Vincentqyw
update: features and matchers
a80d6bb
# Submodule used in [hloc](https://github.com/Vincentqyw/Hierarchical-Localization) toolbox
# [AAAI-23] TopicFM: Robust and Interpretable Topic-Assisted Feature Matching
Our method first inferred the latent topics (high-level context information) for each image and then use them to explicitly learn robust feature representation for the matching task. Please check out the details in [our paper](https://arxiv.org/abs/2207.00328)
![Alt Text](demo/topicfm.gif)
**Overall Architecture:**
![Alt Text](demo/architecture_v4.png)
## TODO List
- [x] Release training and evaluation code on MegaDepth and ScanNet
- [x] Evaluation on HPatches, Aachen Day&Night, and InLoc
- [x] Evaluation for Image Matching Challenge
## Requirements
All experiments in this paper are implemented on the Ubuntu environment
with a NVIDIA driver of at least 430.64 and CUDA 10.1.
First, create a virtual environment by anaconda as follows,
conda create -n topicfm python=3.8
conda activate topicfm
conda install pytorch==1.8.1 torchvision==0.9.1 cudatoolkit=10.1 -c pytorch
pip install -r requirements.txt
# using pip to install any missing packages
## Data Preparation
The proposed method is trained on the MegaDepth dataset and evaluated on the MegaDepth test, ScanNet, HPatches, Aachen Day and Night (v1.1), and InLoc dataset.
All these datasets are large, so we cannot include them in this code.
The following descriptions help download these datasets.
### MegaDepth
This dataset is used for both training and evaluation (Li and Snavely 2018).
To use this dataset with our code, please follow the [instruction of LoFTR](https://github.com/zju3dv/LoFTR/blob/master/docs/TRAINING.md) (Sun et al. 2021)
### ScanNet
We only use 1500 image pairs of ScanNet (Dai et al. 2017) for evaluation.
Please download and prepare [test data](https://drive.google.com/drive/folders/1DOcOPZb3-5cWxLqn256AhwUVjBPifhuf) of ScanNet
provided by [LoFTR](https://github.com/zju3dv/LoFTR/blob/master/docs/TRAINING.md).
## Training
To train our model, we recommend to use GPUs card as much as possible, and each GPU should be at least 12GB.
In our settings, we train on 4 GPUs, each of which is 12GB.
Please setup your hardware environment in `scripts/reproduce_train/outdoor.sh`.
And then run this command to start training.
bash scripts/reproduce_train/outdoor.sh
We then provide the trained model in `pretrained/model_best.ckpt`
## Evaluation
### MegaDepth (relative pose estimation)
bash scripts/reproduce_test/outdoor.sh
### ScanNet (relative pose estimation)
bash scripts/reproduce_test/indoor.sh
### HPatches, Aachen v1.1, InLoc
To evaluate on these datasets, we integrate our code to the image-matching-toolbox provided by Zhou et al. (2021).
The updated code is available [here](https://github.com/TruongKhang/image-matching-toolbox).
After cloning this code, please follow instructions of image-matching-toolbox to install all required packages and prepare data for evaluation.
Then, run these commands to perform evaluation: (note that all hyperparameter settings are in `configs/topicfm.yml`)
**HPatches (homography estimation)**
python -m immatch.eval_hpatches --gpu 0 --config 'topicfm' --task 'both' --h_solver 'cv' --ransac_thres 3 --root_dir . --odir 'outputs/hpatches'
**Aachen Day-Night v1.1 (visual localization)**
python -m immatch.eval_aachen --gpu 0 --config 'topicfm' --colmap <path to use colmap> --benchmark_name 'aachen_v1.1'
**InLoc (visual localization)**
python -m immatch.eval_inloc --gpu 0 --config 'topicfm'
### Image Matching Challenge 2022 (IMC-2022)
IMC-2022 was held on [Kaggle](https://www.kaggle.com/competitions/image-matching-challenge-2022/overview).
Most high ranking methods were achieved by using an ensemble method which combines the matching results of
various state-of-the-art methods including LoFTR, SuperPoint+SuperGlue, MatchFormer, or QuadTree Attention.
In this evaluation, we only submit the results produced by our method (TopicFM) alone. Please refer to [this notebook](https://www.kaggle.com/code/khangtg09121995/topicfm-eval).
This table compares our results with the other methods such as LoFTR (ref. [here](https://www.kaggle.com/code/mcwema/imc-2022-kornia-loftr-score-plateau-0-726)),
SP+SuperGlue (ref. [here](https://www.kaggle.com/code/yufei12/superglue-baseline)).
| | Public Score | Private Score |
|----------------|--------------|---------------|
| SP + SuperGlue | 0.678 | 0.677 |
| LoFTR | 0.726 | 0.736 |
| TopicFM (ours) | **0.804** | **0.811** |
### Runtime comparison
The runtime reported in the paper is measured by averaging runtime of 1500 image pairs of the ScanNet evaluation dataset.
The image size can be changed at `configs/data/scannet_test_1500.py`
python visualization.py --method <method_name> --dataset_name "scannet" --measure_time --no_viz
# note that method_name is in ["topicfm", "loftr"]
To measure time for LoFTR, please download the LoFTR's code as follows:
git submodule update --init
# download pretrained models
mkdir third_party/loftr/pretrained
gdown --id 1M-VD35-qdB5Iw-AtbDBCKC7hPolFW9UY -O third_party/loftr/pretrained/outdoor_ds.ckpt
## Citations
If you find this work useful, please cite this:
@article{giang2022topicfm,
title={TopicFM: Robust and Interpretable Topic-assisted Feature Matching},
author={Giang, Khang Truong and Song, Soohwan and Jo, Sungho},
journal={arXiv preprint arXiv:2207.00328},
year={2022}
}
## Acknowledgement
This code is built based on [LoFTR](https://github.com/zju3dv/LoFTR). We thank the authors for their useful source code.