This page provides all the information related to Design Module 11 - VCU Quad Sensor MIPI CSI Video Capture and HDMI Display design.

1 Overview

This module enables video capture from the quad sensor connected through MIPI CSI-2 Rx implemented in the PL. The Avnet Multi-Camera FMC module is used to capture four video streams through a MIPI CSI-2 interface. The video can be displayed using HDMI Tx through the PL, and can be recorded in SD cards or USB/SATA drives. The module can stream-in or stream-out encoded data through an Ethernet interface. This module supports four video streams using AXI switch at capture side and mixer at display side for NV12 pixel format.

This design supports the following video interfaces:

Sources:

MIPI CSI-2 Rx capture pipeline implemented in the PL
File source (SD card, USB storage, SATA hard disk)
Stream-In from network or internet

Sinks:

HDMI-Tx display pipeline implemented in the PL

VCU Codec:

Video Encode/Decode capability using VCU hard block in PL
- AVC/HEVC encoding
- Encoder/decoder parameter configuration

Streaming Interfaces:

1G Ethernet PS GEM

Video format:

NV12

Supported Resolution:

The table below provides the supported resolution from the command-line app in this design.

Resolution	Command Line
Resolution	Single Stream	Multi-stream
1080p30	NA	√ (4-1080p30)

√- Supported
x - Not supported
NA - Not applicable

The below table gives information about the features supported in this design.

Pipeline	Input Source	Output Type	Resolution	VCU Codec
Multi-Stream Pass-through Pipeline Capture → Display	4 MIPI CSI-2 Rx	HDMI-Tx	4-1080p30	None
Multi-Stream Serial Pipeline Capture → Encode → Decode → Display	4 MIPI CSI-2 Rx	HDMI-Tx	4-1080p30	HEVC / AVC
Multi-Stream Record / Stream-Out pipeline	4 MIPI CSI-2 Rx	File Sink / Stream-Out	4-1080p30	HEVC / AVC
File Playback Pipeline	File Source	HDMI-Tx	1080p30	HEVC / AVC
Streaming Pipeline	Stream-In	HDMI-Tx	4-1080p30	HEVC / AVC

The below figure shows the VCU Quad Sensor MIPI CSI Multi Stream design hardware block diagram.

The below figure shows the VCU Quad Sensor MIPI CSI Multi Stream design software block diagram.

1.1 Board Setup

Refer below link for Board Setup

Zynq UltraScale+ MPSoC VCU TRD 2020.2 Board Setup

1.2 Run Flow

The TRD package is released with the source code, Vivado project, Petalinux BSP, and SD card image that enables the user to run the demonstration. It also includes the binaries necessary to configure and boot the ZCU106 board. Prior to running the steps mentioned in this wiki page, download the TRD package and extract its contents to a directory referred to as TRD_HOME which is the home directory.

Refer below link to download all TRD contents.

Refer Section 4.1 : Download the TRD of Zynq UltraScale+ MPSoC VCU TRD 2020.2 wiki page to download all TRD contents.

TRD package contents are placed in the following directory structure. The user needs to copy all the files from the $TRD_HOME/images/vcu_quad_sensor/ to FAT32 formatted SD card directory.

rdf0428-zcu106-vcu-trd-2020-2
├── apu
│   └── vcu_petalinux_bsp
├── images
│   ├── vcu_10g
│   ├── vcu_audio
│   ├── vcu_hdr10_hdmi
│   ├── vcu_llp2_hdmi_nv12
│   ├── vcu_llp2_hdmi_nv16
│   ├── vcu_llp2_hdmi_xv20
│   ├── vcu_llp2_sdi_xv20
│   ├── vcu_multistream_nv12
│   ├── vcu_pcie
│   ├── vcu_quad_sensor
│   └── vcu_sdi_xv20
├── pcie_host_package
│   ├── COPYING
│   ├── include
│   ├── LICENSE
│   ├── readme.txt
│   ├── RELEASE
│   ├── tests
│   ├── tools
│   └── xdma
├── pl
│   ├── constrs
│   ├── designs
│   ├── prebuild
│   ├── README.md
│   └── srcs
└── README.txt

TRD package contents specific to VCU Quad Sensor MIPI CSI Multi Stream design are placed in the following directory structure.

