Supported Hardware
Frigate supports multiple different detectors that work on different types of hardware:
Most Hardware
- Coral EdgeTPU: The Google Coral EdgeTPU is available in USB and m.2 format allowing for a wide range of compatibility with devices.
- Hailo: The Hailo8 AI Acceleration module is available in m.2 format with a HAT for RPi devices, offering a wide range of compatibility with devices.
AMD
- ROCm: ROCm can run on AMD Discrete GPUs to provide efficient object detection.
- ONNX: ROCm will automatically be detected and used as a detector in the
-rocmFrigate image when a supported ONNX model is configured.
Intel
- OpenVino: OpenVino can run on Intel Arc GPUs, Intel integrated GPUs, and Intel CPUs to provide efficient object detection.
- ONNX: OpenVINO will automatically be detected and used as a detector in the default Frigate image when a supported ONNX model is configured.
Nvidia
- TensortRT: TensorRT can run on Nvidia GPUs, using one of many default models.
- ONNX: TensorRT will automatically be detected and used as a detector in the
-tensorrtFrigate image when a supported ONNX model is configured.
Rockchip
- RKNN: RKNN models can run on Rockchip devices with included NPUs.
Officially Supported Detectors
Frigate provides the following builtin detector types: cpu, edgetpu, openvino, tensorrt, rknn, and hailo8l. By default, Frigate will use a single CPU detector. Other detectors may require additional configuration as described below. When using multiple detectors they will run in dedicated processes, but pull from a common queue of detection requests from across all cameras.
CPU Detector (not recommended)
The CPU detector type runs a TensorFlow Lite model utilizing the CPU without hardware acceleration. It is recommended to use a hardware accelerated detector type instead for better performance. To configure a CPU based detector, set the "type" attribute to "cpu".
If you do not have GPU or Edge TPU hardware, using the OpenVINO Detector is often more efficient than using the CPU detector.
The number of threads used by the interpreter can be specified using the "num_threads" attribute, and defaults to 3.
A TensorFlow Lite model is provided in the container at /cpu_model.tflite and is used by this detector type by default. To provide your own model, bind mount the file into the container and provide the path with model.path.
detectors:
cpu1:
type: cpu
num_threads: 3
model:
path: "/custom_model.tflite"
cpu2:
type: cpu
num_threads: 3
When using CPU detectors, you can add one CPU detector per camera. Adding more detectors than the number of cameras should not improve performance.
Edge TPU Detector
The Edge TPU detector type runs a TensorFlow Lite model utilizing the Google Coral delegate for hardware acceleration. To configure an Edge TPU detector, set the "type" attribute to "edgetpu".
The Edge TPU device can be specified using the "device" attribute according to the Documentation for the TensorFlow Lite Python API. If not set, the delegate will use the first device it finds.
A TensorFlow Lite model is provided in the container at /edgetpu_model.tflite and is used by this detector type by default. To provide your own model, bind mount the file into the container and provide the path with model.path.
See common Edge TPU troubleshooting steps if the Edge TPU is not detected.
Single USB Coral
detectors:
coral:
type: edgetpu
device: usb
Multiple USB Corals
detectors:
coral1:
type: edgetpu
device: usb:0
coral2:
type: edgetpu
device: usb:1
Native Coral (Dev Board)
warning: may have compatibility issues after v0.9.x
detectors:
coral:
type: edgetpu
device: ""
Single PCIE/M.2 Coral
detectors:
coral:
type: edgetpu
device: pci
Multiple PCIE/M.2 Corals
detectors:
coral1:
type: edgetpu
device: pci:0
coral2:
type: edgetpu
device: pci:1
Mixing Corals
detectors:
coral_usb:
type: edgetpu
device: usb
coral_pci:
type: edgetpu
device: pci
OpenVINO Detector
The OpenVINO detector type runs an OpenVINO IR model on AMD and Intel CPUs, Intel GPUs and Intel VPU hardware. To configure an OpenVINO detector, set the "type" attribute to "openvino".
The OpenVINO device to be used is specified using the "device" attribute according to the naming conventions in the Device Documentation. The most common devices are CPU and GPU. Currently, there is a known issue with using AUTO. For backwards compatibility, Frigate will attempt to use GPU if AUTO is set in your configuration.
