Enregistré dans:
Détails bibliographiques
Auteurs principaux: Xu, Shengkai, Kao, Hsiang Lun, Xu, Tianxiang, Zhang, Honghui, Wang, Junqiao, Ding, Runmeng, Liu, Guanyu, Shi, Tianyu, Yu, Zhenyu, Pan, Guofeng, Bi, Ziqian, Ouyang, Yuqi
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2512.12492
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866909964449087488
author Xu, Shengkai
Kao, Hsiang Lun
Xu, Tianxiang
Zhang, Honghui
Wang, Junqiao
Ding, Runmeng
Liu, Guanyu
Shi, Tianyu
Yu, Zhenyu
Pan, Guofeng
Bi, Ziqian
Ouyang, Yuqi
author_facet Xu, Shengkai
Kao, Hsiang Lun
Xu, Tianxiang
Zhang, Honghui
Wang, Junqiao
Ding, Runmeng
Liu, Guanyu
Shi, Tianyu
Yu, Zhenyu
Pan, Guofeng
Bi, Ziqian
Ouyang, Yuqi
contents Polyp detectors trained on clean datasets often underperform in real-world endoscopy, where illumination changes, motion blur, and occlusions degrade image quality. Existing approaches struggle with the domain gap between controlled laboratory conditions and clinical practice, where adverse imaging conditions are prevalent. In this work, we propose AdaptiveDetector, a novel two-stage detector-verifier framework comprising a YOLOv11 detector with a vision-language model (VLM) verifier. The detector adaptively adjusts per-frame confidence thresholds under VLM guidance, while the verifier is fine-tuned with Group Relative Policy Optimization (GRPO) using an asymmetric, cost-sensitive reward function specifically designed to discourage missed detections -- a critical clinical requirement. To enable realistic assessment under challenging conditions, we construct a comprehensive synthetic testbed by systematically degrading clean datasets with adverse conditions commonly encountered in clinical practice, providing a rigorous benchmark for zero-shot evaluation. Extensive zero-shot evaluation on synthetically degraded CVC-ClinicDB and Kvasir-SEG images demonstrates that our approach improves recall by 14 to 22 percentage points over YOLO alone, while precision remains within 0.7 points below to 1.7 points above the baseline. This combination of adaptive thresholding and cost-sensitive reinforcement learning achieves clinically aligned, open-world polyp detection with substantially fewer false negatives, thereby reducing the risk of missed precancerous polyps and improving patient outcomes.
format Preprint
id arxiv_https___arxiv_org_abs_2512_12492
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Adaptive Detector-Verifier Framework for Zero-Shot Polyp Detection in Open-World Settings
Xu, Shengkai
Kao, Hsiang Lun
Xu, Tianxiang
Zhang, Honghui
Wang, Junqiao
Ding, Runmeng
Liu, Guanyu
Shi, Tianyu
Yu, Zhenyu
Pan, Guofeng
Bi, Ziqian
Ouyang, Yuqi
Computer Vision and Pattern Recognition
Computation and Language
Polyp detectors trained on clean datasets often underperform in real-world endoscopy, where illumination changes, motion blur, and occlusions degrade image quality. Existing approaches struggle with the domain gap between controlled laboratory conditions and clinical practice, where adverse imaging conditions are prevalent. In this work, we propose AdaptiveDetector, a novel two-stage detector-verifier framework comprising a YOLOv11 detector with a vision-language model (VLM) verifier. The detector adaptively adjusts per-frame confidence thresholds under VLM guidance, while the verifier is fine-tuned with Group Relative Policy Optimization (GRPO) using an asymmetric, cost-sensitive reward function specifically designed to discourage missed detections -- a critical clinical requirement. To enable realistic assessment under challenging conditions, we construct a comprehensive synthetic testbed by systematically degrading clean datasets with adverse conditions commonly encountered in clinical practice, providing a rigorous benchmark for zero-shot evaluation. Extensive zero-shot evaluation on synthetically degraded CVC-ClinicDB and Kvasir-SEG images demonstrates that our approach improves recall by 14 to 22 percentage points over YOLO alone, while precision remains within 0.7 points below to 1.7 points above the baseline. This combination of adaptive thresholding and cost-sensitive reinforcement learning achieves clinically aligned, open-world polyp detection with substantially fewer false negatives, thereby reducing the risk of missed precancerous polyps and improving patient outcomes.
title Adaptive Detector-Verifier Framework for Zero-Shot Polyp Detection in Open-World Settings
topic Computer Vision and Pattern Recognition
Computation and Language
url https://arxiv.org/abs/2512.12492