. The following example illustrates this process:
// Configure and arm the fail-safe system --------------- int i; // The desired fail-safe output conditions (change as required): uint safeDioEnables[2] = {0x00FFFFFF, 0x00FFFFFF}; // Switch all DIOs to fail-safe states. uint safeDioData[2] = {0, 0}; // Safemode DIO states. uint safeAoutRange[4] = {0, 0, 0, 0}; // Safemode analog output ranges. uint safeAoutLevel[4] = {0, 0, 0, 0}; // Safemode analog output levels. // Allow modifications to fail-safe settings. S826_SafeWrenWrite(0, S826_SAFEN_SWE); // Program analog output fail-safe conditions. for (i = 0; i < S826_NUM_DAC; i++) { S826_DacRangeWrite(0, i, safeAoutRange[i], 1); S826_DacDataWrite(0, i, safeAoutLevel[i], 1); } // Program digital output fail-safe conditions. S826_SafeEnablesWrite(0, safeDioEnables); S826_DioSafeWrite(0, safeDioData, S826_BITWRITE); // Allow the E-stop switch to activate fail-safe operation. S826_SafeControlWrite(0, S826_CONFIG_XSF, S826_BITSET); // Prevent errant software from modifying fail-safe settings. S826_SafeWrenWrite(0, S826_SAFEN_SWD);
In many cases the application program must be alerted when the E-stop pushbutton is pressed, so that it can execute relevant tasks (e.g., record the event to an error log). The following example shows how to detect and handle an E-stop event.
// Detect and handle an E-stop pushbutton press ------------ WaitForDioFallingEdge(0, 47); // Wait for DIO47 falling edge. printf("E-stop pushbutton was pressed!");
Activating safemode with the watchdog
In many control applications, the analog and digital outputs must automatically switch to safe states if software fails to execute normally. This can be implemented by using watchdog Timer0 to activate safemode. To set this up, configure the watchdog and safemode systems during initialization (before I/O operations begin):
#define WD_MILLISECONDS 100 // Watchdog Timer0 will timeout if unkicked for this long wdtiming[] = {WD_MILLISECONDS * 50000, 1, 1, 0, 0}; S826_SafeWrenWrite(0, S826_SAFEN_SWE); // Write-enable watchdog/safemode settings. S826_WatchdogConfigWrite(0, 0x10, wdtiming); // Set t0 interval; t0 triggers safemode. // TODO: Program safemode states S826_WatchdogEnableWrite(0, 1); // Start the watchdog running. S826_SafeWrenWrite(0, S826_SAFEN_SWD); // Write-protect watchdog/safemode settings.
The above code starts the watchdog timer, so the application program must now regularly "kick" the watchdog to prevent a timeout. This is typically done by periodically executing a kick algorithm. The kick algorithm may be simple or complex, depending on the number of running threads and other factors. The simplest algorithm will simply kick the watchdog, unconditionally:
CreateTimer(0, 0, 100000); // Execute this loop every 100 milliseconds: while (1) { S826_WatchdogKick(0, 0x5A55AA5A); // Unconditionally kick the watchdog. WaitForTimer(0, 0); }
Here's a slightly more complex version that monitors the states of two other threads (threadA and threadB). When each monitored thread completes its task, it stores a special value in a reserved memory location. The special values, when OR'ed together, form the value required for a watchdog kick.
int a_kick; // ThreadA stores 0x5A550000 here when it completes. int b_kick; // ThreadB stores 0x0000AA5A here when it completes. CreateTimer(0, 0, 100000); // Execute this loop every 100 milliseconds: while (1) { S826_WatchdogKick(0, a_kick | b_kick); // Kick watchdog if both threads completed. a_kick = b_kick = 0; // Reset completion status. WaitForTimer(0, 0); }
When watchdog timer0 times out, it may be necessary to notify "system health" monitoring software so it can take appropriate corrective action. This is easily done, as shown in the following code:
if (S826_WatchdogEventWait(0, INFINITE_WAIT) == S826_ERR_OK) { // Watchdog timer0 timed out, so take appropriate corrective action }
Output watchdog on a DIO
The outputs from watchdog timer1 and timer2 can be routed to select DIOs. As explained in the API manual (see S826_DioOutputSourceWrite
), timer1 can be routed to DIOs 7, 15, 23, 31, 39 and 47, and timer2 can be routed to DIOs 6, 14, 22, 30, 38 and 46.
