The repository contains a Fractal Category Search, FractalDB Construction, Pre-training, and Fine-tuning in Python/PyTorch.
The repository is based on the paper: Hirokatsu Kataoka, Kazushige Okayasu, Asato Matsumoto, Eisuke Yamagata, Ryosuke Yamada, Nakamasa Inoue, Akio Nakamura and Yutaka Satoh, "Pre-training without Natural Images", International Journal of Computer Vision (IJCV) / ACCV 2020 Best Paper Honorable Mention Award [Project] [PDF (IJCV)] [PDF (ACCV)] [Dataset] [Oral] [Poster]
Update (Mar 23, 2022)
- The paper was accepted to International Journal of Computer Vision (IJCV). We updated the scripts and pre-trained models in the extended experiments. [PDF] [Pre-trained Models]
Update (May 22, 2021)
- Related project "Can Vision Transformers Learn without Natural Images?" was released. We achieved to train vision transformers (ViT) without natural images. [Project] [PDF] [Code]
Update (Jan. 8, 2021)
- Pre-training & Fine-tuning codes
- Downloadable pre-training models [Link]
- Multi-thread preparation with
param_search/parallel_dir.py - Divide execution files into single-thread processing
exe.shand multi-thread processingexe_parallel.shfor FractalDB rendering.
If you use this code, please cite the following paper:
@article{KataokaIJCV2022,
author={Kataoka, Hirokatsu and Okayasu, Kazushige and Matsumoto, Asato and Yamagata, Eisuke and Yamada, Ryosuke and Inoue, Nakamasa and Nakamura, Akio and Satoh, Yutaka},
title={Pre-training without Natural Images},
article={International Journal on Computer Vision (IJCV)},
year={2022},
}
@inproceedings{KataokaACCV2020,
author={Kataoka, Hirokatsu and Okayasu, Kazushige and Matsumoto, Asato and Yamagata, Eisuke and Yamada, Ryosuke and Inoue, Nakamasa and Nakamura, Akio and Satoh, Yutaka},
title={Pre-training without Natural Images},
booktitle={Asian Conference on Computer Vision (ACCV)},
year={2020},
}-
Python 3.x (worked at 3.7)
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Pytorch 1.x (worked at 1.4)
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CUDA (worked at 10.1)
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CuDNN (worked at 7.6)
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Graphic board (worked at single/four NVIDIA V100)
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Fine-tuning datasets If you would like to fine-tune on an image dataset, you must prepare conventional or self-defined datasets. [This repository] includes a downloader as an optional way. To use the following execution files
exe.shandexe_parallel.sh, you should set the downloaded CIFAR-10 dataset in./dataas the following structure.
./
data/
CIFAR10/
train/
airplane/
0001.png
0002.png
...
...
val/
airplane/
0001.png
0002.png
...
...
# Caution! We changed the dir name from 'test' to 'val'
We prepared execution files exe.sh and exe_parallel.sh in the top directory. The execution file contains our recommended parameters. Please type the following commands on your environment. You can execute the Fractal Category Search, FractalDB Construction, Pre-training, and Fine-tuning.
chmod +x exe.sh
./exe.shFor a faster execution, you shuold run the exe_parallel.sh as follows. You must adjust the thread parameter numof_thread=40 in the script depending on your computational resource.
chmod +x exe_parallel.sh
./exe_parallel.shRun the code param_search/ifs_search.py to create fractal categories and their representative images. In our work, the basic parameters are --rate 0.2 --category 1000 --numof_point 100000
python param_search/ifs_search.py --rate=0.2 --category=1000 --numof_point=100000 --save_dir='./data'The structure of directories is constructed as follows.
./
data/
csv_rate20_category1000/
00000.csv
00001.csv
...
rate20_category1000/
00000.png
00001.png
...
param_search/
...
Run the code fractal_renderer/make_fractaldb.py to construct FractalDB.
python fractal_renderer/make_fractaldb.pyThe code includes the following parameters.
--load_root: Category root with CSV file. You can find in "./data".
--save_root: Create the directory of FractalDB.)
