By Yihong Chen, Yue Cao, Han Hu, Liwei Wang.
This repo is an official implementation of "Memory Enhanced Global-Local Aggregation for Video Object Detection", accepted by CVPR 2020. This repository contains a PyTorch implementation of our approach MEGA based on maskrcnn_benchmark, as well as some training scripts to reproduce the results on ImageNet VID reported in our paper.
Besides, this repository also implements several other algorithms like FGFA and RDN. Any new methods are welcomed. Hoping for your pull request! We hope this repository would help further research in the field of video object detection and beyond. :)
Please cite our paper in your publications if it helps your research:
@inproceedings{chen20mega,
Author = {Chen, Yihong and Cao, Yue and Hu, Han and Wang, Liwei},
Title = {Memory Enhanced Global-Local Aggregation for Video Object Detection},
Conference = {CVPR},
Year = {2020}
}
- Add motion-IoU specific AP evaluation code. Only available for ImageNet VID dataset. (19/06/2020)
- Demo for visualization added (Support image folder and video). (17/06/2020)
- Results of ResNet-50 backbone added. (13/04/2020)
- Code and pretrained weights for Deep Feature Flow released. (30/03/2020)
Pretrained models are now available at Baidu (code: neck) and Google Drive.
| Model | Backbone | AP50 | AP (fast) | AP (med) | AP (slow) | Link |
|---|---|---|---|---|---|---|
| single frame baseline | ResNet-101 | 76.7 | 52.3 | 74.1 | 84.9 | |
| DFF | ResNet-101 | 75.0 | 48.3 | 73.5 | 84.5 | |
| FGFA | ResNet-101 | 78.0 | 55.3 | 76.9 | 85.6 | |
| RDN-base | ResNet-101 | 81.1 | 60.2 | 79.4 | 87.7 | |
| RDN | ResNet-101 | 81.7 | 59.5 | 80.0 | 89.0 | |
| MEGA | ResNet-101 | 82.9 | 62.7 | 81.6 | 89.4 |
| Model | Backbone | AP50 | AP (fast) | AP (med) | AP (slow) | Link |
|---|---|---|---|---|---|---|
| single frame baseline | ResNet-50 | 71.8 | 47.2 | 69.2 | 80.6 | |
| DFF | ResNet-50 | 70.4 | 43.6 | 68.9 | 80.8 | |
| FGFA | ResNet-50 | 74.3 | 50.6 | 72.3 | 84.0 | |
| RDN-base | ResNet-50 | 76.7 | 53.8 | 74.8 | 85.4 | |
| MEGA | ResNet-50 | 77.3 | 56.5 | 75.7 | 85.2 |
Note: The performance of ResNet-50 backbone are not so stable.
Note: The motion-IoU specific AP evaluation code is a bit different from the original implementation in FGFA. I think the original implementation is really weird so I modify it. So the results may not be directly comparable with the results provided in FGFA and other methods that use MXNet version evaluation code. But we could tell which method is relatively better under the same evaluation protocol.
Please follow INSTALL.md for installation instructions.
Please download ILSVRC2015 DET and ILSVRC2015 VID dataset from here. After that, we recommend to symlink the path to the datasets to datasets/. And the path structure should be as follows:
./datasets/ILSVRC2015/
./datasets/ILSVRC2015/Annotations/DET
./datasets/ILSVRC2015/Annotations/VID
./datasets/ILSVRC2015/Data/DET
./datasets/ILSVRC2015/Data/VID
./datasets/ILSVRC2015/ImageSets
Note: We have already provided a list of all images we use to train and test our model as txt files under directory datasets/ILSVRC2015/ImageSets. You do not need to change them.
Note: Cache files will be created at the first time you run this project, this may take some time! Don't worry!
Note: Currently, one GPU could only hold 1 image. Do not put 2 or more images on 1 GPU!
Note We provide template files named BASE_RCNN_{}gpus.yaml which would automatically change the batch size and other relevant settings. This behavior is similar to detectron2. If you want to train model with different number of gpus, please change it by yourself :) But assure 1 GPU only holds 1 image! That is to say, you should always keep SOLVER.IMS_PER_BATCH and TEST.IMS_PER_BATCH equal to the number of GPUs you use.
The inference command line for testing on the validation dataset:
python -m torch.distributed.launch \
--nproc_per_node 4 \
tools/test_net.py \
--config-file configs/MEGA/vid_R_101_C4_MEGA_1x.yaml \
--motion-specific \
MODEL.WEIGHT MEGA_R_101.pth
Please note that:
- If your model's name is different, please replace
MEGA_R_101.pthwith your own. - If you want to evaluate a different model, please change
--config-fileto its config file andMODEL.WEIGHTto its weights file. - If you do not want to evaluate motion-IoU specific AP, simply deleting
--motion-specific. - Testing is time-consuming, so be patient!
- As testing on above 170000+ frames is toooo time-consuming, so we enable directly testing on generated bounding boxes, which is automatically saved in a file named
predictions.pthon your training directory. That means you do not need to run the evaluation from the very start every time. You could access this by running:
python tools/test_prediction.py \
--config-file configs/MEGA/vid_R_101_C4_MEGA_1x.yaml \
--prediction [YOUR predictions.pth generated by MEGA]
--motion-specific
The following command line will train MEGA_R_101_FPN_1x on 4 GPUs with Synchronous Stochastic Gradient Descent (SGD):
python -m torch.distributed.launch \
--nproc_per_node=4 \
tools/train_net.py \
--master_port=$((RANDOM + 10000)) \
--config-file configs/MEGA/vid_R_101_C4_MEGA_1x.yaml \
--motion-specific \
OUTPUT_DIR training_dir/MEGA_R_101_1x
Please note that:
- The models will be saved into
OUTPUT_DIR. - If you want to train MEGA and other methods with other backbones, please change
--config-file. - For training FGFA and DFF, we need pretrained weight of FlowNet. We provide the converted version here. After downloaded, it should be placed at
models/. Seeconfig/defaults.pyand the code for further details. - For training RDN, we adopt the same two-stage training strategy as described in its original paper. The first phase should be run with config file
configs/RDN/vid_R_101_C4_RDN_base_1x.yaml. For the second phase,MODEL.WEIGHTshould be set to the filename of the final model of the first stage training. Or you could rename the model's filename toRDN_base_R_101.pthand put it undermodels/and directly train the second phase with config fileconfigs/RDN/vid_R_101_C4_RDN_1x.yaml. - If you do not want to evaluate motion-IoU specific AP at the end of training, simply deleting
--motion-specific.
Please follow demo/README.md to see how to visualize your own images or video.
If you want to use these methods on your own dataset or implement your new method. Please follow CUSTOMIZE.md.
Any pull requests or issues are welcomed.