最小边界框
计算机科学
比例(比率)
感受野
人工智能
跳跃式监视
遥感
融合
模式识别(心理学)
领域(数学)
回归
红外线的
传感器融合
统计
光学
数学
物理
地质学
语言学
哲学
量子力学
纯数学
图像(数学)
标识
DOI:10.1109/tgrs.2025.3564958
摘要
Single-frame infrared small target (SIRST) detection is crucial for both military and civilian applications, but remains challenging due to low resolution and small target sizes. Most existing methods model the detection task as a semantic segmentation task, which requires high-resolution feature maps and incurs significant computational costs. Moreover, manual annotations often struggle to achieve pixel-level precision, and the inherent ambiguity in the annotations can affect the training outcomes. This paper treats the SIRST detection task as a bounding box regression problem and proposes a novel target detection network architecture, named adaptive fusion bounding box regression network (ABRNet). Specifically, to address the challenges posed by complex and changeable backgrounds, we design an adaptive receptive field module. This module utilizes spatial selection masks to choose feature maps with varying receptive field sizes, thereby leveraging the unique prior knowledge inherent in different scenarios. In addition, we introduce a cross-scale feature encoding fusion structure to alleviate the network’s low tolerance to bounding box perturbations. The module fuses multi-scale local and global features to capture the fine details of small targets. By combining high-dimensional features with detailed features, it facilitates accurate bounding box regression, thereby improving detection performance. Additionally, we employ linear interval mapping to achieve dynamic balancing of hard samples. Experimental results on public datasets demonstrate ABRNet’s superiority over state-of-the-art methods.
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