Paced-Curriculum Distillation with Prediction and Label Uncertainty for
Image Segmentation
- URL: http://arxiv.org/abs/2302.01049v1
- Date: Thu, 2 Feb 2023 12:24:14 GMT
- Title: Paced-Curriculum Distillation with Prediction and Label Uncertainty for
Image Segmentation
- Authors: Mobarakol Islam and Lalithkumar Seenivasan and S. P. Sharan and V. K.
Viekash and Bhavesh Gupta and Ben Glocker and Hongliang Ren
- Abstract summary: In curriculum learning, the idea is to train on easier samples first and gradually increase the difficulty.
In self-paced learning, a pacing function defines the speed to adapt the training progress.
We develop a novel paced-curriculum distillation (PCD) for medical image segmentation.
- Score: 25.20877071896899
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Purpose: In curriculum learning, the idea is to train on easier samples first
and gradually increase the difficulty, while in self-paced learning, a pacing
function defines the speed to adapt the training progress. While both methods
heavily rely on the ability to score the difficulty of data samples, an optimal
scoring function is still under exploration. Methodology: Distillation is a
knowledge transfer approach where a teacher network guides a student network by
feeding a sequence of random samples. We argue that guiding student networks
with an efficient curriculum strategy can improve model generalization and
robustness. For this purpose, we design an uncertainty-based paced curriculum
learning in self distillation for medical image segmentation. We fuse the
prediction uncertainty and annotation boundary uncertainty to develop a novel
paced-curriculum distillation (PCD). We utilize the teacher model to obtain
prediction uncertainty and spatially varying label smoothing with Gaussian
kernel to generate segmentation boundary uncertainty from the annotation. We
also investigate the robustness of our method by applying various types and
severity of image perturbation and corruption. Results: The proposed technique
is validated on two medical datasets of breast ultrasound image segmentation
and robotassisted surgical scene segmentation and achieved significantly better
performance in terms of segmentation and robustness. Conclusion: P-CD improves
the performance and obtains better generalization and robustness over the
dataset shift. While curriculum learning requires extensive tuning of
hyper-parameters for pacing function, the level of performance improvement
suppresses this limitation.
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