rdf0428-zcu106-vcu-trd-2020-2
├── apu
│   └── vcu_petalinux_bsp
│       └── xilinx-vcu-zcu106-v2020.2-final.bsp
├── images
│   ├── vcu_quad_sensor
│   │   ├── autostart.sh
│   │   ├── BOOT.BIN
│   │   ├── boot.scr
│   │   ├── config
│   │   ├── image.ub
│   │   ├── quad_sensor_isp_tuning.sh
│   │   ├── quad_sensor_media_graph_setting.sh
│   │   ├── system.dtb
│   │   └── vcu
├── pcie_host_package
├── pl
│   ├── constrs
│   ├── designs
│   │   ├── zcu106_Quad_Sensor
│   ├── prebuild
│   │   ├── zcu106_Quad_Sensor
│   ├── README.md
│   └── srcs
│       ├── hdl
│       └── ip
└── README.txt

The below snippet shows the configuration files (input.cfg) for running various multistream Display, Record, and Streaming use cases. All these configurations files are placed in the images folder mentioned above. The directory structure in /media/card.

config
├── 4-1080p30
│   ├── Display
│   ├── Record
│   ├── Stream-out
│   └── Stream-in 
└── input.cfg

1.2.1 GStreamer Application (vcu_gst_app)

The vcu_gst_app is a command-line multi-threaded Linux application. The command-line application requires an input configuration file (input.cfg) to be provided in the plain text.

Run below modetest command to set CRTC configurations for 4Kp30:

$ modetest -D a0270000.v_mix -s 42:3840x2160-30@AR24 &

Execution of the application is shown below:

$ vcu_gst_app <path to *.cfg file>

Example:

4-1080p30 HEVC_HIGH Display Pipeline Execution

$ vcu_gst_app /media/card/config/4-1080p30/Display/4_1080p30_HEVC_15Mbps.cfg

4-1080p30 HEVC_HIGH Record Pipeline Execution

$ vcu_gst_app /media/card/config/4-1080p30/Record/4_1080p30_HEVC_15Mbps.cfg

4-1080p30 HEVC_HIGH Stream-out Pipeline Execution

$ vcu_gst_app /media/card/config/4-1080p30/Stream-out/4_1080p30_HEVC_15Mbps.cfg

4-1080p30 HEVC_HIGH Stream-in Pipeline Execution

$ vcu_gst_app /media/card/config/4-1080p30/Stream-in/input.cfg

Latency Measurement: To measure the latency of the pipeline, run the below command. The latency data is huge, so dump it to a file.

$ GST_DEBUG="GST_TRACER:7" GST_TRACERS="latency" GST_DEBUG_FILE=/run/latency.log vcu_gst_app /media/card/config/input.cfg

Refer below link for detailed run flow steps

Zynq UltraScale+ MPSoC VCU TRD 2020.2 - Run Flow

1.3 Build Flow

Refer below link for detailed build flow steps

Zynq UltraScale+ MPSoC VCU TRD 2020.2 - Build Flow

2 Other Information

2.1 Known Issues

For Petalinux related known issues please refer: PetaLinux 2020.2 - Product Update Release Notes and Known Issues
For VCU related known issues please refer AR# 66763: LogiCORE H.264/H.265 Video Codec Unit (VCU) - Release Notes and Known Issues and Xilinx Zynq UltraScale+ MPSoC Video Codec Unit.
For Out of memory issue please refer: AR# 75900

2.2 Limitations

For Petalinux related limitations please refer: PetaLinux 2020.2 - Product Update Release Notes and Known Issues
For VCU related limitations please refer AR# 66763: LogiCORE H.264/H.265 Video Codec Unit (VCU) - Release Notes and Known Issues, Xilinx Zynq UltraScale+ MPSoC Video Codec Unit and PG252

2.3 Optimum VCU Encoder parameters for use-cases:

Video streaming:

Video streaming use-case requires a very stable bitrate graph for all pictures
It is good to avoid periodic large Intra pictures during the encoding session
Low-latency rate control (hardware RC) is the preferred control-rate for video streaming; as it tries to maintain equal amount frame sizes for all pictures.
Good to avoid periodic Intra frames instead use low-delay-p (IPPPPP…)
VBR is not a preferred mode of streaming

Performance: AVC Encoder settings:

It is preferred to use 8 or higher slices for better AVC encoder performance
AVC standard does not support Tile mode processing, which results in the processing of MB rows sequentially for entropy coding.

