Intelligent Optimization based on Machine Learning: State of Art and Perspectives (A Survey)

TAURIDA JOURNAL OF COMPUTER SCIENCE THEORY AND MATHEMATICS Pub Date : 1900-01-01 DOI:10.37279/1729-3901-2020-19-1-32-63

V. Donskoy

{"title":"Intelligent Optimization based on Machine Learning: State of Art and Perspectives (A Survey)","authors":"V. Donskoy","doi":"10.37279/1729-3901-2020-19-1-32-63","DOIUrl":null,"url":null,"abstract":"This survey focuses on the following problem: it is necessary, observing the behaviour of the object, automatically figure out how to improve (optimize) the quality of his functioning and to identify constraints to the improvement of this quality. In other words, build the objective function (or set of objective functions in multiobjective case) and constraints - i.e. the mathematical model of optimization - by mean machine learning. We present the main developed to date methods and algorithms that enable the automatic construction of mathematical models of planning and management objects by the use of arrays of precedents. The construction of empirical optimization models by reliable case information allows us to obtain an objective control model that reflects real-world processes. This is their main advantage compared to the traditional, subjective approach to the construction of control models. Relevant to the task a set of mathematical methods and information technologies called ``Extraction optimization models from data'', ``BOMD: Building Optimization Models from Data'', ``Building Models from Data'', ``The LION Way: Learning plus Intelligent Optimization'', ``Data-Driven Optimization''. The incompleteness of information and uncertainty are understood in different ways. Significantly different are the problem settings - deterministic, stochastic, parametric, mixed. Therefore, the consideration of a wider range of tasks leads to a variety of (primarily statistical) and other formulations of the problem and interpretations of uncertainty and incompleteness of initial information. The survey contains the following sections:\nEmpirical synthetic of pseudoBoolean models;\nEmpirical linear models with real variables;\nEmpirical neural network optimization models;\nIterative models;\nModels, including statistical statements;\nProblems, associated with the lack of the training set of points not belonging to the region of feasible solutions.","PeriodicalId":246257,"journal":{"name":"TAURIDA JOURNAL OF COMPUTER SCIENCE THEORY AND MATHEMATICS","volume":"30 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"1900-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"TAURIDA JOURNAL OF COMPUTER SCIENCE THEORY AND MATHEMATICS","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.37279/1729-3901-2020-19-1-32-63","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 0

Abstract

This survey focuses on the following problem: it is necessary, observing the behaviour of the object, automatically figure out how to improve (optimize) the quality of his functioning and to identify constraints to the improvement of this quality. In other words, build the objective function (or set of objective functions in multiobjective case) and constraints - i.e. the mathematical model of optimization - by mean machine learning. We present the main developed to date methods and algorithms that enable the automatic construction of mathematical models of planning and management objects by the use of arrays of precedents. The construction of empirical optimization models by reliable case information allows us to obtain an objective control model that reflects real-world processes. This is their main advantage compared to the traditional, subjective approach to the construction of control models. Relevant to the task a set of mathematical methods and information technologies called ``Extraction optimization models from data'', ``BOMD: Building Optimization Models from Data'', ``Building Models from Data'', ``The LION Way: Learning plus Intelligent Optimization'', ``Data-Driven Optimization''. The incompleteness of information and uncertainty are understood in different ways. Significantly different are the problem settings - deterministic, stochastic, parametric, mixed. Therefore, the consideration of a wider range of tasks leads to a variety of (primarily statistical) and other formulations of the problem and interpretations of uncertainty and incompleteness of initial information. The survey contains the following sections: Empirical synthetic of pseudoBoolean models; Empirical linear models with real variables; Empirical neural network optimization models; Iterative models; Models, including statistical statements; Problems, associated with the lack of the training set of points not belonging to the region of feasible solutions.

查看原文本刊更多论文

基于机器学习的智能优化:现状与展望(综述)

这项调查主要关注以下问题:是否有必要观察对象的行为，自动找出如何改进(优化)其功能的质量，并确定改进这种质量的约束。换句话说，通过平均机器学习构建目标函数(或多目标情况下的目标函数集)和约束-即优化的数学模型。我们介绍了迄今为止开发的主要方法和算法，这些方法和算法可以通过使用先例数组来自动构建规划和管理对象的数学模型。通过可靠的案例信息构建经验优化模型，可以得到反映现实过程的客观控制模型。与传统的、主观的方法构建控制模型相比，这是它们的主要优势。与任务相关的一套数学方法和信息技术称为“从数据中提取优化模型”、“BOMD:从数据中构建优化模型”、“从数据中构建模型”、“LION方式:学习加智能优化”、“数据驱动优化”。信息的不完全性和不确定性有不同的理解方式。显著不同的是问题设置——确定性的、随机的、参数化的、混合的。因此，考虑到更广泛的任务范围会导致问题的各种(主要是统计)和其他形式以及对初始信息的不确定性和不完整性的解释。调查内容包括以下几个部分:伪布尔模型的经验合成;带实变量的经验线性模型;经验神经网络优化模型;迭代模型;包括统计语句在内的模型;与缺乏不属于可行解区域的训练集相关的问题。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

TAURIDA JOURNAL OF COMPUTER SCIENCE THEORY AND MATHEMATICS

自引率

0.00%

发文量