OpenVINO is supported on 6th Gen Intel platforms (Skylake) and newer. It will also run on AMD CPUs despite having no official support for it. A supported Intel platform is required to use the GPU device with OpenVINO. For detailed system requirements, see OpenVINO System Requirements
When using many cameras one detector may not be enough to keep up. Multiple detectors can be defined assuming GPU resources are available. An example configuration would be:
detectors:
ov_0:
type: openvino
device: GPU
ov_1:
type: openvino
device: GPU
Supported Models
SSDLite MobileNet v2
An OpenVINO model is provided in the container at /openvino-model/ssdlite_mobilenet_v2.xml and is used by this detector type by default. The model comes from Intel's Open Model Zoo SSDLite MobileNet V2 and is converted to an FP16 precision IR model. Use the model configuration shown below when using the OpenVINO detector with the default model.
detectors:
ov:
type: openvino
device: GPU
model:
width: 300
height: 300
input_tensor: nhwc
input_pixel_format: bgr
path: /openvino-model/ssdlite_mobilenet_v2.xml
labelmap_path: /openvino-model/coco_91cl_bkgr.txt
YOLOX
This detector also supports YOLOX. Frigate does not come with any YOLOX models preloaded, so you will need to supply your own models.
YOLO-NAS
YOLO-NAS models are supported, but not included by default. You can build and download a compatible model with pre-trained weights using this notebook 
.
The pre-trained YOLO-NAS weights from DeciAI are subject to their license and can't be used commercially. For more information, see: https://docs.deci.ai/super-gradients/latest/LICENSE.YOLONAS.html
The input image size in this notebook is set to 320x320. This results in lower CPU usage and faster inference times without impacting performance in most cases due to the way Frigate crops video frames to areas of interest before running detection. The notebook and config can be updated to 640x640 if desired.
After placing the downloaded onnx model in your config folder, you can use the following configuration:
detectors:
ov:
type: openvino
device: GPU
model:
model_type: yolonas
width: 320 # <--- should match whatever was set in notebook
height: 320 # <--- should match whatever was set in notebook
input_tensor: nchw
input_pixel_format: bgr
path: /config/yolo_nas_s.onnx
labelmap_path: /labelmap/coco-80.txt
Note that the labelmap uses a subset of the complete COCO label set that has only 80 objects.
NVidia TensorRT Detector
Nvidia GPUs may be used for object detection using the TensorRT libraries. Due to the size of the additional libraries, this detector is only provided in images with the -tensorrt tag suffix, e.g. ghcr.io/blakeblackshear/frigate:stable-tensorrt. This detector is designed to work with Yolo models for object detection.
Minimum Hardware Support
The TensorRT detector uses the 12.x series of CUDA libraries which have minor version compatibility. The minimum driver version on the host system must be >=530. Also the GPU must support a Compute Capability of 5.0 or greater. This generally correlates to a Maxwell-era GPU or newer, check the NVIDIA GPU Compute Capability table linked below.
To use the TensorRT detector, make sure your host system has the nvidia-container-runtime installed to pass through the GPU to the container and the host system has a compatible driver installed for your GPU.
There are improved capabilities in newer GPU architectures that TensorRT can benefit from, such as INT8 operations and Tensor cores. The features compatible with your hardware will be optimized when the model is converted to a trt file. Currently the script provided for generating the model provides a switch to enable/disable FP16 operations. If you wish to use newer features such as INT8 optimization, more work is required.
Compatibility References:
NVIDIA TensorRT Support Matrix
Generate Models
The model used for TensorRT must be preprocessed on the same hardware platform that they will run on. This means that each user must run additional setup to generate a model file for the TensorRT library. A script is included that will build several common models.
The Frigate image will generate model files during startup if the specified model is not found. Processed models are stored in the /config/model_cache folder. Typically the /config path is mapped to a directory on the host already and the model_cache does not need to be mapped separately unless the user wants to store it in a different location on the host.
By default, the yolov7-320 model will be generated, but this can be overridden by specifying the YOLO_MODELS environment variable in Docker. One or more models may be listed in a comma-separated format, and each one will be generated. To select no model generation, set the variable to an empty string, YOLO_MODELS="". Models will only be generated if the corresponding {model}.trt file is not present in the model_cache folder, so you can force a model to be regenerated by deleting it from your Frigate data folder.