Quality: Low bitrate AVC encoding:

Enable profile=high and use qp-mode=auto for low-bitrate encoding use-cases
The high profile enables 8x8 transform which results in better video quality at low bitrates

3 Appendix A - Input Configuration File (input.cfg)

The example configuration files are stored at /media/card/config/ folder.

Configuration Type	Configuration Name	Description	Available Options
Common	Common Configuration	It is the starting point of common configuration
	Num of Input	Provide the number of inputs.	4
	Output	Select the video interface.	HDMI
	Out Type	Type of output	display, record, and stream
	Display Rate	Pipeline frame rate	30
	Exit	It indicates to the application that the configuration is over
Input	Input Configuration	It is the starting point of the input configuration
	Input Num	Starting N^th input configuration	1, 2, 3, 4
	Input Type	Input source type	CSI, CSI_2, CSI_3, CSI_4, File, Stream
	Uri	File path or Network URL. Applicable for file playback and stream-in pipeline only. Supported file formats for playback are ts, mp4, and mkv See Mount Location for additional file paths	file:///run/media/sda/abc.ts (for file path), udp://192.168.25.89:5004/ (for Network streaming, Here `192.168.25.89` is Client's IP address and `5004` is port number)
	Raw	To tell the pipeline is processed or pass-through	True, False
	Width	The width of the live source Avnet Quad Sensor FMC supports upto 1928x1208 resolution	1920
	Height	The height of the live source Avnet Quad Sensor FMC supports upto 1928x1208 resolution	1080
	Format	The format of input data	NV12
	Exit	It indicates to the application that the configuration is over
Encoder	Encoder Configuration	It is the starting point of encoder configuration
	Encoder Num	Starting N^th encoder configuration	1,2,3,4
	Encoder Name	Name of the encoder	AVC, HEVC
	Profile	Name of the profile	high for AVC, main for HEVC.
	Rate Control	Rate control options	CBR, VBR, and low-latency
	Filler Data	Filler Data NAL units for CBR rate control	True, False
	QP	QP control mode used by the VCU encoder	Uniform, Auto
	L2 Cache	Enable or Disable L2Cache buffer in encoding process.	True, False
	Latency Mode	Encoder latency mode.	Normal, sub_frame
	Low Bandwidth	If enabled, decrease the vertical search range used for P-frame motion estimation to reduce the bandwidth.	True, False
	Gop Mode	Group of Pictures mode.	Basic, low_delay_p, low_delay_b
	Bitrate	Target bitrate in Kbps	15000
	B Frames	Number of B-frames between two consecutive P-frames	0
	Slice	The number of slices produced for each frame. Each slice contains one or more complete macroblock/CTU row(s). Slices are distributed over the frame as regularly as possible. If slice-size is defined as well more slices may be produced to fit the slice-size requirement.	4-22 4K resolution with HEVC codec 4-32 4K resolution with AVC codec 4-32 1080p resolution with HEVC codec 4-32 1080p resolution with AVC codec
	GoP Length	The distance between two consecutive I frames	1-1000
	GDR Mode	It specifies which Gradual Decoder Refresh(GDR) scheme should be used when `gop-mode = low_delay_p` GDR mode is currently supported with LLP1/LLP2 low-delay-p use-cases only	Horizontal/Vertical/Disabled
	Entropy Mode	It specifies the entropy mode for H.264 (AVC) encoding process	CAVLC/CABAC/Default
	Max Picture Size	It is used to curtail instantaneous peak in the bit-stream using this parameter. It works in CBR/VBR rate-control only. When it is enabled, `max-picture-size` value is calculated and set with 10% of `AllowedPeakMargin`. i.e. `max-picture-size = (TargetBitrate / FrameRate) * 1.1` It works in CBR/VBR rate-control only	TRUE/FALSE
	Preset	Based on provided six presets, predefined configuration will be set for encoder parameters. Select custom to provide user-specific options for encoder parameters.	HEVC_HIGH, HEVC_MEDIUM, HEVC_LOW, AVC_HIGH, AVC_MEDIUM, AVC_LOW, Custom
	Exit	It indicates to the application that the configuration is over
Record	Record Configuration	It is the starting point of record configuration.
	Record Num	Starting N^th record configuration	1, 2, 3, 4
	Out-File Name	Record file path See Mount Location for additional file paths	e.g. /run/media/sda/abc.ts
	Duration	Duration in minutes	1-3
	Exit	It indicates to the application that the configuration is over.
Streaming	Streaming Configuration	It is the starting point of streaming configuration.
	Streaming Num	Starting N^th Streaming configuration	1, 2, 3, 4
	Host IP	The host to send the packets to	`192.168.25.89` or Windows PC IP
	Port:	The port to send the packets to	5004, 5008, 5012, 5016
	Exit	It indicates to the application that the configuration is over.
Trace	Trace Configuration	It is the starting point of trace configuration.
	FPS Info	To display fps info on the console.	True, False
	APM Info	To display APM counter number on the console.	True, False
	Pipeline Info	To display pipeline info on console.	True, False
	Exit	It indicates to the application that the configuration is over.