The following code will route the output of timer1 to dio7 so that dio7 will be turned on (driven low, to 0 V) when timer1 times out. As always, timer0 is used to time the kicks. Timer1 is assigned a minimum delay (DELAY1=1) so that it will timeout (and thereby activate dio7) one clock (20 ns) after timer0 times out.
#define WD_MILLISECONDS 100 // Watchdog Timer0 will timeout if unkicked for this long wdtiming[] = {WD_MILLISECONDS * 50000, 1, 1, 0, 0}; // timing parameters uint routing[] = {1 << 7, 0}; // mask for dio7 S826_SafeWrenWrite(0, S826_SAFEN_SWE); // Write-enable protected settings. S826_WatchdogConfigWrite(0, // Configure watchdog: S826_WD_NIE, // connect timer1 to NMI net wdtiming); // set timer0 & timer1 intervals S826_DioOutputSourceWrite(0, routing); // Route NMI net to dio7. S826_WatchdogEnableWrite(0, 1); // Start the watchdog (AND START KICKING!) S826_SafeWrenWrite(0, S826_SAFEN_SWD); // Write-disable protected settings.
Turning off the relay
After the watchdog has activated the Reset Out relay, the application program can deactivate the relay by calling S826_WatchdogEnableWrite()
with enable=0
, as shown below:
S826_WatchdogEnableWrite(0, 0); // Turn off relay on board0.
Default safemode states
- In safemode, will all outputs default to power-on/reset conditions if safemode data registers have not been programmed?
Yes, because upon power-up or reset, all safemode data registers are initialized to match their runmode counterparts: DIO outputs are initialized to '0' (i.e., outputs will be pulled up to +5V) and analog outputs are initialized to 0V using the 0 to +5V output range.
Programming safemode states
It's recommended to program the safemode data registers even if you will be using default values. This will serve to document fail-safe operation in your code and enable you to easily change safemode states if you need to. The following example shows how to do this for board number 0:
// Program fail-safe states for all analog and digital outputs -------------- int aout; // analog output channel number uint SafeDio[] = {0, 0}; // fail-safe DIO states S826_SafeWrenWrite(0, S826_SAFEN_SWE); // Write-enable safemode data registers. S826_DioSafeWrite(0, SafeDio, S826_BITWRITE); // Program safemode DIO states. for (aout = 0; aout < S826_NUM_DAC; aout++) { // Program safemode analog output condition: S826_DacRangeWrite(0, aout, S826_DAC_SPAN_0_5, 1); // output range S826_DacDataWrite(0, aout, 0, 1); // output voltage } S826_SafeWrenWrite(0, S826_SAFEN_SWD); // Protect safemode data registers.
P2 mating connector
These connectors (or equivalents) will mate to the board's three-pin Watchdog Reset Out header (P2):
- Molex 22-01-2037 (ramp only)
- Molex 22-01-3037 (ramp + alignment ribs)
Timestamp generator
The timestamp generator is a high-resolution "clock" based on a free-running 32-bit counter. The counter increments every microsecond and overflows (to zero, without notification) every 232 µs (approximately 71.6 minutes). It is a binary counter and consequently does not keep track of the date or time-of-day.
The generator's current time is automatically appended to every counter snapshot and every ADC sample so that application programs can know (to within 1 µs) when each sample was acquired. It is particularly useful for precisely measuring the elapsed time between hardware events. Calculation of elapsed time is easy (a single subtraction) as long as the time doesn't exceed 71.6 minutes. It can be used in a variety of ways, including measuring speed and capturing serial data.
If desired, an application program can also directly read the current time as shown below:
// Read the timestamp generator's current time. uint CurrentTimestamp(uint board) { uint t; S826_TimestampRead(board, &t); return t; }
The following example shows a simple application of direct timestamp reads:
// Example: Use board0 to measure system Sleep() time. uint t1, t0 = CurrentTimestamp(0); // Get start time. Sleep(100); // Sleep approximately 100 ms. t1 = CurrentTimestamp(0); // Get end time. printf("Slept %d µs", t1 - t0); // Display actual sleep time.
