Abstract
With rapid development of advanced manufacturing technologies and high demands for innovative lightweight constructions to mitigate the environmental and economic impacts, design optimization has attracted increasing attention in many engineering subjects, such as civil, structural, aerospace, automotive, and energy engineering. For nonconvex nonlinear constrained optimization problems with continuous variables, evaluations of the fitness and constraint functions by means of finite element simulations can be extremely expensive. To address this problem by algorithms with sufficient accuracy as well as less computational cost, an extended multipoint approximation method (EMAM) and an adaptive weighting-coefficient strategy are proposed to efficiently seek the optimum by the integration of metamodels with sequential quadratic programming (SQP). The developed EMAM stems from the principle of the polynomial approximation and assimilates the advantages of Taylor’s expansion for improving the suboptimal continuous solution. Results demonstrate the superiority of the proposed EMAM over other evolutionary algorithms (e.g., particle swarm optimization technique, firefly algorithm, genetic algorithm, metaheuristic methods, and other metamodeling techniques) in terms of the computational efficiency and accuracy by four well-established engineering problems. The developed EMAM reduces the number of simulations during the design phase and provides wealth of information for designers to effectively tailor the parameters for optimal solutions with computational efficiency in the simulation-based engineering optimization problems.
Highlights
Solving nonlinear optimization problems is a hot issue in design optimization of practical engineering systems
In order to obtain solutions with high computational accuracy in reasonable time, the hybrid optimization method has become increasingly popular for solving nonlinear optimization problems because it can reduce the computational burden during the analysis by replacing the complex physical systems with the mathematical models and improve the accuracy of the optimal solution with the use of the combined heuristic methods and mathematical programming techniques
To implement Taylor’s expansion metamodel into the framework of multipoint approximation method (MAM), the function of Euclidean distance for the determination of weighting coefficients during the process of approximations is replaced by a proposed strategy for adaptive selection of weighting coefficients. en, the sequential quadratic programming (SQP) technique is applied on the approximations to obtain the optimal solutions. e correctness of this enhanced extended MAM (EMAM) is validated by comparing with the results from several nonconvex benchmark problems [34, 35], which were successfully solved by researchers in use of the state-of-the-art algorithms, such as genetic algorithms (GAs) [36,37,38], evolution strategies (ESs) [39], particle swarm optimization (PSO) [40], charged system search (CSS) [41], colliding bodies optimization (CBO) [42], and firefly algorithm (FA) [43]
Summary
Solving nonlinear optimization problems is a hot issue in design optimization of practical engineering systems. Taking into account the above situations, MAM has been gradually developed and become one of the algorithms demonstrating good performance on efficiently solving mid-range constrained engineering optimization problems with the use of the combined heuristic methods and SQP technique. To implement Taylor’s expansion metamodel into the framework of MAM, the function of Euclidean distance for the determination of weighting coefficients during the process of approximations is replaced by a proposed strategy for adaptive selection of weighting coefficients. Based on response surface methodology [22], the multipoint approximation method (MAM) aims at constructing midrange approximations [4, 5] and is suitable to solve large-scale optimization problems by producing better-quality approximations that are sufficiently accurate in a current trust region and inexpensive in terms of computational costs required for their building. The above two-step metamodel building strategy leads to solving the linear system of NF equations with NF unknowns bl
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