Mount Locations

The mount locations for various devices can be found in the below table.
The mount locations can vary. Users can use lsblk or mount to find the location of the mounted devices.

Below are some example mount points

Device	Mount Location
SD Card	/media/card
Sata Drive	/run/media/sda
USB Drive	/media/usb
RAM Disk	/run/media

4 Appendix B - CSI-2 Rx/HDMI-Tx Link-up and GStreamer Commands

This section covers configuration of CSI-2 Rx using media-ctl utility and HDMI-Tx using modetest utility, along with demonstrating CSI-2 Rx/HDMI-Tx link-up issues. It also contains sample GStreamer MIPI CSI Video pipelines for Display, Record & Playback, Stream-in and Stream-out use-cases.

Run the below command for media node to print media device topology where "media0" represents media node.

$ media-ctl -p -d /dev/media0

When MIPI CSI-2 Rx source is connected, it shows as below:

root@zcu106_vcu_quad_sensor:~# media-ctl -p -d /dev/media0
Media controller API version 5.4.0

Media device information
------------------------
driver          xilinx-video
model           Xilinx Video Composite Device
serial          
bus info        
hw revision     0x0
driver version  5.4.0

Device topology
- entity 1: vcap_csi_p0_scalar_0 output 0 (1 pad, 1 link)
            type Node subtype V4L flags 0
            device node name /dev/video0
	pad0: Sink
		<- "a0040000.v_proc_ss":1 [ENABLED]

- entity 5: vcap_csi_p0_scalar_0 output 1 (1 pad, 1 link)
            type Node subtype V4L flags 0
            device node name /dev/video1
	pad0: Sink
		<- "a0080000.v_proc_ss":1 [ENABLED]

- entity 9: vcap_csi_p0_scalar_0 output 2 (1 pad, 1 link)
            type Node subtype V4L flags 0
            device node name /dev/video2
	pad0: Sink
		<- "a00c0000.v_proc_ss":1 [ENABLED]

- entity 13: vcap_csi_p0_scalar_0 output 3 (1 pad, 1 link)
             type Node subtype V4L flags 0
             device node name /dev/video3
	pad0: Sink
		<- "a0140000.v_proc_ss":1 [ENABLED]

- entity 17: AR0231.25-0014 (1 pad, 1 link)
             type V4L2 subdev subtype Sensor flags 0
             device node name /dev/v4l-subdev0
	pad0: Source
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		-> "MAX9286-SERDES.25-0048":3 [ENABLED]

- entity 19: AR0231.25-0013 (1 pad, 1 link)
             type V4L2 subdev subtype Sensor flags 0
             device node name /dev/v4l-subdev1
	pad0: Source
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		-> "MAX9286-SERDES.25-0048":2 [ENABLED]

- entity 21: AR0231.25-0012 (1 pad, 1 link)
             type V4L2 subdev subtype Sensor flags 0
             device node name /dev/v4l-subdev2
	pad0: Source
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		-> "MAX9286-SERDES.25-0048":1 [ENABLED]

- entity 23: AR0231.25-0011 (1 pad, 1 link)
             type V4L2 subdev subtype Sensor flags 0
             device node name /dev/v4l-subdev3
	pad0: Source
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		-> "MAX9286-SERDES.25-0048":0 [ENABLED]

