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Main Authors: Aslam, Muhammad Haseeb, Martinez, Clara, Pedersoli, Marco, Koerich, Alessandro, Etemad, Ali, Granger, Eric
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.14307
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author Aslam, Muhammad Haseeb
Martinez, Clara
Pedersoli, Marco
Koerich, Alessandro
Etemad, Ali
Granger, Eric
author_facet Aslam, Muhammad Haseeb
Martinez, Clara
Pedersoli, Marco
Koerich, Alessandro
Etemad, Ali
Granger, Eric
contents Advances in self-distillation have shown that when knowledge is distilled from a teacher to a student using the same deep learning (DL) architecture, the student performance can surpass the teacher particularly when the network is overparameterized and the teacher is trained with early stopping. Alternatively, ensemble learning also improves performance, although training, storing, and deploying multiple models becomes impractical as the number of models grows. Even distilling an ensemble to a single student model or weight averaging methods first requires training of multiple teacher models and does not fully leverage the inherent stochasticity for generating and distilling diversity in DL models. These constraints are particularly prohibitive in resource-constrained or latency-sensitive applications such as wearable devices. This paper proposes to train only one model and generate multiple diverse teacher representations using distillation-time dropout. However, generating these representations stochastically leads to noisy representations that are misaligned with the learned task. To overcome this problem, a novel stochastic self-distillation (SSD) training strategy is introduced for filtering and weighting teacher representation to distill from task-relevant representations only, using student-guided knowledge distillation (SGKD). The student representation at each distillation step is used as authority to guide the distillation process. Experimental results on real-world affective computing, wearable/biosignal datasets from the UCR Archive, the HAR dataset, and image classification datasets show that the proposed SSD method can outperform state-of-the-art methods without increasing the model size at both training and testing time, and incurs negligible computational complexity compared to state-of-the-art ensemble learning and weight averaging methods.
format Preprint
id arxiv_https___arxiv_org_abs_2504_14307
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Learning from Stochastic Teacher Representations Using Student-Guided Knowledge Distillation
Aslam, Muhammad Haseeb
Martinez, Clara
Pedersoli, Marco
Koerich, Alessandro
Etemad, Ali
Granger, Eric
Machine Learning
Advances in self-distillation have shown that when knowledge is distilled from a teacher to a student using the same deep learning (DL) architecture, the student performance can surpass the teacher particularly when the network is overparameterized and the teacher is trained with early stopping. Alternatively, ensemble learning also improves performance, although training, storing, and deploying multiple models becomes impractical as the number of models grows. Even distilling an ensemble to a single student model or weight averaging methods first requires training of multiple teacher models and does not fully leverage the inherent stochasticity for generating and distilling diversity in DL models. These constraints are particularly prohibitive in resource-constrained or latency-sensitive applications such as wearable devices. This paper proposes to train only one model and generate multiple diverse teacher representations using distillation-time dropout. However, generating these representations stochastically leads to noisy representations that are misaligned with the learned task. To overcome this problem, a novel stochastic self-distillation (SSD) training strategy is introduced for filtering and weighting teacher representation to distill from task-relevant representations only, using student-guided knowledge distillation (SGKD). The student representation at each distillation step is used as authority to guide the distillation process. Experimental results on real-world affective computing, wearable/biosignal datasets from the UCR Archive, the HAR dataset, and image classification datasets show that the proposed SSD method can outperform state-of-the-art methods without increasing the model size at both training and testing time, and incurs negligible computational complexity compared to state-of-the-art ensemble learning and weight averaging methods.
title Learning from Stochastic Teacher Representations Using Student-Guided Knowledge Distillation
topic Machine Learning
url https://arxiv.org/abs/2504.14307