Small-Sample Target Detection Across Domains Based on Supervision and Distillation

To address the issues of significant object discrepancies, low similarity, and image noise interference between source and target domains in object detection, we propose a supervised learning approach combined with knowledge distillation. Initially, student and teacher models are jointly trained thr...

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Veröffentlicht in:	Electronics (Basel) 2024-12, Vol.13 (24), p.4975
Hauptverfasser:	Sun, Fusheng, Jia, Jianli, Han, Xie, Kuang, Liqun, Han, Huiyan
Format:	Artikel
Sprache:	eng
Schlagworte:	Ablation Accuracy Adaptation Algorithms Artificial neural networks Datasets Design Feature extraction Machine learning Modules Noise control Object recognition Supervised learning Supervision Target detection Teachers Visual effects
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container_title	Electronics (Basel)
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creator	Sun, Fusheng Jia, Jianli Han, Xie Kuang, Liqun Han, Huiyan
description	To address the issues of significant object discrepancies, low similarity, and image noise interference between source and target domains in object detection, we propose a supervised learning approach combined with knowledge distillation. Initially, student and teacher models are jointly trained through supervised and distillation-based approaches, iteratively refining the inter-model weights to mitigate the issue of model overfitting. Secondly, a combined convolutional module is integrated into the feature extraction network of the student model, to minimize redundant computational effort; an explicit visual center module is embedded within the feature pyramid network, to bolster feature representation; and a spatial grouping enhancement module is incorporated into the region proposal network, to mitigate the adverse effects of noise on the outcomes. Ultimately, the model undergoes a comprehensive optimization process that leverages the loss functions originating from both the supervised and knowledge distillation phases. The experimental results demonstrate that this strategy significantly boosts classification and identification accuracy on cross-domain datasets; when compared to the TFA (Task-agnostic Fine-tuning and Adapter), CD-FSOD (Cross-Domain Few-Shot Object Detection) and DeFRCN (Decoupled Faster R-CNN for Few-Shot Object Detection), with sample orders of magnitude 1 and 5, increased the detection accuracy by 1.67% and 1.87%, respectively.
doi_str_mv	10.3390/electronics13244975
format	Article
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subjects	Ablation Accuracy Adaptation Algorithms Artificial neural networks Datasets Design Feature extraction Machine learning Modules Noise control Object recognition Supervised learning Supervision Target detection Teachers Visual effects
title	Small-Sample Target Detection Across Domains Based on Supervision and Distillation
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