- entity 25: a0000000.mipi_csi2_rx_subsystem (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev4
	pad0: Source
		[fmt:SGRBG8_1X8/1920x1080 field:none]
		-> "amba_pl@0:axis_switch@0":0 [ENABLED]
	pad1: Sink
		[fmt:SGRBG8_1X8/1920x1080 field:none]
		<- "MAX9286-SERDES.25-0048":4 [ENABLED]

- entity 28: amba_pl@0:axis_switch@0 (5 pads, 5 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev5
	pad0: Sink
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		<- "a0000000.mipi_csi2_rx_subsystem":0 [ENABLED]
	pad1: Source
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		-> "a0190000.v_demosaic":0 [ENABLED]
	pad2: Source
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		-> "a01c0000.v_demosaic":0 [ENABLED]
	pad3: Source
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		-> "a01f0000.v_demosaic":0 [ENABLED]
	pad4: Source
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		-> "a0220000.v_demosaic":0 [ENABLED]

- entity 34: a0190000.v_demosaic (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev6
	pad0: Sink
		[fmt:SGRBG8_1X8/1920x1080 field:none]
		<- "amba_pl@0:axis_switch@0":1 [ENABLED]
	pad1: Source
		[fmt:RBG888_1X24/1920x1080 field:none]
		-> "a0180000.v_gamma_lut":0 [ENABLED]

- entity 37: a01c0000.v_demosaic (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev7
	pad0: Sink
		[fmt:SGRBG8_1X8/1920x1080 field:none]
		<- "amba_pl@0:axis_switch@0":2 [ENABLED]
	pad1: Source
		[fmt:RBG888_1X24/1920x1080 field:none]
		-> "a01b0000.v_gamma_lut":0 [ENABLED]

- entity 40: a01f0000.v_demosaic (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev8
	pad0: Sink
		[fmt:SGRBG8_1X8/1920x1080 field:none]
		<- "amba_pl@0:axis_switch@0":3 [ENABLED]
	pad1: Source
		[fmt:RBG888_1X24/1920x1080 field:none]
		-> "a01e0000.v_gamma_lut":0 [ENABLED]

- entity 43: a0220000.v_demosaic (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev9
	pad0: Sink
		[fmt:SGRBG8_1X8/1920x1080 field:none]
		<- "amba_pl@0:axis_switch@0":4 [ENABLED]
	pad1: Source
		[fmt:RBG888_1X24/1920x1080 field:none]
		-> "a0210000.v_gamma_lut":0 [ENABLED]

- entity 46: a0180000.v_gamma_lut (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev10
	pad0: Sink
		[fmt:RBG888_1X24/1920x1080 field:none]
		<- "a0190000.v_demosaic":1 [ENABLED]
	pad1: Source
		[fmt:RBG888_1X24/1920x1080 field:none]
		-> "a0010000.v_proc_ss":0 [ENABLED]

- entity 49: a01b0000.v_gamma_lut (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev11
	pad0: Sink
		[fmt:RBG888_1X24/1920x1080 field:none]
		<- "a01c0000.v_demosaic":1 [ENABLED]
	pad1: Source
		[fmt:RBG888_1X24/1920x1080 field:none]
		-> "a0020000.v_proc_ss":0 [ENABLED]

- entity 52: a01e0000.v_gamma_lut (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev12
	pad0: Sink
		[fmt:RBG888_1X24/1920x1080 field:none]
		<- "a01f0000.v_demosaic":1 [ENABLED]
	pad1: Source
		[fmt:RBG888_1X24/1920x1080 field:none]
		-> "a0030000.v_proc_ss":0 [ENABLED]

- entity 55: a0210000.v_gamma_lut (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev13
	pad0: Sink
		[fmt:RBG888_1X24/1920x1080 field:none]
		<- "a0220000.v_demosaic":1 [ENABLED]
	pad1: Source
		[fmt:RBG888_1X24/1920x1080 field:none]
		-> "a0100000.v_proc_ss":0 [ENABLED]

- entity 58: a0010000.v_proc_ss (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev14
	pad0: Sink
		[fmt:RBG888_1X24/1920x1080 field:none]
		<- "a0180000.v_gamma_lut":1 [ENABLED]
	pad1: Source
		[fmt:RBG888_1X24/1920x1080 field:none]
		-> "a0040000.v_proc_ss":0 [ENABLED]

