Boan Ji, Huabin Wang, Mengxin Zhang, Borun Mao, Xuejun Li
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引用次数: 0
摘要
脑磁共振成像(MRI)被广泛用于阿尔茨海默病(AD)的分类。然而,3D图像的尺寸太大了。切片后的图像会丢失一些特征,从而导致网络大小和分类性能的冲突。本文利用变压器模型中的关键部件,提出了一种新的轻量化方法,保证了网络的轻量化,实现了高度精确的分类。首先,利用图像贴片输入来模拟变压器模型,增强特征感知;其次,利用变压器模型中常用的高斯误差线性单元(Gaussian error linear unit, GELU)来增强网络的泛化能力。最后,网络使用MRI切片作为学习数据。深度可分离卷积使网络更轻量化。在ADNI公共数据库上进行了实验。与正常对照(NC)相比,AD实验的准确率达到98.54%。网络参数数量为现有同类网络的1.3%。
An Efficient Lightweight Network Based on Magnetic Resonance Images for Predicting Alzheimer's Disease
Brain magnetic resonance images (MRI) are widely used for the classification of Alzheimer's disease (AD). The size of 3D images is, however, too large. Some of the sliced image features are lost, which results in conflicting network size and classification performance. This article uses key components in the transformer model to propose a new lightweight method, ensuring the lightness of the network and achieving highly accurate classification. First, the transformer model is imitated by using image patch input to enhance feature perception. Second, the Gaussian error linear unit (GELU), commonly used in transformer models, is used to enhance the generalization ability of the network. Finally, the network uses MRI slices as learning data. The depthwise separable convolution makes the network more lightweight. Experiments are carried out on the ADNI public database. The accuracy rate of AD vs. normal control (NC) experiments reaches 98.54%. The amount of network parameters is 1.3% of existing similar networks.
期刊介绍:
The International Journal on Semantic Web and Information Systems (IJSWIS) promotes a knowledge transfer channel where academics, practitioners, and researchers can discuss, analyze, criticize, synthesize, communicate, elaborate, and simplify the more-than-promising technology of the semantic Web in the context of information systems. The journal aims to establish value-adding knowledge transfer and personal development channels in three distinctive areas: academia, industry, and government.
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