Julia M H Noothout1, Nikolas Lessmann2, Matthijs C van Eede1, Louis D van Harten1, Ecem Sogancioglu2, Friso G Heslinga3, Mitko Veta3, Bram van Ginneken2, Ivana Išgum1,4,5,6. 1. Amsterdam University Medical Center, University of Amsterdam, Department of Biomedical Engineering and Physics, Amsterdam, The Netherlands. 2. Radboud University Medical Center, Department of Medical Imaging, Nijmegen, The Netherlands. 3. Eindhoven University of Technology, Department of Biomedical Engineering, Eindhoven, The Netherlands. 4. Amsterdam University Medical Center, University of Amsterdam, Department of Radiology and Nuclear Medicine, Amsterdam, The Netherlands. 5. Amsterdam University Medical Center, University of Amsterdam, Amsterdam Cardiovascular Sciences, Heart Failure & Arrhythmias, Amsterdam, The Netherlands. 6. University of Amsterdam, Informatics Institute, Amsterdam, The Netherlands.
Abstract
Purpose: Ensembles of convolutional neural networks (CNNs) often outperform a single CNN in medical image segmentation tasks, but inference is computationally more expensive and makes ensembles unattractive for some applications. We compared the performance of differently constructed ensembles with the performance of CNNs derived from these ensembles using knowledge distillation, a technique for reducing the footprint of large models such as ensembles. Approach: We investigated two different types of ensembles, namely, diverse ensembles of networks with three different architectures and two different loss-functions, and uniform ensembles of networks with the same architecture but initialized with different random seeds. For each ensemble, additionally, a single student network was trained to mimic the class probabilities predicted by the teacher model, the ensemble. We evaluated the performance of each network, the ensembles, and the corresponding distilled networks across three different publicly available datasets. These included chest computed tomography scans with four annotated organs of interest, brain magnetic resonance imaging (MRI) with six annotated brain structures, and cardiac cine-MRI with three annotated heart structures. Results: Both uniform and diverse ensembles obtained better results than any of the individual networks in the ensemble. Furthermore, applying knowledge distillation resulted in a single network that was smaller and faster without compromising performance compared with the ensemble it learned from. The distilled networks significantly outperformed the same network trained with reference segmentation instead of knowledge distillation. Conclusion: Knowledge distillation can compress segmentation ensembles of uniform or diverse composition into a single CNN while maintaining the performance of the ensemble.
Purpose: Ensembles of convolutional neural networks (CNNs) often outperform a single CNN in medical image segmentation tasks, but inference is computationally more expensive and makes ensembles unattractive for some applications. We compared the performance of differently constructed ensembles with the performance of CNNs derived from these ensembles using knowledge distillation, a technique for reducing the footprint of large models such as ensembles. Approach: We investigated two different types of ensembles, namely, diverse ensembles of networks with three different architectures and two different loss-functions, and uniform ensembles of networks with the same architecture but initialized with different random seeds. For each ensemble, additionally, a single student network was trained to mimic the class probabilities predicted by the teacher model, the ensemble. We evaluated the performance of each network, the ensembles, and the corresponding distilled networks across three different publicly available datasets. These included chest computed tomography scans with four annotated organs of interest, brain magnetic resonance imaging (MRI) with six annotated brain structures, and cardiac cine-MRI with three annotated heart structures. Results: Both uniform and diverse ensembles obtained better results than any of the individual networks in the ensemble. Furthermore, applying knowledge distillation resulted in a single network that was smaller and faster without compromising performance compared with the ensemble it learned from. The distilled networks significantly outperformed the same network trained with reference segmentation instead of knowledge distillation. Conclusion: Knowledge distillation can compress segmentation ensembles of uniform or diverse composition into a single CNN while maintaining the performance of the ensemble.
Authors: Hugo J Kuijf; J Matthijs Biesbroek; Jeroen De Bresser; Rutger Heinen; Simon Andermatt; Mariana Bento; Matt Berseth; Mikhail Belyaev; M Jorge Cardoso; Adria Casamitjana; D Louis Collins; Mahsa Dadar; Achilleas Georgiou; Mohsen Ghafoorian; Dakai Jin; April Khademi; Jesse Knight; Hongwei Li; Xavier Llado; Miguel Luna; Qaiser Mahmood; Richard McKinley; Alireza Mehrtash; Sebastien Ourselin; Bo-Yong Park; Hyunjin Park; Sang Hyun Park; Simon Pezold; Elodie Puybareau; Leticia Rittner; Carole H Sudre; Sergi Valverde; Veronica Vilaplana; Roland Wiest; Yongchao Xu; Ziyue Xu; Guodong Zeng; Jianguo Zhang; Guoyan Zheng; Christopher Chen; Wiesje van der Flier; Frederik Barkhof; Max A Viergever; Geert Jan Biessels Journal: IEEE Trans Med Imaging Date: 2019-03-19 Impact factor: 10.048
Authors: David Tellez; Maschenka Balkenhol; Irene Otte-Holler; Rob van de Loo; Rob Vogels; Peter Bult; Carla Wauters; Willem Vreuls; Suzanne Mol; Nico Karssemeijer; Geert Litjens; Jeroen van der Laak; Francesco Ciompi Journal: IEEE Trans Med Imaging Date: 2018-03-28 Impact factor: 10.048
Authors: Konstantinos Kamnitsas; Christian Ledig; Virginia F J Newcombe; Joanna P Simpson; Andrew D Kane; David K Menon; Daniel Rueckert; Ben Glocker Journal: Med Image Anal Date: 2016-10-29 Impact factor: 8.545