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Main Authors: Zhou, Zhiping, Xie, Xuchen, Qiu, Yiqiao, Lin, Run, Zheng, Weishi, Wang, Ruixuan
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.00430
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author Zhou, Zhiping
Xie, Xuchen
Qiu, Yiqiao
Lin, Run
Zheng, Weishi
Wang, Ruixuan
author_facet Zhou, Zhiping
Xie, Xuchen
Qiu, Yiqiao
Lin, Run
Zheng, Weishi
Wang, Ruixuan
contents This study focuses on incremental learning for image classification, exploring how to reduce catastrophic forgetting of all learned knowledge when access to old data is restricted. The challenge lies in balancing plasticity (learning new knowledge) and stability (retaining old knowledge). Based on whether the task identifier (task-ID) is available during testing, incremental learning is divided into task incremental learning (TIL) and class incremental learning (CIL). The TIL paradigm often uses multiple classifier heads, selecting the corresponding head based on the task-ID. Since the CIL paradigm cannot access task-ID, methods originally developed for TIL require explicit task-ID prediction to bridge this gap and enable their adaptation to the CIL paradigm. {In this study, a novel continual learning framework extends the TIL method for CIL by introducing out-of-distribution detection for task-ID prediction. Our framework utilizes task-specific Batch Normalization (BN) and task-specific classification heads to effectively adjust feature map distributions for each task, enhancing plasticity. With far fewer parameters than convolutional kernels, task-specific BN helps minimize parameter growth, preserving stability. Based on multiple task-specific classification heads, we introduce an ``unknow'' class for each head. During training, data from other tasks are mapped to this unknown class. During inference, the task-ID is predicted by selecting the classification head with the lowest probability assigned to the unknown class. Our method achieves state-of-the-art performance on two medical image datasets and two natural image datasets. The source code is available at https://github.com/z1968357787/mbn_ood_git_main.
format Preprint
id arxiv_https___arxiv_org_abs_2411_00430
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Class Incremental Learning with Task-Specific Batch Normalization and Out-of-Distribution Detection
Zhou, Zhiping
Xie, Xuchen
Qiu, Yiqiao
Lin, Run
Zheng, Weishi
Wang, Ruixuan
Machine Learning
Computer Vision and Pattern Recognition
F.2.2; I.2.7
This study focuses on incremental learning for image classification, exploring how to reduce catastrophic forgetting of all learned knowledge when access to old data is restricted. The challenge lies in balancing plasticity (learning new knowledge) and stability (retaining old knowledge). Based on whether the task identifier (task-ID) is available during testing, incremental learning is divided into task incremental learning (TIL) and class incremental learning (CIL). The TIL paradigm often uses multiple classifier heads, selecting the corresponding head based on the task-ID. Since the CIL paradigm cannot access task-ID, methods originally developed for TIL require explicit task-ID prediction to bridge this gap and enable their adaptation to the CIL paradigm. {In this study, a novel continual learning framework extends the TIL method for CIL by introducing out-of-distribution detection for task-ID prediction. Our framework utilizes task-specific Batch Normalization (BN) and task-specific classification heads to effectively adjust feature map distributions for each task, enhancing plasticity. With far fewer parameters than convolutional kernels, task-specific BN helps minimize parameter growth, preserving stability. Based on multiple task-specific classification heads, we introduce an ``unknow'' class for each head. During training, data from other tasks are mapped to this unknown class. During inference, the task-ID is predicted by selecting the classification head with the lowest probability assigned to the unknown class. Our method achieves state-of-the-art performance on two medical image datasets and two natural image datasets. The source code is available at https://github.com/z1968357787/mbn_ood_git_main.
title Class Incremental Learning with Task-Specific Batch Normalization and Out-of-Distribution Detection
topic Machine Learning
Computer Vision and Pattern Recognition
F.2.2; I.2.7
url https://arxiv.org/abs/2411.00430