AxsunOCTCapture 3.8.2
Captures and buffers streamed imaged data from the Axsun Ethernet/PCIe DAQ and displays or retrieves images to a client application on request.
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The AxsunOCTCapture library and API captures a high-bandwidth image stream from an Axsun Ethernet/PCIe DAQ board and provides additional image management and display functionality to custom client applications.
The primary functions of the AxsunOCTCapture library (or simply the "Capture library") are:
Some secondary functions of the Capture library include:
AxsunOCTCapture is written in C++ and exposes a Standard C interface to insure maximum portability for client application integration. See relevant Axsun Knowledge Base pages at https://docs.axsun.com/axsun-technologies-knowledge-base/guides/integrated-engine/installing-software#image-capture-tool-and-axsunoctcapture for installation instructions of AxsunOCTCapture dependencies.
Naming Conventions: C function names in this library begin with "ax". Enumerated types begin with "Ax". Struct type definitions end with "_t".
Error Handling: Functions usually return an error code as defined in the AxErr enum. Check that returned values indicate NO_AxERROR after function calls. Sample code shown below and in the linked examples eschews robust error handling in favor of readability.
Thread Safety: Confine AxsunOCTCapture library calls to a single thread or insure serialization at the client application level. Calling AxsunOCTCapture functions concurrently could result in undefined behavior. axGetImageInfo(), axRequestImage(), and axGetStatus() are safe to call from within the New Image event callback.
Project Configuration: Include the AxsunOCTCapture.h header file in your project and link to AxsunOCTCapture.dll (or libaxsunoctcapture.so or libAxsunOCTCapture.dylib on Linux or macOS). On Windows, you must also link to the include library AxsunOCTCapture.lib. Insure that your include search path is correctly pointing to the location of AxsunOCTCapture.h and AxsunCommonEnums.h. To get started, copy the .c or .cpp source code from one of the linked examples into your project and modify as appropriate.
Follow these basic steps to use the capture library in your C-based client application. C and C++ usage examples are provided in AxsunOCTCapture_example.c , AxsunOCTCapture_example_NewImageCallback.cpp , and AxsunOCTCapture_example_LoadExport.cpp. The Capture library uses an "opaque pointer" design pattern to manage the creation, functionality, and destruction of a Capture session (https://en.wikipedia.org/wiki/Opaque_pointer).
1) Open a new AxsunOCTCapture session using axStartSession() and select a capture interface using axSelectInterface():
AOCHandle session = NULL; // declare a handle (opaque pointer) for the session AxErr returnValue = axStartSession(&session, 100); // the "100" argument indicates a desired Main Image Buffer size of 100 MB returnValue = axSelectInterface(session, GIGABIT_ETHERNET); // a session supports either the PCI_EXPRESS or the GIGABIT_ETHERNET interface.
2) Call functions from the AxsunOCTCapture library as desired within your application workflow, using the generated session handle as the first argument. To get status information about the Main Image Buffer, use the axGetStatus() function. First declare variables and then send pointers to those variables with the "address-of" operator (&) as the arguments to axGetStatus():
uint32_t imaging, last_packet, last_frame, last_image, dropped_packets, frames_since_sync; // declare variables returnValue = axGetStatus( session, // the session handle created using axStartSession() &imaging, // is DAQ in Live Imaging, Burst Record, or Idle/Off state? &last_packet, // the number of the last packet enqueued in the buffer &last_frame, // the number of the last frame enqueued in the buffer &last_image, // the number of the last image enqueued in the buffer &dropped_packets, // the number of packets dropped since the last Imaging off/on cycle &frames_since_sync); // the number of frames (256 A-lines) enqueued since the last Image_sync trigger
This paradigm is used for getting information about images in the Main Image Buffer using axGetImageInfo(). This paradigm is used to retrieve or display an image in the Main Image Buffer using axRequestImage(). The client application can retreive or display images from the Main Image Buffer using a polling-based approach as shown in AxsunOCTCapture_example_LoadExport.cpp and AxsunOCTCapture_example.c, or using a callback-based approach as shown in AxsunOCTCapture_example_NewImageCallback.cpp.
3) Call axStopSession() to release resources prior to quitting:
returnValue = axStopSession(session);
Follow these basic steps to use the PCIe control functions in your C-based client application. C and C++ usage examples are provided in AxsunOCTCapture_example.c and AxsunOCTCapture_example_NewImageCallback.cpp. If you connect to the DAQ via the Ethernet interface, use the AxsunOCTControl library or AxsunOCTControl_LW library for this functionality.
1) Open a Capture session as shown above but select the PCI_EXPRESS interface using the axSelectInterface() function:
returnValue = axSelectInterface(session, PCI_EXPRESS);
2) Use the axImagingCntrlPCIe() function to select among DAQ imaging modes: Image-On (Live), Image-On (Burst Record), Image-Off (Idle):
returnValue = axImagingCntrlPCIe(session, -1); // Live mode returnValue = axImagingCntrlPCIe(session, 1000); // Burst Record mode (1000 images) returnValue = axImagingCntrlPCIe(session, 0); // Idle mode
3) The pipeline mode and channel can be selected with axPipelineMode() and an argument selected from the AxPipelineMode and AxChannelMode enums:
returnValue = axPipelineMode(session, EIGHT_BIT, CHAN_1); // set pipeline mode to 8-bit processed data from Channel 1 returnValue = axPipelineMode(session, RAW_DATA, CHAN_2); // set pipeline mode to 16-bit raw ADC data from Channel 2
(Windows OS only) Follow these basic steps to control galvo scanner waveforms in your C-based client application. A C++ usage example is provided in axScanCmd_example.cpp. (Note: scanner control functionality does not require a Capture session to be initialized; however, axStopSession() will release scanner control resources.)
1) Scanner control functionality is accessed via a single function, axScanCmd(), the first argument of which is always a AxScannerCommand to indicate the desired operation, and additional arguments are used for some specific scanner commands or can otherwise be set to 0 or NULL.
int number_of_devices = (int)axScanCmd(COUNT_DEVICES, 0, NULL, NULL, NULL); // initialize scanner resources and count number of connected devices scan_params_t scan_pattern{ 0 }; // create a scan parameters structure for a rectangular raster pattern scan_pattern.X_increments = 2000; // populate some details of the scan parameters structure scan_pattern.Y_increments = 2000; // ... scan_pattern.X_range = 3.0; // ... scan_pattern.Y_range = 3.0; // ... returnValue = axScanCmd(SET_RECT_PATTERN, 0, &scan_pattern, NULL, NULL) // program this rectangular raster scan to the device returnValue = axScanCmd(CONTINUOUS_LINE_SCAN, 0, NULL, NULL, NULL); // execute a continuous line scan along the X dimension returnValue = axScanCmd(SETUP_BURST_RASTER, 0, NULL, NULL, NULL); // move scanner to start of 2D raster scan and wait for START_BURST_RASTER command returnValue = axScanCmd(START_BURST_RASTER, 0, NULL, NULL, NULL); // execute 2D raster scan once returnValue = axScanCmd(WAIT_BURST, 10, NULL, NULL, NULL) // wait for 2D raster scan to complete (function blocks until scan completed or timeout expires) returnValue = axScanCmd(DESTROY_SCAN, 0, NULL, NULL, NULL); // release scanner control resources
2) If desired, a callback function can be registered using axRegisterScannerConnectCallback() to execute whenever a scanner device is connected or disconnected from the library:
void MyCallback(void* user_data) { printf("In MyCallback!"); } returnValue = axRegisterScannerConnectCallback(MyCallback, NULL); // register "MyCallback" to be executed on device connect and disconnect