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逆基尼指数平均法:一种使用注意力集成定制ResNet变体的用于皮肤病变分类的多层次集成方法。

Inverse Gini indexed averaging: A multi-leveled ensemble approach for skin lesion classification using attention-integrated customized ResNet variants.

作者信息

Efat Anwar Hossain, Hasan Sm Mahedy, Uddin Md Palash, Emon Faysal Hossain

机构信息

Computer Science and Engineering Department, IUBAT - International University of Business Agriculture and Technology, Dhaka, Bangladesh.

Computer Science and Engineering Department, Rajshahi University of Engineering & Technology, Kazla, Rajshahi, Bangladesh.

出版信息

Digit Health. 2025 Jan 17;11:20552076241312936. doi: 10.1177/20552076241312936. eCollection 2025 Jan-Dec.

DOI:10.1177/20552076241312936
PMID:39839960
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11748089/
Abstract

OBJECTIVE

To improve the accuracy and explainability of skin lesion detection and classification, particularly for several types of skin cancers, through a novel approach based on the convolutional neural networks with attention-integrated customized ResNet variants (CRVs) and an optimized ensemble learning (EL) strategy.

METHODS

Our approach utilizes all ResNet variants combined with three attention mechanisms: channel attention, soft attention, and squeeze-excitation attention. These attention-integrated ResNet variants are aggregated through a unique multi-level EL strategy. We propose an innovative weight optimization method, inverse Gini indexed averaging (IGIA), which is further extended to multi-leveled IGIA (ML-IGIA) to determine the optimal weights for each model within multiple ensemble levels. For interpretability, we employ gradient class activation map to highlight the regions responsible for classification dominance, enhancing the model's transparency.

RESULTS

Our method was evaluated on the Human Against Machines 10000 dataset, achieving a superior accuracy of 94.52% with the ML-IGIA approach, outperforming existing methods.

CONCLUSIONS

The proposed CRV-based ensemble model with ML-IGIA demonstrates robust performance in skin lesion classification, offering both high accuracy and enhanced interpretability. This approach addresses the current research gap in effective weight optimization in EL and supports timely, automated skin disease detection.

摘要

目的

通过一种基于卷积神经网络的新颖方法,结合注意力集成的定制化残差网络变体(CRV)和优化的集成学习(EL)策略,提高皮肤病变检测和分类的准确性及可解释性,特别是针对几种类型的皮肤癌。

方法

我们的方法利用所有的残差网络变体,并结合三种注意力机制:通道注意力、软注意力和挤压激励注意力。这些集成了注意力的残差网络变体通过独特的多级EL策略进行聚合。我们提出了一种创新的权重优化方法,即逆基尼指数平均法(IGIA),并将其进一步扩展为多级IGIA(ML-IGIA),以确定多个集成级别中每个模型的最优权重。为了实现可解释性,我们采用梯度类激活映射来突出负责分类主导的区域,提高模型的透明度。

结果

我们的方法在“人机对抗10000”数据集上进行了评估,采用ML-IGIA方法实现了94.52%的卓越准确率,优于现有方法。

结论

所提出的基于CRV的集成模型与ML-IGIA在皮肤病变分类中表现出强大的性能,兼具高精度和更高的可解释性。这种方法解决了当前集成学习中有效权重优化方面的研究空白,并支持及时、自动化的皮肤疾病检测。

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