If you have a Jetson device with DLAs (Xavier or Orin), you can generate a model that will run on the DLA by appending -dla to your model name, e.g. specify YOLO_MODELS=yolov7-320-dla. The model will run on DLA0 (Frigate does not currently support DLA1). DLA-incompatible layers will fall back to running on the GPU.
If your GPU does not support FP16 operations, you can pass the environment variable USE_FP16=False to disable it.
Specific models can be selected by passing an environment variable to the docker run command or in your docker-compose.yml file. Use the form -e YOLO_MODELS=yolov4-416,yolov4-tiny-416 to select one or more model names. The models available are shown below.
yolov3-288
yolov3-416
yolov3-608
yolov3-spp-288
yolov3-spp-416
yolov3-spp-608
yolov3-tiny-288
yolov3-tiny-416
yolov4-288
yolov4-416
yolov4-608
yolov4-csp-256
yolov4-csp-512
yolov4-p5-448
yolov4-p5-896
yolov4-tiny-288
yolov4-tiny-416
yolov4x-mish-320
yolov4x-mish-640
yolov7-tiny-288
yolov7-tiny-416
yolov7-640
yolov7-320
yolov7x-640
yolov7x-320
An example docker-compose.yml fragment that converts the yolov4-608 and yolov7x-640 models for a Pascal card would look something like this:
frigate:
environment:
- YOLO_MODELS=yolov4-608,yolov7x-640
- USE_FP16=false
If you have multiple GPUs passed through to Frigate, you can specify which one to use for the model conversion. The conversion script will use the first visible GPU, however in systems with mixed GPU models you may not want to use the default index for object detection. Add the TRT_MODEL_PREP_DEVICE environment variable to select a specific GPU.
frigate:
environment:
- TRT_MODEL_PREP_DEVICE=0 # Optionally, select which GPU is used for model optimization
Configuration Parameters
The TensorRT detector can be selected by specifying tensorrt as the model type. The GPU will need to be passed through to the docker container using the same methods described in the Hardware Acceleration section. If you pass through multiple GPUs, you can select which GPU is used for a detector with the device configuration parameter. The device parameter is an integer value of the GPU index, as shown by nvidia-smi within the container.
The TensorRT detector uses .trt model files that are located in /config/model_cache/tensorrt by default. These model path and dimensions used will depend on which model you have generated.
detectors:
tensorrt:
type: tensorrt
device: 0 #This is the default, select the first GPU
model:
path: /config/model_cache/tensorrt/yolov7-320.trt
input_tensor: nchw
input_pixel_format: rgb
width: 320
height: 320
AMD/ROCm GPU detector
Setup
The rocm detector supports running YOLO-NAS models on AMD GPUs. Use a frigate docker image with -rocm suffix, for example ghcr.io/blakeblackshear/frigate:stable-rocm.
Docker settings for GPU access
ROCm needs access to the /dev/kfd and /dev/dri devices. When docker or frigate is not run under root then also video (and possibly render and ssl/_ssl) groups should be added.
When running docker directly the following flags should be added for device access:
$ docker run --device=/dev/kfd --device=/dev/dri \
...
When using docker compose:
services:
frigate:
---
devices:
- /dev/dri
- /dev/kfd
For reference on recommended settings see running ROCm/pytorch in Docker.
Docker settings for overriding the GPU chipset
Your GPU might work just fine without any special configuration but in many cases they need manual settings. AMD/ROCm software stack comes with a limited set of GPU drivers and for newer or missing models you will have to override the chipset version to an older/generic version to get things working.
Also AMD/ROCm does not "officially" support integrated GPUs. It still does work with most of them just fine but requires special settings. One has to configure the HSA_OVERRIDE_GFX_VERSION environment variable. See the ROCm bug report for context and examples.
For the rocm frigate build there is some automatic detection:
- gfx90c -> 9.0.0
- gfx1031 -> 10.3.0
- gfx1103 -> 11.0.0
If you have something else you might need to override the HSA_OVERRIDE_GFX_VERSION at Docker launch. Suppose the version you want is 9.0.0, then you should configure it from command line as:
$ docker run -e HSA_OVERRIDE_GFX_VERSION=9.0.0 \
...
