Your search keyword '"Xu, Te"' showing total 2 results

1. Decomposition Is All You Need: Single-Objective to Multi-Objective Optimization towards Artificial General Intelligence.

Author

Xu, Wendi, Wang, Xianpeng, Guo, Qingxin, Song, Xiangman, Zhao, Ren, Zhao, Guodong, He, Dakuo, Xu, Te, Zhang, Ming, and Yang, Yang

Subjects

ARTIFICIAL intelligence, EVOLUTIONARY algorithms, FLOW shop scheduling, MATHEMATICAL programming, BEES algorithm, MATHEMATICAL decomposition, EVOLUTIONARY computation, PERMUTATIONS

Abstract

As a new abstract computational model in evolutionary transfer optimization (ETO), single-objective to multi-objective optimization (SMO) is conducted at the macroscopic level rather than the intermediate level for specific algorithms or the microscopic level for specific operators; this method aims to develop systems with a profound grasp of evolutionary dynamic and learning mechanism similar to human intelligence via a "decomposition" style (in the abstract of the well-known "Transformer" article "Attention is All You Need", they use "attention" instead). To the best of our knowledge, it is the first work of SMO for discrete cases because we extend our conference paper and inherit its originality status. In this paper, by implementing the abstract SMO in specialized memetic algorithms, key knowledge from single-objective problems/tasks to the multi-objective core problem/task can be transferred or "gathered" for permutation flow shop scheduling problems, which will reduce the notorious complexity in combinatorial spaces for multi-objective settings in a straight method; this is because single-objective tasks are easier to complete than their multi-objective versions. Extensive experimental studies and theoretical results on benchmarks (1) emphasize our decomposition root in mathematical programming, such as Lagrangian relaxation and column generation; (2) provide two "where to go" strategies for both SMO and ETO; and (3) contribute to the mission of building safe and beneficial artificial general intelligence for manufacturing via evolutionary computation. [ABSTRACT FROM AUTHOR]

Published

2023

2. Gathering Strength, Gathering Storms: Knowledge Transfer via Selection for VRPTW.

Author

Xu, Wendi, Wang, Xianpeng, Guo, Qingxin, Song, Xiangman, Zhao, Ren, Zhao, Guodong, Yang, Yang, Xu, Te, and He, Dakuo

Subjects

STORMS, VEHICLE routing problem, KNOWLEDGE transfer, APPLICATION stores, GENETIC algorithms, DATA mining, MACHINE learning

Abstract

Recently, due to the growth in machine learning and data mining, for scheduling applications in China's industrial intelligence, we are quite fortunate to witness a paradigm of evolutionary scheduling via learning, which includes a new tool of evolutionary transfer optimization (ETO). As a new subset in ETO, single-objective to multi-objective/many-objective optimization (SMO) acts as a powerful, abstract and general framework with wide industrial applications like shop scheduling and vehicle routing. In this paper, we focus on the general mechanism of selection that selects or gathers elite and high potential solutions towards gathering/transferring strength from single-objective problems, or gathering/transferring storms of knowledge from solved tasks. Extensive studies in vehicle routing problems with time windows (VRPTW) on well-studied benchmarks validate the great universality of the SMO framework. Our investigations (1) contribute to a deep understanding of SMO, (2) enrich the classical and fundamental theory of building blocks for genetic algorithms and memetic algorithms, and (3) provide a completive and potential solution for VRPTW. [ABSTRACT FROM AUTHOR]

Published

2022