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浙江大学学报(工学版)
浙江大学学报(工学版)  2026, Vol. 60 Issue (6): 1277-1288    DOI: 10.3785/j.issn.1008-973X.2026.06.015
计算机技术     
基于KAN与CKAN优化的医学图像分割模型
娄世猛1(),邵玉斌1,*(),杜庆治1,唐菁敏1,张赜涛2
1. 昆明理工大学 信息工程与自动化学院,云南 昆明 650500
2. 云南省媒体融合重点实验室,云南 昆明 650228
Medical image segmentation model based on KAN and CKAN optimization
Shimeng LOU1(),Yubin SHAO1,*(),Qingzhi DU1,Jingmin TANG1,Zetao ZHANG2
1. Faculty of Information Engineering and Automation, Kunming University of Science and Technology, Kunming 650500, China
2. Yunnan Province Key Laboratory for Media Integration, Kunming 650228, China
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摘要:

为了解决UNet模型在医学图像分割任务中的复杂特征提取与泛化能力不足的问题,提出基于Kolmogorov-Arnold网络(KAN)和卷积KAN(CKAN)的优化模型KUNet,增强UNet模型的性能. 通过用CKAN替换传统卷积层,引入KAN特征增强模块,优化跳跃连接,结合自适应基函数学习机制,在保留结构信息的同时提高特征提取的多样性与精度. 在4个不同的多模态数据集LiTS、CORN、DRIVE和Lungs上,与UNet基线模型、nnUNet模型和Swin-UNet模型进行对比实验. 结果表明,UNet基线模型与KUNet模型在4个数据集上Dice系数和IoU系数的平均最大性能差异指标(MAPG)分别为0.67990.6203,且KUNet模型相较于最优或次优模型在4个数据集上的平均提升指标为0.32130.2625. 利用KUNet模型,能够在短周期内有效提取到更多的特征,提升图像分割的准确度.
关键词: 图像分割UNetKolmogorov-Arnold network(KAN)卷积KAN(CKAN)最大性能差异指标(MAPG)    
Abstract:

An optimized model KUNet based on Kolmogorov-Arnold network (KAN) and convolutional KAN (CKAN) was proposed to enhance the performance of the UNet model in order to address the limitation of the UNet model in complex feature extraction and generalization capability for medical image segmentation task. Traditional convolutional layer was replaced with CKAN, KAN feature enhancement module was introduced, and skip connection was optimized. Then the diversity and accuracy of feature extraction were improved while preserving structural information by incorporating an adaptive basis function learning mechanism. Comparative experiments were conducted against the UNet baseline model, nnUNet model and Swin-UNet model on four different multimodal datasets: LiTS, CORN, DRIVE and Lungs. Results showed that the average maximum absolute performance gap (MAPG) between the UNet baseline model and the KUNet model across the four datasets were 0.679 9 and 0.620 3 for Dice coefficient and IoU coefficient, respectively, and the KUNet model achieved average improvement metrics of 0.3213 and 0.2625 compared with the optimal or suboptimal model across the four datasets. The KUNet model was utilized to effectively extract more feature within short training cycle and improve the accuracy of image segmentation.
Key words: image segmentation    UNet    Kolmogorov-Arnold network (KAN)    convolutional Kolmogorov-Arnold network (CKAN)    maximum absolute performance gap (MAPG)
收稿日期: 2025-06-28 出版日期: 2026-05-06
CLC:  TP 393  
基金资助: 云南省媒体融合重点实验室资助项目(220245203).
通讯作者: 邵玉斌     E-mail: 2962772160@qq.com;shaoyubin999@qq.com
作者简介: 娄世猛(2001—),男,硕士生,从事智能信息处理研究. orcid.org/0009-0002-3212-4318.E-mail:2962772160@qq.com
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引用本文:

娄世猛,邵玉斌,杜庆治,唐菁敏,张赜涛. 基于KAN与CKAN优化的医学图像分割模型[J]. 浙江大学学报(工学版), 2026, 60(6): 1277-1288.

Shimeng LOU,Yubin SHAO,Qingzhi DU,Jingmin TANG,Zetao ZHANG. Medical image segmentation model based on KAN and CKAN optimization. Journal of ZheJiang University (Engineering Science), 2026, 60(6): 1277-1288.

链接本文:

https://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2026.06.015        https://www.zjujournals.com/eng/CN/Y2026/V60/I6/1277

图 1  KUNet模型的架构图
图 2  CKAN网络模型的架构图
数据集样本数量分辨率分割目标
LiTS400512×512肝脏
CORN1238384×384角膜神经
DRIVE20565×584眼底血管
Lungs200512×512
表 1  数据集的统计表
图 3  在LiTS数据集上的可视化分割结果
图 4  在CORN数据集上的可视化分割结果
图 5  在DRIVE数据集上的可视化分割结果
图 6  在Lungs数据集上的可视化分割结果
图 7  UNet、KUNet、nnUNet、Swin-UNet模型在LiTS数据集上的性能曲线
图 8  UNet、KUNet、nnUNet、Swin-UNet模型在CORN数据集上的性能曲线
图 9  UNet、KUNet、nnUNet、Swin-UNet模型在DRIVE数据集上的性能曲线
图 10  UNet、KUNet、nnUNet、Swin-UNet模型在Lungs数据集上的性能曲线
数据集周期DiceMAPG1IoUMAPG2
UNet模型KUNet模型UNet模型KUNet模型
LiTS1000.97860.978600.95820.9582
CORN2000.06530.12640.06110.03390.06770.0338
DRIVE30000.71470.714700.55610.5561
Lungs1000.96510.965100.93320.9332
均值0.67990.6203
表 2  KUNet模型与UNet基线模型在各数据集上的最大性能差距
网络模型DiceIoU
LiTSCORNDRIVELungsLiTSCORNDRIVELungs
UNet0.98090.51330.81040.96090.96260.35310.68130.9248
nnUNet0.99170.32190.79810.97470.98370.20490.65210.9563
Swin-UNet0.98420.08150.68750.95710.96880.0430.52390.9177
KUNet0.99050.53020.93010.98420.98110.36810.86940.9689
$ \varDelta $0.13480.03530.92250.46230.14770.02350.83730.3369
$ \overline{\varDelta } $0.32130.2625
表 3  UNet、KUNet、nnUNet、SWin-UNet模型在各数据集上的最佳性能
数据集$ {E}_{\text{UNet}} $$ {E}_{\text{nnUNet}} $$ {E}_{\text{Swin-UNet}} $$ {E}_{\text{KUNet}} $$ {T}_{\text{UNet}} $/s$ {T}_{\text{nnUNet}} $/s$ {T}_{\text{Swin-UNet}} $/s$ {T}_{\text{KUNet}} $/s
LiTS100100100100557.114344544998.17
CORN20001002000200037674.0455071538057941.40
DRIVE500050005000100001630.206393216595458.41
Lungs10010010050262.875509383241.84
表 4  UNet、KUNet、nnUNet、Swin-UNet模型在各数据集上的计算效率
模型DiceIoU
完整KUNet0.99050.9811
变体A0.98860.9774
变体B0.99040.9810
变体C0.98250.9657
变体D0.98920.9786
表 5  不同模块配置下的消融实验结果比较
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