Board ID
The "BOARD NUM" switches (at top edge of board near mounting bracket) assign the board ID used by software. The ID is binary coded on the four switches and can be programmed to any value from 0 (default) to 15. A board's ID determines the corresponding bit that will be set to '1' in the value returned by S826_SystemOpen
. If you have a single 826 board, the return value will be (2^ID)
. If you have multiple boards, the return value is the sum of (2^ID)
for each board. You can enter the return value here to quickly determine its meaning.
- Examples
- You have one board with ID set to 0, so the value returned by
S826_SystemOpen
will be(2^0) = 1
. - You have two boards with IDs set to 1 and 4, so the value returned by
S826_SystemOpen
will be(2^1)+(2^4) = 2+16 = 18
.
This code snippet will tell you the meaning of the value returned by S826_SystemOpen
:
int id, flags = S826_SystemOpen(); if (flags < 0) printf("S826_SystemOpen returned error code %d", flags); else if (flags == 0) printf("No boards were detected"); else { printf("Boards were detected with these IDs:"); for (id = 0; id < 16; id++) { if (flags & (1 << id)) printf(" %d", id); } }
Hardware version
Reading the PWB revision
The circuit board revision (PWB rev) is visible on the solder-side of the 826 board (opposite the mounting bracket, on the bottom corner). S826_VersionRead
returns the PWB rev as a numeric value with decimal range [0:31], which corresponds to a text string in the standard ASME version letter sequence. The following code shows how to convert this 32-bit value to the alphabetic revision code seen on the board:
// Read and display version info from board 0 // Extract major_version, minor_version and build_number from a 32-bit version number: #define VER_FIELDS(N) ((N) >> 24) & 0xFF, ((N) >> 16) & 0xFF, (N) & 0xFFFF const char *revchar[] = { // ASME revision sequence "A", "B", "C", "D", "E", "F", "G", "H", "J", "K", "L", "M", "N", "P", "R", "T", "U", "V", "W", "Y", "AA", "AB", "AC", "AD", "AE", "AF", "AG", "AH", "AJ", "AK", "AL", "AM" }; uint api, drv, bd, fpga; int errcode = S826_VersionRead(0, &api, &drv, &bd, &fpga); // Read version info. if (errcode == S826_ERR_OK) { // If no errors then display info: printf("API version = %d.%d.%d\n", VER_FIELDS(api)); // API major.minor.build printf("Driver version = %d.%d.%d\n", VER_FIELDS(drv)); // DRVR major.minor.build printf("FPGA version = %d.%d.%d\n", VER_FIELDS(fpga)); // FPGA major.minor.build printf("PWB revision = Rev %s\n", revchar[bd & 31]); // PWB rev as seen on circuit board } else printf(" S826_VersionRead returned error code %d", errcode);
Rev C changes
Sensoray has developed Revision C of the 826 circuit board. This change was necessary due to the impending EOL (end-of-life) of a critical component. Specifically, the critical component (PCI Express interface chip) and FPGA were removed and replaced by a new FPGA, which absorbed the functions of the two removed components.
Applications and developers are not affected by this change
The Rev C board is fully compatible with Rev B boards and applications:
- Mechanical attributes are unchanged, including board dimensions and placements of connectors, switches, indicator LEDs, and hold-down bracket.
- Connector pinouts, electrical and timing specifications are unchanged.
- Rev C is 100% software compatible with Rev B on all software layers: application, API and driver (including user-developed drivers and APIs for RTOS, etc.).
Rev B and Rev C boards can be used interchangeably in new and existing applications. From an application's perspective, the only detectable differences between Rev B and Rev C boards are the version numbers returned by the API function S826_VersionRead():
- S826_VersionRead() will report the PWB version as Rev B or Rev C as appropriate for the board's hardware version.
- S826_VersionRead() will report FPGA version 0.0.70 or higher for Rev C boards, or version 0.0.69 or lower for Rev B boards.
Connector pinouts
The following drawings show the pinouts of the board's header connectors as viewed from the top (component) side of the circuit board:
Software
C examples
A variety of C programming examples have been collected together in a common source file to illustrate how to program resources on the 826.
VB.NET demo
To help you jump-start your project, we offer the VB.NET demo for model 826. This demo program provides a pre-built Windows executable with a GUI for nearly every hardware resource on the board. All source files are provided, along with a VisualStudio project.
Programming in C#
Each 826 SDK includes a C# demo application. These demos show how to call API functions from C#, and can serve as a useful starting point for a custom application.