When using docker compose:
services:
frigate:
...
environment:
HSA_OVERRIDE_GFX_VERSION: "9.0.0"
Figuring out what version you need can be complicated as you can't tell the chipset name and driver from the AMD brand name.
- first make sure that rocm environment is running properly by running
/opt/rocm/bin/rocminfoin the frigate container -- it should list both the CPU and the GPU with their properties - find the chipset version you have (gfxNNN) from the output of the
rocminfo(see below) - use a search engine to query what
HSA_OVERRIDE_GFX_VERSIONyou need for the given gfx name ("gfxNNN ROCm HSA_OVERRIDE_GFX_VERSION") - override the
HSA_OVERRIDE_GFX_VERSIONwith relevant value - if things are not working check the frigate docker logs
Figuring out if AMD/ROCm is working and found your GPU
$ docker exec -it frigate /opt/rocm/bin/rocminfo
Figuring out your AMD GPU chipset version:
We unset the HSA_OVERRIDE_GFX_VERSION to prevent an existing override from messing up the result:
$ docker exec -it frigate /bin/bash -c '(unset HSA_OVERRIDE_GFX_VERSION && /opt/rocm/bin/rocminfo |grep gfx)'
Supported Models
There is no default model provided, the following formats are supported:
YOLO-NAS
YOLO-NAS models are supported, but not included by default. You can build and download a compatible model with pre-trained weights using this notebook .
The pre-trained YOLO-NAS weights from DeciAI are subject to their license and can't be used commercially. For more information, see: https://docs.deci.ai/super-gradients/latest/LICENSE.YOLONAS.html
The input image size in this notebook is set to 320x320. This results in lower CPU usage and faster inference times without impacting performance in most cases due to the way Frigate crops video frames to areas of interest before running detection. The notebook and config can be updated to 640x640 if desired.
After placing the downloaded onnx model in your config folder, you can use the following configuration:
detectors:
onnx:
type: rocm
model:
model_type: yolonas
width: 320 # <--- should match whatever was set in notebook
height: 320 # <--- should match whatever was set in notebook
input_pixel_format: bgr
path: /config/yolo_nas_s.onnx
labelmap_path: /labelmap/coco-80.txt
Note that the labelmap uses a subset of the complete COCO label set that has only 80 objects.
ONNX
ONNX is an open format for building machine learning models, Frigate supports running ONNX models on CPU, OpenVINO, and TensorRT. On startup Frigate will automatically try to use a GPU if one is available.
When using many cameras one detector may not be enough to keep up. Multiple detectors can be defined assuming GPU resources are available. An example configuration would be:
detectors:
onnx_0:
type: onnx
onnx_1:
type: onnx
Supported Models
There is no default model provided, the following formats are supported:
YOLO-NAS
YOLO-NAS models are supported, but not included by default. You can build and download a compatible model with pre-trained weights using this notebook .
The pre-trained YOLO-NAS weights from DeciAI are subject to their license and can't be used commercially. For more information, see: https://docs.deci.ai/super-gradients/latest/LICENSE.YOLONAS.html
The input image size in this notebook is set to 320x320. This results in lower CPU usage and faster inference times without impacting performance in most cases due to the way Frigate crops video frames to areas of interest before running detection. The notebook and config can be updated to 640x640 if desired.
After placing the downloaded onnx model in your config folder, you can use the following configuration:
detectors:
onnx:
type: onnx
model:
model_type: yolonas
width: 320 # <--- should match whatever was set in notebook
height: 320 # <--- should match whatever was set in notebook
input_pixel_format: bgr
path: /config/yolo_nas_s.onnx
labelmap_path: /labelmap/coco-80.txt
Note that the labelmap uses a subset of the complete COCO label set that has only 80 objects.
Deepstack / CodeProject.AI Server Detector
The Deepstack / CodeProject.AI Server detector for Frigate allows you to integrate Deepstack and CodeProject.AI object detection capabilities into Frigate. CodeProject.AI and DeepStack are open-source AI platforms that can be run on various devices such as the Raspberry Pi, Nvidia Jetson, and other compatible hardware. It is important to note that the integration is performed over the network, so the inference times may not be as fast as native Frigate detectors, but it still provides an efficient and reliable solution for object detection and tracking.
