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Main Authors: Zhang, Rangya, Xiao, Jiaping, Bai, Lu, Zhang, Yuhang, Feroskhan, Mir
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.26190
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author Zhang, Rangya
Xiao, Jiaping
Bai, Lu
Zhang, Yuhang
Feroskhan, Mir
author_facet Zhang, Rangya
Xiao, Jiaping
Bai, Lu
Zhang, Yuhang
Feroskhan, Mir
contents Continual learning seeks to maintain stable adaptation under non-stationary environments, yet this problem becomes particularly challenging in object detection, where most existing methods implicitly assume relatively balanced visual conditions. In extreme-sparsity regimes, such as those observed in space-based resident space object (RSO) detection scenarios, foreground signals are overwhelmingly dominated by background observations. Under such conditions, we analytically demonstrate that background-driven gradients destabilize the feature backbone during sequential domain shifts, causing progressive representation drift. This exposes a structural limitation of continual learning approaches relying solely on output-level distillation, as they fail to preserve intermediate representation stability. To address this, we propose a dual-stage invariant continual learning framework via joint distillation, enforcing structural and semantic consistency on both backbone representations and detection predictions, respectively, thereby suppressing error propagation at its source while maintaining adaptability. Furthermore, to regulate gradient statistics under severe imbalance, we introduce a sparsity-aware data conditioning strategy combining patch-based sampling and distribution-aware augmentation. Experiments on a high-resolution space-based RSO detection dataset show consistent improvement over established continual object detection methods, achieving an absolute gain of +4.0 mAP under sequential domain shifts.
format Preprint
id arxiv_https___arxiv_org_abs_2603_26190
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Dual-Stage Invariant Continual Learning under Extreme Visual Sparsity
Zhang, Rangya
Xiao, Jiaping
Bai, Lu
Zhang, Yuhang
Feroskhan, Mir
Computer Vision and Pattern Recognition
Machine Learning
Continual learning seeks to maintain stable adaptation under non-stationary environments, yet this problem becomes particularly challenging in object detection, where most existing methods implicitly assume relatively balanced visual conditions. In extreme-sparsity regimes, such as those observed in space-based resident space object (RSO) detection scenarios, foreground signals are overwhelmingly dominated by background observations. Under such conditions, we analytically demonstrate that background-driven gradients destabilize the feature backbone during sequential domain shifts, causing progressive representation drift. This exposes a structural limitation of continual learning approaches relying solely on output-level distillation, as they fail to preserve intermediate representation stability. To address this, we propose a dual-stage invariant continual learning framework via joint distillation, enforcing structural and semantic consistency on both backbone representations and detection predictions, respectively, thereby suppressing error propagation at its source while maintaining adaptability. Furthermore, to regulate gradient statistics under severe imbalance, we introduce a sparsity-aware data conditioning strategy combining patch-based sampling and distribution-aware augmentation. Experiments on a high-resolution space-based RSO detection dataset show consistent improvement over established continual object detection methods, achieving an absolute gain of +4.0 mAP under sequential domain shifts.
title Dual-Stage Invariant Continual Learning under Extreme Visual Sparsity
topic Computer Vision and Pattern Recognition
Machine Learning
url https://arxiv.org/abs/2603.26190