Linux demo
In the Linux SDK, a C# GUI demo is available which uses Linux mono. To get the required libraries on Ubuntu, type:
"sudo apt-get install mono-complete"
For a C# development environment, type:
"sudo apt-get install monodevelop"
Pointer arguments
Many of the API functions have pointer arguments. This is no problem for C#, which allows you to pass function arguments by reference. To see how this is done, consider the S826_AdcEnableRead
function:
The C prototype is:
int S826_AdcEnableRead(unsigned int board, unsigned int *enable);
So in C# you should declare the function this way:
[DllImport("s826.dll", CallingConvention = CallingConvention.StdCall)] static extern Int32 S826_AdcEnableRead(UInt32 board, ref UInt32 enable);
Now you can call the function this way:
Uint32 isEnabled; Int32 errcode = S826_AdcEnableRead(0, ref isEnabled);
Labview
Before running an 826 virtual instrument (VI) under Labview, make sure you install the latest versions of the 826 DLL (s826.dll) and device driver (both are contained in the 826 SDK, which you can obtain from the Downloads tab of the 826 product page).
Each VI is a basically a wrapper for a DLL function and consequently the VIs are dependent on the DLL, which in turn depends on the driver. Board hardware and firmware version numbers will be automatically read from the 826 board by software when all dependencies are satisfied -- it is not necessary to manually enter any board selection information except the board number, which is specified by the board's switch settings (factory default is board number 0).
The VIs are not independently documented, but since each VI wraps a DLL function, the DLL documentation effectively explains the function of each associated VI. The DLL documentation can be found in the 826 product manual (download from the 826 product page Documentation tab).
The VIs may be installed under Labview's instrument library (e.g., "instr.lib\Sensoray 826") or elsewhere if desired. Refer to Labview documentation for information about paths and other relevant topics.
Matlab
To use an 826 with Matlab you must first install the latest 64-bit versions of the 826 API (s826.dll) and device driver; these are both part of the 826 SDK, which you can obtain from the Downloads tab of the 826 product page. You may then use Matlab's loadlibrary()
function to enable access to the API, and calllib()
to call API functions. The API functions are described in the 826 product manual, which can be found on the 826 product page Documentation tab. The following example illustrates how this works.
Note: Matlab cannot execute loadlibrary()
unless a compatible C compiler is installed on your computer. If Matlab complains about an "Error using loadlibrary" because "No supported compiler was found" then you must download and install one of the Matlab-compatible compilers (e.g., MinGW-w64) to resolve this issue. Please consult Mathworks for a list of compatible compilers.
% Simple Matlab example: turn on general-purpose digital I/O 2 *************************** % Change these values as required: hdrPath = 'C:\Sensoray\826api.h'; % Path to API header dllPath = 'C:\Windows\System32\s826.dll'; % Path to API executable board = 0; % Use 826 board #0 (i.e., board w/ID switches set to 0) loadlibrary(dllPath, hdrPath, 'alias', 's826'); % Load the API. boardflags = calllib('s826', 'S826_SystemOpen'); % Open API and detect all boards. if (boardflags < 0) % If API failed to open disp("S826_SystemOpen error"); % Report error. else % Else if (boardflags ~= bitshift(1, board)) % If board #0 was not detected disp("Failed to detect 826 board"); % Report error (check board's switch settings). else % Else ... buf = libpointer('uint32Ptr', [6 0]); % Allocate buffer for DIO state data. errcode = calllib('s826', ... % Turn on DIO1 and DIO2. 'S826_DioOutputWrite', board, buf, 0); clear buf; % Free buffer. if (errcode ~= S826_ERR_OK) disp('DIO write problem') % Report error if DIO write failed. end end errcode = calllib('s826', 'S826_SystemClose'); % Close API. end unloadlibrary s826; % Unload the API.
Matlab SDK
Sensoray offers an open-source software development kit for Matlab programmers, which you can obtain from the Downloads tab of the 826 product page. The Matlab SDK includes two files:
-
s826.m
is a class that defines useful constants and provides wrappers for all 826 API functions. Include this file in any project that interacts with model 826 boards. -
s826_demo.m
is a short program that demonstrates how to use the s826 class.
