深度学习
人工神经网络
计算机科学
人工智能
线性规划
前馈神经网络
机器学习
分段线性函数
分段
功能(生物学)
透视图(图形)
代理(哲学)
理论计算机科学
多样性(控制论)
神经系统网络模型
代表(政治)
运筹学
线性模型
智能决策支持系统
工业工程
数据科学
反向传播
分段线性流形
自然语言
数学优化
循环神经网络
激活函数
软件工程
常量(计算机编程)
强化学习
算法
作者
Joey Huchette,Gonzalo Muñoz,Thiago Serra,Calvin Tsay
标识
DOI:10.1287/ijoc.2024.0902
摘要
In the past decade, deep learning became the prevalent methodology for predictive modeling thanks to the remarkable accuracy of deep neural networks in tasks such as computer vision and natural language processing. Meanwhile, the structure of neural networks converged back to simpler representations based on piecewise constant and piecewise linear functions such as the rectified linear unit (ReLU), which became the most commonly used type of activation function in neural networks. That made certain types of network structure—such as the typical fully connected feedforward neural network—amenable to analysis through polyhedral theory and to the application of methodologies such as linear programming and mixed-integer linear programming for a variety of purposes. In this paper, we survey the main topics emerging from this fast-paced area of work, which brings a fresh perspective to understanding neural networks in more detail as well as to applying linear optimization techniques to train, verify, and reduce the size of such networks. History: Accepted by Andrea Lodi, Area Editor of Design and Analysis of Algorithms—Discrete. Funding: T. Serra was supported by the National Science Foundation (NSF) Division of Information and Intelligent Systems [Grant IIS 2104583], C. Tsay was supported by the Engineering and Physical Sciences Research Council (EPSRC) [Grant EP/T001577/1]. G. Muñoz was supported by the Chilean Research and Development Agency (ANID) [Grant PIA/PUENTE AFB230002].
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