端到端原则
人工智能
计算机科学
目标检测
分类器(UML)
探测器
模式识别(心理学)
计算机视觉
特征提取
遥感
电信
地质学
作者
Shangdong Zheng,Zebin Wu,Yang Xu,Chengxun He,Zhihui Wei
标识
DOI:10.1109/tip.2025.3563708
摘要
Fine-grained object detection (FGOD) fundamentally comprises two primary tasks: object detection and fine-grained classification. In natural scenes, most FGOD methods benefit from higher instance resolution and fewer environmental variation, attributing more commonly associated with the latter task. In this paper, we propose a unified paradigm named Detector with Classifier2 (DC2), which provides a holistic paradigm by explicitly considering the end-to-end integration of object detection and fine-grained classification tasks, rather than prioritizing one aspect. Initially, our detection sub-network is restricted to only determining whether the proposal is a coarse-category and does not delve into the specific sub-categories. Moreover, in order to reduce redundant pixel-level calculation, we propose an instance-level feature enhancement (IFE) module to model the semantic similarities among proposals, which poses great potential for locating more instances in remote sensing images (RSIs). After obtaining the coarse detection predictions, we further construct a classification sub-network, which is built on top of the former branch to determine the specific sub-categories of the aforementioned predictions. Importantly, the detection network is performed on the complete image, while the classification network conducts secondary modeling for the detected regions. These operations can be denoted as the global contextual information and local intrinsic cues extractions for each instance. Therefore, we propose a multi-stream feature aggregation (MSFA) module to integrate global-stream semantic information and local-stream discriminative cues. Our whole DC2 network follows an end-to-end learning fashion, which effectively excavates the internal correlation between detection and fine-grained classification networks. We evaluate the performance of our DC2 network on two benchmarks SAT-MTB and HRSC2016 datasets. Importantly, our method achieves the new state-of-the-art results compared with recent works (approximately 7% mAP gains on SAT-MTB) and improves baseline by a significant margin (43.2% $v.s.~36.7$ %) without any complicated post-processing strategies. Source codes of the proposed methods are available at https://github.com/zhengshangdong/DC2.
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