ROS (Robot Operating System)
Sensoray SDKs do not include a ROS package, but the Linux SDK has everything needed to create one. The simplest way to use ROS with model 826 is to install the Linux 826 device driver and API (shared library), and then call the API functions as shown in the following example. Note that this example is coded in C++, but you can easily call the API functions from Python or any other language.
/////////////////////////////////////////////////////////////////////////////////////////////////////////// // Simple ROS (Robot Operating System) example for Sensoray 826 PCI Express analog/digital IO board. // Function: Publishes 16 analog inputs 10 times per second /////////////////////////////////////////////////////////////////////////////////////////////////////////// #define X826(func) if ((errcode = (func)) != S826_ERR_OK) { printf("\nERROR: %d\n", errcode); return; } // Call function and process error int PublishAINChannels() { int adcbuf[16]; // adc data buffer uint slotlist; // timeslot flags uint slot; // timeslot index (and ain channel number) uint board = 0; // board ID int errcode; // Initialize data array for publisher std_msgs::Int16MultiArray data_array; data_array.layout.dim.push_back(std_msgs::MultiArrayDimension()); data_array.layout.dim[0].label = "board-" + to_string(board) + " AIN"; data_array.layout.dim[0].size = 16; data_array.layout.dim[0].stride = 1; data_array.layout.data_offset = 0; // Configure adc and start it running. for (slot = 0; slot < 16, slot++ ) // Configure slots: chan = slot number, settle time = 20 us, range = +/-10 V X826(S826_AdcSlotConfigWrite(board, slot, slot, 20, S826_ADC_GAIN_1)); X826(S826_AdcSlotlistWrite(board, 0xFFFF, S826_BITWRITE)); // Enable all slots. X826(S826_AdcTrigModeWrite(board, 0)); // Select continuous trigger mode. X826(S826_AdcEnableWrite(board, 1)); // Start conversions. ROS_INFO("\tPublishing AIN Channels"); ros::Rate loop_rate(10); while (ros::ok()) { // Wait for next publish time. This is at top of loop so first ADC burst will complete before we try to read the data. // Otherwise we might get bogus data the first time through the loop. loop_rate.sleep(); // Fetch ADC data data_array.data.clear(); slotlist = 0xFFFF; // from all 16 slots errcode = S826_AdcRead(board, adcbuf, NULL, &slotlist, 0); // Handle errors if ((errcode != S826_ERR_OK) && (errcode != S826_ERR_MISSEDTRIG)) { // this app doesn't care about adc missed triggers printf("\nERROR: %d\n", errcode); break; } // Publish ADC data for (slot = 0; slot < 16; slot++) { // Publishing raw data (16-bit signed int). Convert to +/-10V by multiplying by 10/32768. // example: cout << (double)(data_array.data[i] * 10) / 32768 << endl; data_array.data.push_back((short)(adcbuf[slot] & 0xFFFF)); } analog_input_pub.publish(data_array); } S826_AdcEnableWrite(board, 0); // Halt conversions. return errcode; }
Resources for custom driver development
- I want to develop my own device driver for the 826. Does Sensoray offer any resources for custom driver development?
Yes, we provide these resources free of charge:
- Linux Software Development Kit (SDK) - Includes source code for the 826 driver, hardware abstraction layer (HAL) and API middleware, comprising a complete 826 software stack for Linux. The generic API is operating system independent and thread-safe, which makes this SDK a great starting point for porting to any operating system. The stack has been carefully designed for reliable operation in and for easy porting to real-time operating systems. The SDK can be found on the Downloads tab of the 826 product page.
- Model 826 Technical Manual - This comprehensive manual explains the API and 826 hardware in detail (download from the Documentation tab of the 826 product page).
- Register Map - A map of the board's hardware registers is available here. The registers are accessed through PCI BAR 2. Registers appear in both banked and flat address spaces. The banked space is only required for rev 0 boards; you should use the flat space exclusively if you have a later rev, as this will yield superior performance.
Software updates
1. Windows 3.3.4
- C# demo application added to SDK. Error checking for invalid modes to S826_CounterModeWrite.
2. Linux 3.3.5
- C# GUI demo available, using Linux mono.
