Research and Analysis of Algorithm for Detecting Surface Defects on Automotive Wheel Hubs Based on CCL-YOLOv8

doi:10.16182/j.issn1004731x.joss.25-0139

Abstract

Abstract:

To address the challenges such as low detection efficiency, difficulties in identifying small defects, and poor accuracy in detecting surface defects on automotive wheel hubs, a lightweight neural network called CCL-YOLOv8 was proposed based on an improved YOLOv8n architecture. A synergistic improvement in both detection accuracy and efficiency was achieved through a three-stage model optimization strategy. A convolutional attention fusion module was introduced, which integrated convolution operations with self-attention mechanisms, thereby enhancing the model's ability to capture local features of small defects while perceiving global context under low signal-to-noise ratio conditions. A C2f-Star module was constructed to reduce computational overhead and enhance feature expression by optimizing feature interaction through element-wise multiplication. A lightweight shared detail-enhanced convolution detection head was designed to reduce the number of parameters and computational requirements and ensure high-precision detection by combining shared convolution and differential convolution. Experimental results demonstrate that the CCL-YOLOv8 algorithm significant enhancements are achieved in detection accuracy, model lightweighting, and computational efficiency compared to existing algorithms. Consequently, this approach effectively addresses the technical challenges in detecting surface defects on automotive wheel hubs and provides an efficient, lightweight, and precise solution for industrial real-time detection.

Key words: automotive wheel hub, CCL-YOLOv8, defect detection, model lightweighting, attention mechanism

CLC Number:

TP391.9

Chen Yanjun, Zhou Min, Zha Meng, Zhang Meizhou. Research and Analysis of Algorithm for Detecting Surface Defects on Automotive Wheel Hubs Based on CCL-YOLOv8[J]. Journal of System Simulation, 2026, 38(3): 670-686.

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缺陷类型	形成原因	缺陷特征
点状缺陷	磕碰、划伤、麻点等	缺陷成点状凹坑
线状缺陷	因应力和温度造成的热裂纹、冷裂纹、拉裂、刀具振动裂纹等	缺陷呈细线条状，有明显的凹陷开裂边缘
孔状缺陷	气孔、缩孔、夹杂等	大小不等的圆孔洞、缩孔、凹陷等
面状缺陷	擦伤、划伤、麻面、拉毛等	成连续的面状缺陷，面积较大

实验组	CAFM	C2f-Star	LSDECD	mAP@0.5/%	mAP@0.5:0.95/%	P/%	R/%	参数量×10⁶	GFLOPs
T0				88.2	74.6	83.1	80.2	12.3	8.9
T1	√			90.3	77.9	87.2	84.5	13.6	10
T2		√		89.6	76.2	85.9	81.4	9.94	7.6
T3			√	88.7	74.3	84.5	82.2	10	6.6
T4	√	√		91.4	75.6	88.6	85.3	12.1	9.1
T5	√		√	89.4	76.6	85.4	81.6	9.22	4.2
T6		√	√	89.7	78.2	87.6	86.3	11.8	7.7
T7	√	√	√	93.2	78.9	90.1	88.5	10.3	5.7

模型	mAP@0.5/%	参数量×10⁶	GFLOPs	帧率/(帧/s)
YOLOv8n	88.2	12.30	8.9	213.4
Faster RCNN	67.3	137.10	370.2	16.3
SSD	64.2	26.30	62.7	24.6
YOLOv5n	81.8	1.90	4.5	373.1
YOLOv7-tiny	85.7	6.03	13.2	186.2
RT-DETR-R18	90.4	40.50	58.2	154.1
YOLOv9-tiny	90.1	1.90	6.5	169.0
CCL-YOLOv8	93.2	10.30	5.7	239.5