基于改进YOLOv8的皮肤黑色素瘤图像分割算法

doi:10.19678/j.issn.1000-3428.0069910

计算机工程 ›› 2026, Vol. 52 ›› Issue (3): 429-440. doi: 10.19678/j.issn.1000-3428.0069910

基于改进YOLOv8的皮肤黑色素瘤图像分割算法

顾群¹, 随思懿¹, 王瑞²^,*(), 张海¹, 许天鹏¹

1. 兰州理工大学计算机与通信学院, 甘肃兰州 730050
2. 上海建桥学院信息技术学院, 上海 201306

收稿日期:2024-05-23 修回日期:2024-08-22 出版日期:2026-03-15 发布日期:2024-11-05
通讯作者: 王瑞
作者简介:
顾群, 男, 副教授、博士, 主研方向为机器学习、复杂系统建模与控制、智能控制理论与应用
随思懿, 硕士
王瑞(通信作者), 副教授、硕士
张海, 硕士
许天鹏, 讲师、博士

Skin Melanoma Image Segmentation Algorithm Based on Improved YOLOv8

GU Qun¹, SUI Siyi¹, WANG Rui²^,*(), ZHANG Hai¹, XU Tianpeng¹

1. School of Computer and Communication, Lanzhou University of Technology, Lanzhou 730050, Gansu, China
2. College of Information Technology, Shanghai Jian Qiao University, Shanghai 201306, China

Received:2024-05-23 Revised:2024-08-22 Online:2026-03-15 Published:2024-11-05
Contact: WANG Rui

摘要/Abstract

摘要：

针对现有很多皮肤黑色素瘤图像分割算法因病灶区域形状多样、边缘模糊导致分割结果不精准的问题, 基于YOLOv8提出一种结合多尺度特征提取和边缘分割增强的皮肤黑色素瘤分割算法YOLOv8-Skin。首先, 将YOLOv8的主干网络CSPDarkNet53更换为更适合医学图像分割的U-Net v2网络, 使得在低级特征中注入丰富的语义信息, 同时精细化高级特征, 从而实现对皮肤黑色素瘤图像中对象边界的精确勾画和小结构的有效提取; 其次, 在颈部的C2f中引入可变形大核注意力(D-LKA)机制, 通过使用可变形卷积提升模型对于不规则图像结构信息的捕捉能力, 并利用大核卷积融合不同层次的特征; 最后, 在头部引入多样化分支块(DBB)形成新的分割头, 通过结合不同规模和复杂度的多样化分支增强单个卷积的表示能力, 从而增强模型对于病灶区域的特征提取。实验结果表明, YOLOv8-Skin的Dice系数、特异性、灵敏度、准确度在ISIC2017数据集上分别达到88.86%、91.34%、97.24%、96.29%, 在ISIC2018数据集上分别达到91.64%、95.42%、96.69%、95.83%, 在PH²数据集上分别达到95.92%、95.43%、97.02%、96.13%, 具有更强的分割性能, 能够更好地适用于皮肤黑色素瘤分割任务。

关键词: YOLOv8网络, 皮肤黑色素瘤分割, U-Net v2网络, 可变形大核注意力机制, 多样化分支块

Abstract:

This study proposes a skin melanoma segmentation algorithm, YOLOv8-Skin, designed to address the issue of imprecise results in existing algorithms caused by diverse shapes and blurred edges. YOLOv8-Skin combines multiscale feature extraction and enhanced edge segmentation based on YOLOv8. First, the backbone network CSPDarkNet53 of YOLOv8 is replaced with U-Net v2, which is more suitable for medical image segmentation. This change introduces rich semantic information into low-level features and refines high-level features, enabling precise delineation of lesion boundaries and effective extraction of small structures in melanoma images. Second, a Deformable-Large Kernel Attention (D-LKA) mechanism is introduced into the neck's C2f, enhancing the model's ability to capture irregular image structures through deformable convolutions and improving multilevel feature fusion using large kernel convolutions. Finally, a Diverse Branch Block (DBB) is incorporated into the head, forming a new segmentation head that enhances the representation capability of single convolutions by combining diverse branches of different scales and complexities. This enriches the feature space and improves feature extraction. Experiments conducted on the ISIC2017, ISIC2018, and PH² datasets verify the algorithm's effectiveness. On the ISIC2017 dataset, the Dice coefficient, Specificity, Sensitivity, and Accuracy reach 88.86%, 91.34%, 97.24%, and 96.29%, respectively. On the ISIC2018 dataset, they reach 91.64%, 95.42%, 96.69%, and 95.83%, respectively. On the PH² dataset, they reach 95.92%, 95.43%, 97.02%, and 96.13%, respectively. The algorithm demonstrates stronger segmentation performance and is better suited for melanoma segmentation tasks compared to existing methods.

Key words: YOLOv8 network, skin melanoma segmentation, U-Net v2 network, Deformable-Large Kernel Attention (D-LKA) mechanism, Diverse Branch Block (DBB)

顾群, 随思懿, 王瑞, 张海, 许天鹏. 基于改进YOLOv8的皮肤黑色素瘤图像分割算法[J]. 计算机工程, 2026, 52(3): 429-440.

GU Qun, SUI Siyi, WANG Rui, ZHANG Hai, XU Tianpeng. Skin Melanoma Image Segmentation Algorithm Based on Improved YOLOv8[J]. Computer Engineering, 2026, 52(3): 429-440.

https://www.ecice06.com/CN/Y2026/V52/I3/429

图/表 20

图1 YOLOv8结构

Fig.1 YOLOv8 structure

图2 Conv结构

Fig.2 Conv structure

图3 C2f结构

Fig.3 C2f structure

图4 SPPF结构

Fig.4 SPPF structure

图5 YOLOv8-Skin架构

Fig.5 YOLOv8-Skin architecture

图6 U-Net v2网络结构

Fig.6 U-Net v2 network structure

图7 D-LKA架构

Fig.7 D-LKA architecture

图8 DBB转换方法

Fig.8 DBB transform method

图9 DBB结构

Fig.9 DBB structure

图10 消融实验结果折线图

Fig.10 Line chart of ablation experimetnal results

图11 消融实验可视化对比

Fig.11 Visualization comparison of ablation experiments

图12 定性实验结果对比

Fig.12 Comparison of qualitative experimental results

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