- entity 61: a0020000.v_proc_ss (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev15
	pad0: Sink
		[fmt:RBG888_1X24/1920x1080 field:none]
		<- "a01b0000.v_gamma_lut":1 [ENABLED]
	pad1: Source
		[fmt:RBG888_1X24/1920x1080 field:none]
		-> "a0080000.v_proc_ss":0 [ENABLED]

- entity 64: a0030000.v_proc_ss (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev16
	pad0: Sink
		[fmt:RBG888_1X24/1920x1080 field:none]
		<- "a01e0000.v_gamma_lut":1 [ENABLED]
	pad1: Source
		[fmt:RBG888_1X24/1920x1080 field:none]
		-> "a00c0000.v_proc_ss":0 [ENABLED]

- entity 67: a0100000.v_proc_ss (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev17
	pad0: Sink
		[fmt:RBG888_1X24/1920x1080 field:none]
		<- "a0210000.v_gamma_lut":1 [ENABLED]
	pad1: Source
		[fmt:RBG888_1X24/1920x1080 field:none]
		-> "a0140000.v_proc_ss":0 [ENABLED]

- entity 70: a0040000.v_proc_ss (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev18
	pad0: Sink
		[fmt:RBG888_1X24/1920x1080 field:none]
		<- "a0010000.v_proc_ss":1 [ENABLED]
	pad1: Source
		[fmt:VYYUYY8_1X24/1920x1080 field:none]
		-> "vcap_csi_p0_scalar_0 output 0":0 [ENABLED]

- entity 73: a0080000.v_proc_ss (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev19
	pad0: Sink
		[fmt:RBG888_1X24/1920x1080 field:none]
		<- "a0020000.v_proc_ss":1 [ENABLED]
	pad1: Source
		[fmt:VYYUYY8_1X24/1920x1080 field:none]
		-> "vcap_csi_p0_scalar_0 output 1":0 [ENABLED]

- entity 76: a00c0000.v_proc_ss (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev20
	pad0: Sink
		[fmt:RBG888_1X24/1920x1080 field:none]
		<- "a0030000.v_proc_ss":1 [ENABLED]
	pad1: Source
		[fmt:VYYUYY8_1X24/1920x1080 field:none]
		-> "vcap_csi_p0_scalar_0 output 2":0 [ENABLED]

- entity 79: a0140000.v_proc_ss (2 pads, 2 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev21
	pad0: Sink
		[fmt:RBG888_1X24/1920x1080 field:none]
		<- "a0100000.v_proc_ss":1 [ENABLED]
	pad1: Source
		[fmt:VYYUYY8_1X24/1920x1080 field:none]
		-> "vcap_csi_p0_scalar_0 output 3":0 [ENABLED]

- entity 82: MAX9286-SERDES.25-0048 (5 pads, 5 links)
             type V4L2 subdev subtype Unknown flags 0
             device node name /dev/v4l-subdev22
	pad0: Sink
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		<- "AR0231.25-0011":0 [ENABLED]
	pad1: Sink
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		<- "AR0231.25-0012":0 [ENABLED]
	pad2: Sink
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		<- "AR0231.25-0013":0 [ENABLED]
	pad3: Sink
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		<- "AR0231.25-0014":0 [ENABLED]
	pad4: Source
		[fmt:SGRBG8_1X8/1920x1080 field:none colorspace:srgb]
		-> "a0000000.mipi_csi2_rx_subsystem":1 [ENABLED]

When the MIPI CSI-2 Rx source is not connected, it will not show any media node.

Notes for gst-launch-1.0 commands:

Video node for MIPI CSI-2 Rx source can be checked using media-ctl command. Run below media-ctl command to check video node for MIPI CSI-2 Rx source where "media0" indicates media node for MIPI CSI input source.

$ media-ctl -p -d /dev/media0

Make sure MIPI CSI-2 Rx media pipeline is configured for 1080p resolution and source/sink have the same color format. Run below script to set resolution and format of MIPI CSI-2 Rx media pipeline nodes where "media0" indicates media node for MIPI CSI-2 Rx input source.

$ sh /media/card/quad_sensor_media_graph_setting.sh

If HDMI-Tx link-up issue is observed after Linux booting, use the following command:

$ modetest -D a0270000.v_mix -s 42:3840x2160-30@AR24 &

Display RAW use case: Run the following gst-launch-1.0 command to display pass-through pipeline.

