Skip to content

Latest commit

 

History

History
143 lines (122 loc) · 6.51 KB

README.md

File metadata and controls

143 lines (122 loc) · 6.51 KB

3DUnet-Tensorflow

Tumor Segmentation 1 Tumor Segmentation 2

3D Unet biomedical segmentation model powered by tensorpack with fast io speed.

Borrow a lot of codes from https://github.com/taigw/brats17/. I improved the pipeline and using tensorpack's dataflow for faster io speed. Currently it takes around 7 minutes for 500 iterations with patch size [5 X 20 X 144 X 144]. You can achieve reasonable results within 40 epochs (more gpu will also reduce your training time.)

I want to verify the effectiveness (consistent improvement despite of slight implementation differences and different deep-learning framework) of some architecture proposed these years. Such as dice_loss, generalised dice_loss, residual connection, instance norm, deep supervision ...etc. Those design are popular and used in many papers in BRATS competition.

Dependencies

DIR/
  training/
    HGG/
    LGG/
  val/
    BRATS*.nii.gz

Data

If you don't have Brats data, you can visit ellisdg/3DUnetCNN where he provided sample data from TCGA.

You can modify data_loader.py to apply for different 3D datasets. The data sampling strategy is defined in data_sampler.py BatchData class.

Usage

Change config in config.py:

  1. Change BASEDIR to /path/to/DIR as described above.

Train:

python3 train.py --logdir=./train_log/unet3d --gpu 0

Eval:

python3 train.py --load=./train_log/unet3d/model-30000 --gpu 0 --evaluate

Predict:

python3 train.py --load=./train_log/unet3d/model-30000 --gpu 0 --predict

If you want to use 5 fold cross validation :

  1. Run generate_5fold.py to save 5fold.pkl
  2. Set config CROSS_VALIDATION to True
  3. Set config CROSS_VALIDATION_PATH to {/path/to/5fold.pkl}
  4. Set config FOLD to {0~4}

Results

The detailed parameters and training settings. The results are derived from Brats2018 online evaluation on Validation Set.

Single Model

Setting 1:

Unet3d, num_filters=32 (all), depth=3, sampling=one_positive

  • PatchSize = [5, 20, 144, 144] per gpu, num_gpus = 2, epochs = 40
  • Lr = 0.01, num_step=500, epoch time = 6:35(min), total_training_time ~ 5 hours

Setting 2:

Unet3d, num_filters=32 (all), depth=3, sampling=one_positive

  • PatchSize = [2, 128, 128, 128] pre gpu, num_gpus = 2, epochs = 40
  • Lr = 0.01, num_step=500, epoch time = 20:35(min), total_training_time ~ 8 hours

Setting 3

Unet3d, num_filters=16~256, sampling=one_positive, depth=5, residual

  • PatchSize = [2, 128, 128, 128], num_gpus = 1, epochs = 20
  • Lr = 0.001, num_step=500, epoch time = 20(min), total_training_time ~ 8 hours

Setting 4:

Unet3d, num_filters=16~256, depth=5, residual InstanceNorm, sampling=random

  • PatchSize = [2, 128, 128, 128], num_gpus = 1, epochs = 20
  • Lr = 0.001, num_step=500, epoch time = 20(min), total_training_time ~ 8 hours

Setting 5:

Unet3d, num_filters=16~256, depth=5, residual, InstanceNorm, sampling=one_positive

  • PatchSize = [2, 128, 128, 128], num_gpus = 1, epochs = 20
  • Lr = 0.001, num_step=500, epoch time = 20(min), total_training_time ~ 8 hours

Setting 6:

Unet3d, num_filters=16~256, depth=5, residual, deep-supervision, InstanceNorm, sampling=one_positive

  • PatchSize = [2, 128, 128, 128], num_gpus = 1, epochs = 20
  • Lr = 0.001, epoch time = 19(min), total_training_time ~ 8 hours

Setting 7:

Unet3d, num_filters=16~256, depth=5, residual, deep-supervision, BatchNorm, sampling=one_positive

  • PatchSize = [2, 128, 128, 128], num_gpus = 1, epochs = 20
  • Lr = 0.001, epoch time = 20(min), total_training_time ~ 8 hours

Setting 8:

Unet3d, num_filters=16~256, depth=5, residual, deep-supervision, InstanceNorm, sampling=random

  • PatchSize = [2, 128, 128, 128], num_gpus = 2, epochs = 20
  • Lr = 0.001, epoch time = 22(min), total_training_time ~ 8 hours
Setting Dice_ET Dice_WT Dice_TC
1 0.74 0.85 0.75
2 0.74 0.83 0.77
2* 0.77 0.84 0.77
3 0.74 0.87 0.78
4 0.75 0.87 0.790
5 0.72 0.87 0.796
6 0.73 0.88 0.80
6* 0.75 0.88 0.80
7 0.73 0.87 0.78
8* 0.77 0.87 0.81

Ensemble Results

Multi-View:

Introduced by Automatic Brain Tumor Segmentation using Cascaded Anisotropic Convolutional Neural Networks. Trained with axial, sagittal and coronal and then average the prediction prob.

Currently only support manually set path for each model (see train.py after line 147.)

Test-Time augmentation:

Testing with image augmentation to improve model robustness.

  • Flip: Predicting on original image and horizontal flipped image and average the prediction prob.
Setting Dice_ET Dice_WT Dice_TC
8+Flip 0.73 0.88 0.81
8*+Flip 0.77 0.88 0.82
Multi-View* 0.78 0.89 0.81
Multi-View*+Flip 0.78 0.89 0.82

p.s. * means advanced post-processing

Preprocessing

Zero Mean Unit Variance (default)

Normalize each modality with zero mean and unit variance within brain region

Bias Correction

Details in Tustison, Nicholas J., et al. "N4ITK: improved N3 bias correction." IEEE transactions on medical imaging 29.6 (2010): 1310-1320.

Setting Dice_ET Dice_WT Dice_TC
N4+8*+Flip 0.76 0.87 0.80
Multi-View*+N4+Flip 0.76 0.89 0.80

Using preprocess.py to convert Brats data into corrected image. Will take one days to process 200+ files. (multi-threading could help)

Notes

Results for brats2018 will be updated and more experiments will be included. [2018/8/3]