Video and Vision Processing Suite Intel® FPGA IP User Guide

ID 683329
Date 12/31/2023
Public

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Document Table of Contents
1. About the Video and Vision Processing Suite 2. Getting Started with the Video and Vision Processing IPs 3. Video and Vision Processing IPs Functional Description 4. Video and Vision Processing IP Interfaces 5. Video and Vision Processing IP Registers 6. Video and Vision Processing IPs Software Programming Model 7. Protocol Converter Intel® FPGA IP 8. 1D LUT Intel® FPGA IP 9. 3D LUT Intel® FPGA IP 10. AXI-Stream Broadcaster Intel® FPGA IP 11. Bits per Color Sample Adapter Intel FPGA IP 12. Black Level Correction Intel® FPGA IP 13. Black Level Statistics Intel® FPGA IP 14. Chroma Key Intel® FPGA IP 15. Chroma Resampler Intel® FPGA IP 16. Clipper Intel® FPGA IP 17. Clocked Video Input Intel® FPGA IP 18. Clocked Video to Full-Raster Converter Intel® FPGA IP 19. Clocked Video Output Intel® FPGA IP 20. Color Space Converter Intel® FPGA IP 21. Defective Pixel Correction Intel® FPGA IP 22. Deinterlacer Intel® FPGA IP 23. Demosaic Intel® FPGA IP 24. FIR Filter Intel® FPGA IP 25. Frame Cleaner Intel® FPGA IP 26. Full-Raster to Clocked Video Converter Intel® FPGA IP 27. Full-Raster to Streaming Converter Intel® FPGA IP 28. Genlock Controller Intel® FPGA IP 29. Generic Crosspoint Intel® FPGA IP 30. Genlock Signal Router Intel® FPGA IP 31. Guard Bands Intel® FPGA IP 32. Histogram Statistics Intel® FPGA IP 33. Interlacer Intel® FPGA IP 34. Mixer Intel® FPGA IP 35. Pixels in Parallel Converter Intel® FPGA IP 36. Scaler Intel® FPGA IP 37. Stream Cleaner Intel® FPGA IP 38. Switch Intel® FPGA IP 39. Tone Mapping Operator Intel® FPGA IP 40. Test Pattern Generator Intel® FPGA IP 41. Unsharp Mask Intel® FPGA IP 42. Video and Vision Monitor Intel FPGA IP 43. Video Frame Buffer Intel® FPGA IP 44. Video Frame Reader Intel FPGA IP 45. Video Frame Writer Intel FPGA IP 46. Video Streaming FIFO Intel® FPGA IP 47. Video Timing Generator Intel® FPGA IP 48. Vignette Correction Intel® FPGA IP 49. Warp Intel® FPGA IP 50. White Balance Correction Intel® FPGA IP 51. White Balance Statistics Intel® FPGA IP 52. Design Security 53. Document Revision History for Video and Vision Processing Suite User Guide

36.3.4. Partial Frame Scaling

For large video wall applications, you may want to scale video frames using multiple scaler IPs. The output frames are split into tiles (either horizontally, vertically or horizontally and vertically), and each scaler IP processes the data for a single tile.

Typically, the goal is for the combined output image to look identical to how it looks when processed by a single scaler, without tiling. This result is not achieved automatically when using multiple scalers, and the IP requires additional information about the horizontal and vertical offset position of the scaler inside the combined image. If the scaling algorithms are not offset correctly for the chosen tiling, visible seams may appear in the combined output image. You can configure the scaler to support partial frame scaling, with separate parameters to enable tiling in the horizontal and vertical directions (Horizontal partial image scaling and Vertical partial image scaling respectively).

If you turn on partial image scaling in either the horizontal or vertical direction, you must provide additional offset information at run time via the register map. You must enable the Avalon memory-mapped control agent interface if you turn on partial scaling. The additional control values specify the fractional pixel offset for the first input pixel, an initial phase offset, and a fractional phase offset. You must also supply the resolutions of the untiled input and output images so that the IP can calculate the overall scaling ratio. For further details of the register map and how control values should be set for partial scaling, see Scaler Registers.

When using partial frames, you must calculate which portion of the overall input image is required to create the given output tile. Only send the required tile in the input image to the scaler IP. The following example demonstrates the calculation of the horizontal start index and end index of the required area within each line. The same calculations determine the vertical window, with width replaced by height. Where i s is the start index for the required tile in each input line and i e is the end index for the required tile in each input line. o s and o e are the indices of the first and last pixels of the output tile respectively in the overall, combined scaled output frame.

The indices i s and i e mark the edges of the minimum input tile required to generate the given output tile. However, to achieve a seamless join between tiles, extra overscan data is required on the edges of the tile to populate all the taps of the scaling filter. A filter with N taps has (N-1) /2 taps to the left (above for vertical) and N/2 taps to the right (below for vertical) of the center pixel in the filter. On the true left or right edge of the overall frame, you cannot fill these taps with any real data, so the IP replicates the edge pixel to populate them. However, for an output tile whose left and right edge does not sit at the edge of the overall frame, the IP must populate these taps with pixels from the input frame. The first and last indices of the input tile including overscan, i so and i eo respectively, are then defined as follows:

The horizontal dimension the scaler requires that pixel index i s is transmitted in pixel 0 within each group of pixels transmitted in parallel (as set by the Number of pixels in parallel parameter). Ensure you round the number of overscan pixels to the left of i s (nominally N-1) /2) to the nearest multiple of pixels in parallel (pip). The equation defines the final horizontal input tile left index (h_i so ) when overscan is on:

You can choose not to supply the additional overscan data if your system does not allow it or the cost is too high, but expect to see noticeable seams at the tile edges. Registers in the register map allow you to turn on and off the left and top edge overscan for horizontal and vertical scaling respectively at run time. This register merely informs the scaler whether it should expect the overscan data or not. The scaler responds automatically if it receives right or bottom edge overscan data, with no register map setting required. Controlling the overscan behavior of the scaler at runtime allows you to change the position of the tile that each scaler IP processes dynamically.