Windows
Custom installation and re-distribution
Sensoray's installer uses the Nullsoft Scriptable Install System (NSIS). It is created from a .NSI script. The core API is installed as follows in NSI script code:
Section "Core API" SectionIn RO ${If} ${RunningX64} SetOutPath "$WINDIR\system32"; !insertmacro DisableX64FSRedirection File "..\mid-826\code\Release64\s826.dll"; !insertmacro EnableX64FSRedirection SetOutPath "$WINDIR\SysWOW64"; File "..\mid-826\code\Release\s826.dll"; ${Else} SetOutPath "$WINDIR\system32"; File "..\mid-826\code\Release\s826.dll"; ${EndIf} SectionEnd
The drivers are installed via dpinst.exe in the NSI script as follows:
Section "Drivers" SectionIn RO CreateDirectory "$INSTDIR\driver\x64"; SetOutPath "$INSTDIR\driver\x64"; File "..\cd\driver\x64\dpinst.exe"; File "..\cd\driver\x64\s826.cat"; File "..\cd\driver\x64\s826.inf"; File "..\cd\driver\x64\s826.sys"; File "..\cd\driver\x64\s826filter.cat"; File "..\cd\driver\x64\s826filter.inf"; File "..\cd\driver\x64\s826filter.sys"; File "..\cd\driver\x64\WdfCoInstaller01009.dll"; CreateDirectory "$INSTDIR\driver\x32"; SetOutPath "$INSTDIR\driver\x32"; File "..\cd\driver\x32\dpinst.exe"; File "..\cd\driver\x32\s826.cat"; File "..\cd\driver\x32\s826.inf"; File "..\cd\driver\x32\s826.sys"; File "..\cd\driver\x32\s826filter.cat"; File "..\cd\driver\x32\s826filter.inf"; File "..\cd\driver\x32\s826filter.sys"; File "..\cd\driver\x32\WdfCoInstaller01009.dll"; MessageBox MB_OK "Driver installation dialog will pop-up. Follow the prompts and click Finish when done" ${If} ${RunningX64} ExecWait '"$INSTDIR\driver\x64\dpinst.exe" /f' ${Else} ExecWait '"$INSTDIR\driver\x32\dpinst.exe" /f' ${EndIf} NoInstallDriver: SectionEnd
- What other libraries does the installer install as part of the Core API?
The 826 is compiled with Microsoft Visual Studio C++ 2008. The re-distributables for C++ must be installed. The installer installs this library silently running the command:
"vcredist_x86.exe /q"
and the following additional command on 64-bit systems:
"vcredist_x64.exe /q"
These re-distributables are available from Microsoft for x64 and x86.
- Are any other libraries required? I installed the libraries above, but the demo doesn't work with my custom installer?
The demo is written using .NET libraries (version 3.5). These are also available from Microsoft here. The executable can be silently installed using this command:
"dotnetfx35setup.exe /qb"
- Could I obtain the full 826 NSI script as a template for creating my own installer?
Yes, the full script is available here.
Silent install
- I want to run the installer silently. Do you have any way to do this?
There are many options. For re-distribution, you may create your own installation package. Also, starting with version 3.3.9, there are additional command line options to quiet the setup.exe installer from command line or batch file. These options are described below.
- What are the options for silent install?
The basic silent install is invoked by running the following command from command line or batch script:
"setup.exe /S"
Please note that the /S is case sensitive and must be upper case.
- I've pre-installed the drivers and don't want to re-install them during the installation? Is there a command for that?
"setup.exe /S /no_driver=1"
- Is there an additional command to not install the demo programs?
Yes, in version 3.3.9, the following command will install the required DLLs and system libraries, but no drivers or demo programs.
"setup.exe /S /no_driver=1 /no_demos=1"
- I want to install the drivers silently, but there is always a pop-up to verify.
Unfortunately, there is no way around this. Windows requires confirmation from the user for driver install, even if the driver is signed.
- I'm running the setup silently, but it pops up a dialog to confirm if I want to make changes to the PC (User Account Control). How do I prevent this?
Windows controls this through User Access Control. If running the setup from a standard windows console, the Windows User Account Control (UAC) will pop-up. This cannot be by-passed by Sensoray because the installer installs files to system directories.
One work-around is to launch the setup in an Windows Command Prompt Window started in administrator mode (right-click and select "Run As Administrator"). Another approach is to launch the setup as a user with administrator privileges. User access control may also be disabled, but we do not recommend this for security reasons.
Link error
- I'm using VisualStudio (VS) on a 64-bit machine to build a 32-bit application for the 826. VS reports that linking failed because it can't open s826.lib. What could be the problem?
