Deep Learning and Its Application to Function Approximation for MR in Medicine: An Overview.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2022-10-01 Epub Date: 2021-09-17 DOI:10.2463/mrms.rev.2021-0040
Hidenori Takeshima
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引用次数: 1

Abstract

This article presents an overview of deep learning (DL) and its applications to function approximation for MR in medicine. The aim of this article is to help readers develop various applications of DL. DL has made a large impact on the literature of many medical sciences, including MR. However, its technical details are not easily understandable for non-experts of machine learning (ML).The first part of this article presents an overview of DL and its related technologies, such as artificial intelligence (AI) and ML. AI is explained as a function that can receive many inputs and produce many outputs. ML is a process of fitting the function to training data. DL is a kind of ML, which uses a composite of many functions to approximate the function of interest. This composite function is called a deep neural network (DNN), and the functions composited into a DNN are called layers. This first part also covers the underlying technologies required for DL, such as loss functions, optimization, initialization, linear layers, non-linearities, normalization, recurrent neural networks, regularization, data augmentation, residual connections, autoencoders, generative adversarial networks, model and data sizes, and complex-valued neural networks.The second part of this article presents an overview of the applications of DL in MR and explains how functions represented as DNNs are applied to various applications, such as RF pulse, pulse sequence, reconstruction, motion correction, spectroscopy, parameter mapping, image synthesis, and segmentation.

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深度学习及其在医学磁共振函数逼近中的应用综述。
本文概述了深度学习(DL)及其在医学磁共振函数逼近中的应用。本文的目的是帮助读者开发DL的各种应用。DL对包括mr在内的许多医学科学的文献产生了很大的影响。然而,它的技术细节对于非机器学习(ML)专家来说并不容易理解。本文的第一部分概述了深度学习及其相关技术,如人工智能(AI)和ML。AI被解释为可以接收许多输入并产生许多输出的功能。机器学习是一个将函数拟合到训练数据的过程。深度学习是机器学习的一种,它使用许多函数的组合来近似感兴趣的函数。这个复合函数被称为深度神经网络(DNN),而组成深度神经网络的函数被称为层。第一部分还涵盖了深度学习所需的底层技术,如损失函数、优化、初始化、线性层、非线性、归一化、循环神经网络、正则化、数据增强、残差连接、自动编码器、生成对抗网络、模型和数据大小,以及复值神经网络。本文的第二部分概述了深度学习在MR中的应用,并解释了如何将表示为dnn的函数应用于各种应用,如射频脉冲、脉冲序列、重建、运动校正、光谱学、参数映射、图像合成和分割。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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