Setup
To get started with CodeProject.AI, visit their official website to follow the instructions to download and install the AI server on your preferred device. Detailed setup instructions for CodeProject.AI are outside the scope of the Frigate documentation.
To integrate CodeProject.AI into Frigate, you'll need to make the following changes to your Frigate configuration file:
detectors:
deepstack:
api_url: http://<your_codeproject_ai_server_ip>:<port>/v1/vision/detection
type: deepstack
api_timeout: 0.1 # seconds
Replace <your_codeproject_ai_server_ip> and <port> with the IP address and port of your CodeProject.AI server.
To verify that the integration is working correctly, start Frigate and observe the logs for any error messages related to CodeProject.AI. Additionally, you can check the Frigate web interface to see if the objects detected by CodeProject.AI are being displayed and tracked properly.
Community Supported Detectors
Rockchip platform
Hardware accelerated object detection is supported on the following SoCs:
- RK3562
- RK3566
- RK3568
- RK3576
- RK3588
This implementation uses the Rockchip's RKNN-Toolkit2, version v2.0.0.beta0. Currently, only Yolo-NAS is supported as object detection model.
Prerequisites
Make sure to follow the Rockchip specific installation instrucitions.
Configuration
This config.yml shows all relevant options to configure the detector and explains them. All values shown are the default values (except for two). Lines that are required at least to use the detector are labeled as required, all other lines are optional.
detectors: # required
rknn: # required
type: rknn # required
# number of NPU cores to use
# 0 means choose automatically
# increase for better performance if you have a multicore NPU e.g. set to 3 on rk3588
num_cores: 0
model: # required
# name of model (will be automatically downloaded) or path to your own .rknn model file
# possible values are:
# - deci-fp16-yolonas_s
# - deci-fp16-yolonas_m
# - deci-fp16-yolonas_l
# - /config/model_cache/your_custom_model.rknn
path: deci-fp16-yolonas_s
# width and height of detection frames
width: 320
height: 320
# pixel format of detection frame
# default value is rgb but yolo models usually use bgr format
input_pixel_format: bgr # required
# shape of detection frame
input_tensor: nhwc
# needs to be adjusted to model, see below
labelmap_path: /labelmap.txt # required
The correct labelmap must be loaded for each model. If you use a custom model (see notes below), you must make sure to provide the correct labelmap. The table below lists the correct paths for the bundled models:
path | labelmap_path |
|---|---|
| deci-fp16-yolonas_* | /labelmap/coco-80.txt |
Choosing a model
The pre-trained YOLO-NAS weights from DeciAI are subject to their license and can't be used commercially. For more information, see: https://docs.deci.ai/super-gradients/latest/LICENSE.YOLONAS.html
The inference time was determined on a rk3588 with 3 NPU cores.
| Model | Size in mb | Inference time in ms |
|---|---|---|
| deci-fp16-yolonas_s | 24 | 25 |
| deci-fp16-yolonas_m | 62 | 35 |
| deci-fp16-yolonas_l | 81 | 45 |
You can get the load of your NPU with the following command:
$ cat /sys/kernel/debug/rknpu/load
>> NPU load: Core0: 0%, Core1: 0%, Core2: 0%,
- All models are automatically downloaded and stored in the folder
config/model_cache/rknn_cache. After upgrading Frigate, you should remove older models to free up space. - You can also provide your own
.rknnmodel. You should not save your own models in therknn_cachefolder, store them directly in themodel_cachefolder or another subfolder. To convert a model to.rknnformat see therknn-toolkit2(requires a x86 machine). Note, that there is only post-processing for the supported models.
Hailo-8l
This detector is available for use with Hailo-8 AI Acceleration Module.
See the installation docs for information on configuring the hailo8.
Configuration
detectors:
hailo8l:
type: hailo8l
device: PCIe
model:
path: /config/model_cache/h8l_cache/ssd_mobilenet_v1.hef
model:
width: 300
height: 300
input_tensor: nhwc
input_pixel_format: bgr
model_type: ssd