This repository includes the necessary implementation to reproduce the experiments highlighted in the master thesis.
- [email protected] - 3.6
- [email protected]
- Keras
- numpy
- Nibabel
- Scipy
- dicom
- h5py
This example comprises the use of D3-ircad database that includes 20 CT volumes for patients. 15 out of 20 scans feature tumors in the liver. All axial slices are represented in DICOM format. This repository contains the necessary utility to translate the downloaded database to a consumable .h5 database.
Please consult the ircad website to learn more:
The provided code example assumes that the D3-ircad is located in the project root repository. Steps to reproduce:
1- Download 3Dircadb1.zip
from the ircad website and add it to the project root.
2- Execute the notebook 1- dircad-data-extractor.ipynb
to decompress and synthesize the data.
3- Execute the notebook 2- dataset-builder-dircad.ipynb
to build an .h5
dataset that contains all volumes.
The thesis proposes a self-training method that enables semi-supervised learning on liver segmentation. The technique makes use of an oracle that learns to assess the quality of segmentation. A supervised model computes masks to unsupervised data. The oracle discerns the masks with high prediction and includes them in the training data. The following image highlights the training workflow:
The first step consists of training an oracle using the annotated data (1 of the 20 labeled patients). Here is the following step in the provided example:
1- Execute the notebook 3- oracle-database-build.ipynb
to generate a training database for the oracle. We choose per default the CT scan 0
as the annotated data in the provided example.
2- Execute the notebook 4- training-oracle.ipynb
to train an oracle. The model is initialized with a pre-trained VGG-16 model on the ImageNet task (1000 categories).
In the first iteration of the self-training, the segmenter is trained on the annotated dataset solely. The segmenter computes liver segments for unannotated data (19 remaining CT scans). Each computed segmentation is evaluated by the oracle. If the oracle assesses that a mask for a given axial slice is of high quality (class 0
or 5
), then the mask will be added in its corresponding bucket. A sampling process is carried out to select a few samples from each bucket. At each iteration, the sampling compels the increase of the database size, hence adding new data at each iteration. These steps can be executed as follows:
1- Execute the notebook 5- init-ssl-database.ipynb
to initialize a separate database that contains the semi-supervised data.
2- Execute the notebook 6- self-training.ipynb
to train the segmenter with the annotated data and samples new annotated data. Re-execute the notebook to iterate further with self-training method.
For any type of query conserning this work, please contact the author per email: [email protected]
.