TY - GEN
T1 - Representation Disentanglement for Multi-task Learning with Application to Fetal Ultrasound
AU - Meng, Qingjie
AU - Pawlowski, Nick
AU - Rueckert, Daniel
AU - Kainz, Bernhard
PY - 2019/10/8
Y1 - 2019/10/8
N2 - One of the biggest challenges for deep learning algorithms in medical image analysis is the indiscriminate mixing of image properties, e.g. artifacts and anatomy. These entangled image properties lead to a semantically redundant feature encoding for the relevant task and thus lead to poor generalization of deep learning algorithms. In this paper we propose a novel representation disentanglement method to extract semantically meaningful and generalizable features for different tasks within a multi-task learning framework. Deep neural networks are utilized to ensure that the encoded features are maximally informative with respect to relevant tasks, while an adversarial regularization encourages these features to be disentangled and minimally informative about irrelevant tasks. We aim to use the disentangled representations to generalize the applicability of deep neural networks. We demonstrate the advantages of the proposed method on synthetic data as well as fetal ultrasound images. Our experiments illustrate that our method is capable of learning disentangled internal representations. It outperforms baseline methods in multiple tasks, especially on images with new properties, e.g. previously unseen artifacts in fetal ultrasound.
AB - One of the biggest challenges for deep learning algorithms in medical image analysis is the indiscriminate mixing of image properties, e.g. artifacts and anatomy. These entangled image properties lead to a semantically redundant feature encoding for the relevant task and thus lead to poor generalization of deep learning algorithms. In this paper we propose a novel representation disentanglement method to extract semantically meaningful and generalizable features for different tasks within a multi-task learning framework. Deep neural networks are utilized to ensure that the encoded features are maximally informative with respect to relevant tasks, while an adversarial regularization encourages these features to be disentangled and minimally informative about irrelevant tasks. We aim to use the disentangled representations to generalize the applicability of deep neural networks. We demonstrate the advantages of the proposed method on synthetic data as well as fetal ultrasound images. Our experiments illustrate that our method is capable of learning disentangled internal representations. It outperforms baseline methods in multiple tasks, especially on images with new properties, e.g. previously unseen artifacts in fetal ultrasound.
U2 - 10.1007/978-3-030-32875-7_6
DO - 10.1007/978-3-030-32875-7_6
M3 - Conference contribution
SN - 9783030328740
T3 - Lecture Notes in Computer Science
SP - 47
EP - 55
BT - Smart Ultrasound Imaging and Perinatal, Preterm and Paediatric Image Analysis
PB - Springer
T2 - First International Workshop, SUSI 2019 and 4th International Workshop, PIPPI 2019
Y2 - 13 October 2019 through 17 September 2023
ER -