Melanoma Detection using Convolutional Neural Network with Transfer Learning on Dermoscopic and Macroscopic Images

Jessica Millenia, M. F. Naufal, J. Siswantoro
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Abstract

Background: Melanoma is a skin cancer that starts when the melanocytes that produce the skin color pigment start to grow out of control and form a cancer. Detecting melanoma early before it spreads to the lymph nodes and other parts of the body is very important because it makes a big difference to the patient's 5-year life expectancy. Screening is the process of conducting a skin examination to suspect a mole is melanoma using dermoscopic or macroscopic images. However, manual screening takes a long time. Therefore, automatic melanoma detection is needed to speed up the melanoma detection process. The previous studies still have weakness because it has low precision or recall, which means the model cannot predict melanoma accurately. The distribution of melanoma and moles datasets is imbalanced where the number of melanomas is less than moles. In addition, in previous study, comparisons of several CNN transfer learning architectures have not been carried out on dermoscopic and macroscopic images. Objective: This study aims to detect melanoma using the Convolutional Neural Network (CNN) with transfer learning on dermoscopic and macroscopic melanoma images. CNN with Transfer learning is a popular method for classifying digital images with high accuracy. Methods: This study compares four CNN with transfer learning architectures, namely MobileNet, Xception, VGG16, and ResNet50 on dermoscopic and macroscopic image. This research also uses black-hat filtering and inpainting at the preprocessing stage to remove hair from the skin image. Results: MobileNet is the best model for classifying melanomas or moles in this experiment which has 83.86% of F1 score and 11 second of training time per epoch. Conclusion: MobileNet and Xception have high average F1 scores of 84.42% and 80.00%, so they can detect melanoma accurately even though the number of melanoma datasets is less than moles. Therefore, it can be concluded that MobileNet and Xception are suitable models for classifying melanomas and moles. However, MobileNet has the fastest training time per epoch which is 11 seconds. In the future, oversampling method can be implemented to balance the number of datasets to improve the performance of the classification model.
基于迁移学习的卷积神经网络在皮肤镜和宏观图像上检测黑色素瘤
背景:黑色素瘤是一种皮肤癌,当产生皮肤色素的黑色素细胞开始生长失控并形成癌症时就开始了。在黑色素瘤扩散到淋巴结和身体其他部位之前及早发现是非常重要的,因为这对患者的5年预期寿命有很大影响。筛查是使用皮肤镜或宏观图像进行皮肤检查以怀疑痣是黑色素瘤的过程。然而,人工筛选需要很长时间。因此,需要黑色素瘤自动检测来加快黑色素瘤的检测过程。先前的研究仍然有弱点,因为它的精度或召回率较低,这意味着该模型不能准确预测黑色素瘤。黑色素瘤和痣数据集的分布是不平衡的,黑色素瘤的数量少于痣。此外,在以往的研究中,几种CNN迁移学习架构并没有在皮肤镜和宏观图像上进行比较。目的:本研究旨在利用卷积神经网络(CNN)对皮肤镜和宏观黑色素瘤图像进行迁移学习检测。带有迁移学习的CNN是一种流行的数字图像分类方法,具有很高的准确率。方法:本研究将MobileNet、Xception、VGG16和ResNet50四种CNN迁移学习架构在皮肤镜和宏观图像上进行比较。本研究还在预处理阶段使用了黑帽滤波和上漆来去除皮肤图像中的毛发。结果:MobileNet是本实验中对黑色素瘤或痣进行分类的最佳模型,其F1得分为83.86%,每个epoch的训练时间为11秒。结论:MobileNet和Xception的平均F1得分分别为84.42%和80.00%,在黑色素瘤数据集数量少于痣的情况下也能准确检测出黑色素瘤。因此,MobileNet和Xception是比较适合黑色素瘤和痣分类的模型。然而,MobileNet的每个epoch的训练时间最快,为11秒。未来可以采用过采样的方法来平衡数据集的数量,以提高分类模型的性能。
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