$ gst-launch-1.0 v4l2src device=/dev/video0 io-mode=4 ! video/x-raw, width=1920, height=1080, format=NV12, framerate=30/1 ! queue ! fpsdisplaysink text-overlay=false video-sink="kmssink bus-id="a0270000.v_mix" show-preroll-frame=false plane-id=34 render-rectangle=<0,0,1920,1080>" v4l2src device=/dev/video1 io-mode=4 ! video/x-raw, width=1920, height=1080, format=NV12, framerate=30/1 ! queue ! fpsdisplaysink text-overlay=false video-sink="kmssink bus-id="a0270000.v_mix" show-preroll-frame=false plane-id=35 render-rectangle=<1920,0,1920,1080>" v4l2src device=/dev/video2 io-mode=4 ! video/x-raw, width=1920, height=1080, format=NV12, framerate=30/1 ! queue ! fpsdisplaysink text-overlay=false video-sink="kmssink bus-id="a0270000.v_mix" show-preroll-frame=false plane-id=36 render-rectangle=<0,1080,1920,1080>" v4l2src device=/dev/video3 io-mode=4 ! video/x-raw, width=1920, height=1080, format=NV12, framerate=30/1 ! queue ! fpsdisplaysink text-overlay=false video-sink="kmssink bus-id="a0270000.v_mix" show-preroll-frame=false plane-id=37 render-rectangle=<1920,1080,1920,1080>" -v

Display serial use case: Run the following gst-launch-1.0 command to display processed pipeline (capture → encode → decode → display) on HDMI-Tx.

$ gst-launch-1.0 v4l2src device=/dev/video0 io-mode=4 ! video/x-raw, width=1920, height=1080, format=NV12, framerate=30/1 ! omxh265enc qp-mode=auto gop-mode=basic gop-length=60 b-frames=0 target-bitrate=15000 num-slices=8 control-rate=constant prefetch-buffer=true low-bandwidth=false filler-data=true cpb-size=1000 initial-delay=500 ! video/x-h265, profile=main, alignment=au ! queue ! omxh265dec internal-entropy-buffers=3 low-latency=0 ! queue max-size-bytes=0 ! fpsdisplaysink text-overlay=false video-sink="kmssink bus-id="a0270000.v_mix" show-preroll-frame=false plane-id=34 render-rectangle=<0,0,1920,1080>" v4l2src device=/dev/video1 io-mode=4 ! video/x-raw, width=1920, height=1080, format=NV12, framerate=30/1 ! omxh265enc qp-mode=auto gop-mode=basic gop-length=60 b-frames=0 target-bitrate=15000 num-slices=8 control-rate=constant prefetch-buffer=true low-bandwidth=false filler-data=true cpb-size=1000 initial-delay=500 ! video/x-h265, profile=main, alignment=au ! queue ! omxh265dec internal-entropy-buffers=3 low-latency=0 ! queue max-size-bytes=0 ! fpsdisplaysink text-overlay=false video-sink="kmssink bus-id="a0270000.v_mix" show-preroll-frame=false plane-id=35 render-rectangle=<1920,0,1920,1080>" v4l2src device=/dev/video2 io-mode=4 ! video/x-raw, width=1920, height=1080, format=NV12, framerate=30/1 ! omxh265enc qp-mode=auto gop-mode=basic gop-length=60 b-frames=0 target-bitrate=15000 num-slices=8 control-rate=constant prefetch-buffer=true low-bandwidth=false filler-data=true cpb-size=1000 initial-delay=500 ! video/x-h265, profile=main, alignment=au ! queue ! omxh265dec internal-entropy-buffers=3 low-latency=0 ! queue max-size-bytes=0 ! fpsdisplaysink text-overlay=false video-sink="kmssink bus-id="a0270000.v_mix" show-preroll-frame=false plane-id=36 render-rectangle=<0,1080,1920,1080>" v4l2src device=/dev/video3 io-mode=4 ! video/x-raw, width=1920, height=1080, format=NV12, framerate=30/1 ! omxh265enc qp-mode=auto gop-mode=basic gop-length=60 b-frames=0 target-bitrate=15000 num-slices=8 control-rate=constant prefetch-buffer=true low-bandwidth=false filler-data=true cpb-size=1000 initial-delay=500 ! video/x-h265, profile=main, alignment=au ! queue ! omxh265dec internal-entropy-buffers=3 low-latency=0 ! queue max-size-bytes=0 ! fpsdisplaysink text-overlay=false video-sink="kmssink bus-id="a0270000.v_mix" show-preroll-frame=false plane-id=37 render-rectangle=<1920,1080,1920,1080>" -v

Record use case: Run the following gst-launch-1.0 command to record video using GStreamer pipeline.