You should use the 32-bit DLL (and its associated LIB) because you are building a 32-bit application (x86). Use the 64-bit version only when building 64-bit apps (x64). To avoid confusion, you can copy the 32-bit DLL and its associated LIB file from the install directory to your project directory, then point the linker to it there. Make sure to also point the debugger to the 32-bit DLL by setting its working directory.
Note: You will always use the 64-bit driver on a 64-bit OS regardless of 32/64-bit application type, but you don't need to select this as it is automatically installed by the SDK installer.
Windows 10 IoT
Sensoray has created a Universal driver (UD) for the 826 under OneCoreUAP-based editions of Windows. It is similar to the standard driver, but compiled as Universal. This driver is in our SDK zip file under the "driver/sensoray_826_universal_driver" directory. Installation may be dependent on the specific Windows version. The inf is Windows Universal compatible. Sensoray does not currently have a demonstration Universal Windows App for the 826, but the .NET demo app may be portable.
Linux
Linux versions
- Do you recommend specific Linux distributions for use with the 826?
We no longer support the obsolete kernel 2.4, but otherwise have no specific recommendation as it depends on the application (e.g., it might be desirable to use a low-latency kernel). The 826 driver is compatible to kernel versions 2.6 and higher.
Build errors
On some Linux distributions, "sudo make install
" may issue messages like these:
-
modprobe: ERROR: could not insert 's826': Required key not available
-
SSL error:02001002:system library:fopen:No such file or directory: ../crypto/bio/bss_file.c
In such cases, it's likely that the 826 driver successfully installed and you are simply seeing a warning. You can confirm this by trying "sudo modprobe s826
" and the 826 demo application.
Remote access
- Is there any way to use an 826 with a laptop?
Not directly, because laptops don't provide PCI Express slots. However, it is possible to locate the 826 in a host computer and, with appropriate software, remotely access its interfaces from a laptop (e.g., via Ethernet or USB); in fact, several 826 users have reported that they do exactly that.
When designing such a system, it's important to consider that Ethernet and USB are not capable of real-time communication with register-based measurement and control hardware. Consequently, depending on the application, this may require the host to offload time-critical I/O functions from the laptop, such as interrupt handling, FIFO processing, and low-level register I/O sequences, in order to achieve real-time performance.
Environmental specifications
Parameter | Value |
---|---|
Pressure, operating | 650 to 1010 hPa |
Humidity, operating | 20% to 80% RH, non-condensing |
Migrating from model 626
Differences between models 626 and 826
When upgrading your PCI system to PCIe, we recommend model 826 as a replacement for model 626. The following table compares the interfaces on the two boards:
Interface | 626 | 826 |
---|---|---|
System bus | PCI | PCI Express |
Counters | 6 channels 24-bit resolution 24-bit sample latch |
6 channels 32-bit resolution sample FIFO (16-deep) with 32-bit timestamps |
GPIOs | 48 channels 40 w/edge detection (1 Msps) no debounce not fail-safe |
48 channels 48 w/edge detection (50 Msps) debounce filter fail-safe outputs |
Analog out | 4 channels 14-bit resolution 20 Ksps not fail-safe |
8 channels 16-bit resolution 900 Ksps fail-safe outputs |
Analog in | 16 channels 16-bit resolution 15 Ksps |
16 channels 16-bit resolution 300 Ksps |
Watchdog timer | Single stage 4 shunt-selectable intervals |
3 timer stages software programmable intervals |
Fail-safe controller | None | Integrated |
Connector pinout differences
- Do models 826 and 626 have the same connectors and pinouts?
Both boards use identical connectors. The pinouts of the digital and counter connectors are identical, but analog connector pinouts differ slightly because the 826 has four additional analog outputs. The analog pinouts are identical except for pins 41, 43, 45 and 47, which convey DAC channel 4-7 outputs on the 826 (vs. remote sense inputs on the 626).
Using 626 cables with the 826
- I have a 7505TDIN breakout board and 7501C1 (50-pin cable) for the 626. Can I use these with the 826?
The 7505TDIN and 7501C are both compatible with the 826. However, we recommend using an 826C2 cable instead of the 7501C because it has a low profile header at one end that results in a denser cable stackup. That said, the 7501C cable can be used if it doesn't cause mechanical interference in your system.
See also
- GPIO interfacing - design tips for DIO circuits