用于准确和可解释皮肤癌诊断的两阶段输入空间图像增强和可解释技术

IF 1.9 Q2 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS

Computation Pub Date : 2023-12-05 DOI:10.3390/computation11120246

Catur Supriyanto, Abu Salam, Junta Zeniarja, Adi Wijaya

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引用次数: 0

摘要

本研究论文提出了一种使用图像增强技术进行皮肤癌早期检测的深度学习方法。我们介绍了一种利用几何增强和生成对抗网络(GAN)的两阶段图像增强过程来区分皮肤癌类别。公共HAM10000数据集用于测试所提出的模型的工作效果。使用了各种预训练的卷积神经网络(CNN)模型，包括Xception、Inceptionv3、Resnet152v2、EfficientnetB7、InceptionresnetV2和VGG19。该方法的准确率为96.90%，精密度为97.07%，召回率为96.87%，f1分数为96.97%，优于其他先进的方法。本文还讨论了Shapley加法解释(SHAP)的使用，这是一种可解释的皮肤癌诊断技术，可以帮助临床医生理解诊断背后的原因，并提高对系统的信任。总的来说，所提出的方法提出了一种有前途的自动化皮肤癌检测方法，可以改善患者的治疗结果并降低医疗成本。

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Two-Stage Input-Space Image Augmentation and Interpretable Technique for Accurate and Explainable Skin Cancer Diagnosis

This research paper presents a deep-learning approach to early detection of skin cancer using image augmentation techniques. We introduce a two-stage image augmentation process utilizing geometric augmentation and a generative adversarial network (GAN) to differentiate skin cancer categories. The public HAM10000 dataset was used to test how well the proposed model worked. Various pre-trained convolutional neural network (CNN) models, including Xception, Inceptionv3, Resnet152v2, EfficientnetB7, InceptionresnetV2, and VGG19, were employed. Our approach demonstrates an accuracy of 96.90%, precision of 97.07%, recall of 96.87%, and F1-score of 96.97%, surpassing the performance of other state-of-the-art methods. The paper also discusses the use of Shapley Additive Explanations (SHAP), an interpretable technique for skin cancer diagnosis, which can help clinicians understand the reasoning behind the diagnosis and improve trust in the system. Overall, the proposed method presents a promising approach to automated skin cancer detection that could improve patient outcomes and reduce healthcare costs.

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来源期刊

Computation Mathematics-Applied Mathematics

CiteScore

3.50

自引率

4.50%

发文量

201

审稿时长

8 weeks

期刊介绍： Computation a journal of computational science and engineering. Topics: computational biology, including, but not limited to: bioinformatics mathematical modeling, simulation and prediction of nucleic acid (DNA/RNA) and protein sequences, structure and functions mathematical modeling of pathways and genetic interactions neuroscience computation including neural modeling, brain theory and neural networks computational chemistry, including, but not limited to: new theories and methodology including their applications in molecular dynamics computation of electronic structure density functional theory designing and characterization of materials with computation method computation in engineering, including, but not limited to: new theories, methodology and the application of computational fluid dynamics (CFD) optimisation techniques and/or application of optimisation to multidisciplinary systems system identification and reduced order modelling of engineering systems parallel algorithms and high performance computing in engineering.