The code for our paper U^2-Net (U square net) published in Pattern Recognition 2020:
Xuebin Qin,
Zichen Zhang,
Chenyang Huang,
Masood Dehghan,
Osmar R. Zaiane and
Martin Jagersand.
Contact: xuebin[at]ualberta[dot]ca
(2020-Nov-21) Recently, we found an interesting application of U^2-Net for human portrait drawing. Therefore, we trained another model for this task based on the APDrawingGAN dataset.
- Clone this repo to local
git clone https://github.com/NathanUA/U-2-Net.git
-
Download the u2net_portrait.pth model and put it into the directory:
./saved_models/u2net_portrait/
. -
Run on the testing set.
(1) Download the train and test set from APDrawingGAN. These images and their ground truth are stitched side-by-side (512x1024). You need to split each of these images into two 512x512 images and put them into./test_data/test_portrait_images/portrait_im/
. You can also download the split testing set on GoogleDrive.
(2) Running the inference with commandpython u2net_portrait_test.py
will ouptut the results into./test_data/test_portrait_images/portrait_results
. -
Run on your own dataset.
(1) Prepare your images and put them into./test_data/test_portrait_images/your_portrait_im/
. To obtain enough details of the protrait, human head region in the input image should be close to or larger than 512x512. The head background should be relatively clear.
(2) Run the prediction by commandpython u2net_portrait_demo.py
will outputs the results to./test_data/test_portrait_images/your_portrait_results/
.
(3) The difference betweenpython u2net_portrait_demo.py
andpython u2net_portrait_test.py
is that we added a simple face detection step before the portrait generation inu2net_portrait_demo.py
. Because the testing set of APDrawingGAN are normalized and cropped to 512x512 for including only heads of humans, while our own dataset may varies with different resolutions and contents. Therefore, the codepython u2net_portrait_demo.py
will detect the biggest face from the given image and then crop, pad and resize the ROI to 512x512 for feeding to the network. The following figure shows how to take your own photos for generating high quality portraits.
(2020-Sep-13) Our U^2-Net based model is the 6th in MICCAI 2020 Thyroid Nodule Segmentation Challenge.
(2020-May-18) The official paper of our U^2-Net (U square net) (PDF in elsevier(free until July 5 2020), PDF in arxiv) is now available. If you are not able to access that, please feel free to drop me an email.
(2020-May-16) We fixed the upsampling issue of the network. Now, the model should be able to handle arbitrary input size. (Tips: This modification is to facilitate the retraining of U^2-Net on your own datasets. When using our pre-trained model on SOD datasets, please keep the input size as 320x320 to guarantee the performance.)
(2020-May-16) We highly appreciate Cyril Diagne for building this fantastic AR project: AR Copy and Paste using our U^2-Net (Qin et al, PR 2020) and BASNet(Qin et al, CVPR 2019). The demo video in twitter has achieved over 5M views, which is phenomenal and shows us more application possibilities of SOD.
Our previous work: BASNet (CVPR 2019)
Python 3.6
numpy 1.15.2
scikit-image 0.14.0
python-opencv
PIL 5.2.0
PyTorch 0.4.0
torchvision 0.2.1
glob
- Clone this repo
git clone https://github.com/NathanUA/U-2-Net.git
-
Download the pre-trained model u2net.pth (176.3 MB) or u2netp.pth (4.7 MB) and put it into the dirctory './saved_models/u2net/' and './saved_models/u2netp/'
-
Cd to the directory 'U-2-Net', run the train or inference process by command:
python u2net_train.py
orpython u2net_test.py
respectively. The 'model_name' in both files can be changed to 'u2net' or 'u2netp' for using different models.
We also provide the predicted saliency maps (u2net results,u2netp results) for datasets SOD, ECSSD, DUT-OMRON, PASCAL-S, HKU-IS and DUTS-TE.
@InProceedings{Qin_2020_PR,
title = {U2-Net: Going Deeper with Nested U-Structure for Salient Object Detection},
author = {Qin, Xuebin and Zhang, Zichen and Huang, Chenyang and Dehghan, Masood and Zaiane, Osmar and Jagersand, Martin},
journal = {Pattern Recognition},
volume = {106},
pages = {107404},
year = {2020}
}