$ gst-launch-1.0 v4l2src device=/dev/video0 io-mode=4 num-buffers=1800 ! video/x-raw, format=NV12, width=1920, height=1080, framerate=30/1 ! omxh265enc qp-mode=auto gop-mode=basic gop-length=60 b-frames=0 target-bitrate=15000 num-slices=8 control-rate=constant prefetch-buffer=true low-bandwidth=false filler-data=true cpb-size=1000 initial-delay=500 ! queue ! video/x-h265, profile=main, alignment=au ! mpegtsmux alignment=7 name=mux0 ! filesink location="/run/media/sda/test_1.ts" v4l2src device=/dev/video1 io-mode=4 num-buffers=1800 ! video/x-raw, format=NV12, width=1920, height=1080, framerate=30/1 ! omxh265enc qp-mode=auto gop-mode=basic gop-length=60 b-frames=0 target-bitrate=15000 num-slices=8 control-rate=constant prefetch-buffer=true low-bandwidth=false filler-data=true cpb-size=1000 initial-delay=500 ! queue ! video/x-h265, profile=main, alignment=au ! mpegtsmux alignment=7 name=mux1 ! filesink location="/run/media/sda/test_2.ts" v4l2src device=/dev/video2 io-mode=4 num-buffers=1800 ! video/x-raw, format=NV12, width=1920, height=1080, framerate=30/1 ! omxh265enc qp-mode=auto gop-mode=basic gop-length=60 b-frames=0 target-bitrate=15000 num-slices=8 control-rate=constant prefetch-buffer=true low-bandwidth=false filler-data=true cpb-size=1000 initial-delay=500 ! queue ! video/x-h265, profile=main, alignment=au ! mpegtsmux alignment=7 name=mux2 ! filesink location="/run/media/sda/test_3.ts" v4l2src device=/dev/video3 io-mode=4 num-buffers=1800 ! video/x-raw, format=NV12, width=1920, height=1080, framerate=30/1 ! omxh265enc qp-mode=auto gop-mode=basic gop-length=60 b-frames=0 target-bitrate=15000 num-slices=8 control-rate=constant prefetch-buffer=true low-bandwidth=false filler-data=true cpb-size=1000 initial-delay=500 ! queue ! video/x-h265, profile=main, alignment=au ! mpegtsmux alignment=7 name=mux3 ! filesink location="/run/media/sda/test_4.ts"

File location should be SATA SSD(ext4 format) to avoid the read-write bandwidth issue

File Playback use case: Run the following gst-launch-1.0 command to play the recorded file on HDMI-Tx using the GStreamer pipeline.

$ gst-launch-1.0 uridecodebin uri="file:///run/media/sda/test_1.ts" ! queue max-size-bytes=0 ! fpsdisplaysink text-overlay=false video-sink="kmssink bus-id="a0270000.v_mix" plane-id=34 render-rectangle=<0,0,1920,1080>" uridecodebin uri="file:///run/media/sda/test_2.ts" ! queue max-size-bytes=0 ! fpsdisplaysink text-overlay=false video-sink="kmssink bus-id="a0270000.v_mix" plane-id=35 render-rectangle=<1920,0,1920,1080>" uridecodebin uri="file:///run/media/sda/test_3.ts" ! queue max-size-bytes=0 ! fpsdisplaysink text-overlay=false video-sink="kmssink bus-id="a0270000.v_mix" plane-id=36 render-rectangle=<0,1080,1920,1080>" uridecodebin uri="file:///run/media/sda/test_4.ts" ! queue max-size-bytes=0 ! fpsdisplaysink text-overlay=false video-sink="kmssink bus-id="a0270000.v_mix" plane-id=37 render-rectangle=<1920,1080,1920,1080>" -v