基于YOLO-BSNM的复杂背景下交通标志识别实验设计OA
Experimental design of traffic sign detection and recognition in complex scenes based on YOLO-BSNM
针对自动驾驶场景中小尺度交通标志检测精度不足的问题,文章提出了一种基于YOLO v11n架构的改进检测算法YOLO-BSNM,引入了多维协同注意力机制、归一化Wasserstein距离损失函数、160×160像素高分辨率小目标检测头和双向特征金字塔网络特征融合模块,构建了面向复杂场景的优化检测框架.实验结果表明,改进后的 YOLO-BSNM 模型在自建数据集上取得了 81.7%的精确率(P)、75.4%的召回率(R)和 83.4%的 mAP50指标,较原始算法有显著提升.通过轻量化优化和树莓派 4B 平台移植的验证,模型参数量减少了 6.2×105 个,在保持实时检测帧率的同时,以更少的计算资源实现了检测精度与模型规模的平衡优化,有效达成了提升性能与控制参数量的双重目标.
[Objective]This study aims to address the critical challenges associated with recognizing small traffic signs in autonomous driving scenarios.These challenges are particularly pronounced in highly dynamic and visually cluttered environments and adverse meteorological conditions,as well as when the signs are far away.[Methods]To achieve enhanced recognition performance,this study adopted an improved systematic detection method based on the YOLO v11n architecture.In particular,an optimized framework,referred to as YOLO-BSNM,was constructed for complex scenarios by integrating multichannel attention(MCA)with a channel-height-width three-branch dynamic fusion mechanism,a normalized weighted loss(NWDLoss),a 160×160-pixel high-resolution small-object detection head,and a BiFPN feature fusion module.To enhance the discriminability of features of small objects,MCA employed a channel-height-width three-branch dynamic fusion mechanism.NWDLoss addressed the localization sensitivity issues of traditional IoU-based losses via probabilistic distribution matching.The small-object detection head incorporated a sampling-fusion-extraction layer to mitigate detail loss resulting from resolution decay in deep features.Finally,the BiFPN feature fusion module performed the weighted fusion of multiresolution feature maps to reduce the critical feature loss.[Results]The experimental results demonstrated that the improved YOLO-BSNM algorithm achieved a precision(P)of 81.7%,a recall(R)of 75.4%,and an mAP50 of 83.4%when using the custom dataset,indicating substantial advancements over the baseline algorithm.Concurrently,the model size was smaller by 0.62 million parameters through lightweight optimization,achieving higher detection accuracy with fewer computational resources.The results also indicated that the framework showed enhanced adaptability to challenging scenarios,such as environments with blurring and occlusions.The edge-device deployment capability of the algorithm offers a robust foundation for fulfilling the real-time detection needs of intelligent transportation systems.[Conclusions]This study successfully developed an efficient and accurate traffic sign identification technology based on the YOLO-BSNM model.This technology overcame the limitations of traditional recognition methods and showed improved efficiency and precision in recognizing traffic signs.It provides substantial support for advancing autonomous driving.Deployment and performance verification on an embedded Raspberry Pi 4B platform demonstrated that the optimized model achieved a good balance between architecture lightweightness and detection accuracy,effectively reducing the false alarm and missed detection rates.This advancement meets the objective of enhancing performance while minimizing parameter overhead.YOLO-BSNM accomplished simultaneous enhancements in micro-object feature discrimination and multiscale information integration through the optimized combination of an attention mechanism and a feature fusion strategy.The probabilistic distribution matching-based loss function enhanced the stability of bounding box regression.These technical innovations led to an efficient detection framework,providing a novel approach for detecting micro-objects in complex environments.The lightweight detection system represents a promising solution for deployment in resource-constrained scenarios,such as drone-based remote sensing and satellite image analysis.The integration of multimodal data from infrared sensors,LiDAR,and dynamic environment adaptation algorithms enables the model to overcome detection challenges under variable lighting and extreme weather conditions.This research provides a technical framework for autonomous driving applications and elicits new avenues for investigating universal micro-object detection solutions in computer vision.
宋军;储志韩;范梓灏;邹奔;焦万果
南京林业大学 信息科学技术学院/人工智能学院,江苏 南京 210037南京林业大学 信息科学技术学院/人工智能学院,江苏 南京 210037南京林业大学 信息科学技术学院/人工智能学院,江苏 南京 210037南京林业大学 信息科学技术学院/人工智能学院,江苏 南京 210037南京林业大学 信息科学技术学院/人工智能学院,江苏 南京 210037
信息技术与安全科学
深度学习YOLO交通标志识别树莓派注意力机制
deep learningYOLOtraffic sign recognitionRaspberry Piattention mechanism
《实验技术与管理》 2026 (2)
47-55,9
2024年南京林业大学研究生优质教学资源建设课题(164070020)国家自然科学基金(62261040)
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