--image_size_x: x-coordinate image size
--image_size_y: y-coordinate image size
--pad_size_x: x-coordinate padding size
--pad_size_y: y-coordinate padding size
--iteration: #dot/#patch in a fractal image
--draw_type: Rendering type. You can select "{point, patch}_{gray, color}"
--weight_csv: Weight parameter. You can find "./fractal_renderer/weights"
--instance: #instance. 10 -> 1000 instances per category, 100 -> 10,000 instances per category')
The structure of rendered FractalDB is constructed as follows.
./
data/
FractalDB-1000/
00000/
00000_00_count_0_flip0.png
00000_00_count_0_flip1.png
00000_00_count_0_flip2.png
00000_00_count_0_flip3.png
...
00001/
00001_00_count_0_flip0.png
00001_00_count_0_flip1.png
00001_00_count_0_flip2.png
00001_00_count_0_flip3.png
...
...
Run the code pretraining/main.py to create a FractalDB pre-trained model.
python pretraining/main.py
Please confirm a FractalDB is existing in ./data directory. After the pre-training, a trained model is created like FractalDB-1000_resnet50_epoch90.pth and FractalDB-1000_resnet50_checkpoint.pth.tar. Moreover, you can resume the training from a checkpoint by assigning --resume parameter.
These are the important parameters in pre-training.
--dataset: model name
--path2traindb: path to FractalDB
--path2weight: path to trained weight
--resume: path to latest checkpoint
--usenet: CNN architecture
--epochs: end epoch
--numof_classes: number of pre-trained class
Pre-trained models Our pre-trained models are available in this [Link].
We have mainly prepared two different pre-trained models. These pre-trained models are trained on FractalDB in different categories (1k and 10k) and the same number of instances (1k).
FractalDB-1000_resnet50_epoch90.pth: --dataset=FractalDB-1000 --usenet=resnet50 --epochs=90 --numof_classes=1000
FractalDB-10000_resnet50_epoch90.pth: --dataset=FractalDB-10000 --usenet=resnet50 --epochs=90 --numof_classes=10000
If you would like to additionally train from the pre-trained model, you command with the next fine-tuning code as follows.
# FractalDB-1000_resnet50_epoch90.pth
python finetuning/main.py --path2db='/path/to/your/fine-tuning/data' --dataset='FractalDB-1000' --ft_dataset='YourDataset' --numof_pretrained_classes=1000 --usenet=resnet50
# FractalDB-10000_resnet50_epoch90.pth
python finetuning/main.py --path2db='/path/to/your/fine-tuning/data' --dataset='FractalDB-10000' --ft_dataset='YourDataset' --numof_pretrained_classes=10000 --usenet=resnet50
Run the code finetuning/main.py to additionally train any image datasets. However, in order to use the fine-tuning code, you must prepare a fine-tuning dataset (e.g., CIFAR-10/100, Pascal VOC 2012). Please look at Requirements for a dataset preparation and download option.
python finetuning/main.py --path2db='/path/to/your/fine-tuning/data' --ft_dataset='YourDataset'
These are the important parameters in fine-tuning.
--dataset: model name (pre-training dataset)
--ft_dataset: model name (fine-tuning dataset)
--path2db: path to fine-tuning dataset
--path2weight: path to trained weight
--resume: path to latest checkpoint
--useepoch: use epoch in pre-training model
--usenet: CNN architecture
--epochs: end epoch
--numof_pretrained_classes: num of pre-training class
--numof_classes: number of pre-trained class
Anyway, you must arrange the directories train and val under the fine-tuning dataset (or rewrite the phase in data loader DBLoader). The following dataset structure is also written in Requirements.
./
data/
CIFAR10/
train/
airplane/
0001.png
0002.png
...
...
val/
airplane/
0001.png
0002.png
...
...
The authors affiliated in National Institute of Advanced Industrial Science and Technology (AIST), Tokyo Denki University (TDU), and Tokyo Institute of Technology (TITech) are not responsible for the reproduction, duplication, copy, sale, trade, resell or exploitation for any commercial purposes, of any portion of the images and any portion of derived the data. In no event will we be also liable for any other damages resulting from this data or any derived data.