Structural topology optimisation using simulated annealing with multiresolution design variables

The use of evolutionary algorithms for structural topology optimisation is said to be ineffective due to a considerably large number of topological design variables. However, such a problem can be alleviated by using additional numerical techniques. This paper presents the applications of simulated annealing (SA) for solving structural topology optimisation. The numerical technique termed multiresolution design variables (MRDV) is proposed as a numerical tool to enhance the searching performance of SA when dealing with topology optimisation. The approximate density distribution (ADD) and chromosome repairing techniques are employed to deal with checkerboard patterns and multiple disconnected areas on the structural topologies. The SA strategies using various sets of MRDV are implemented to solve a number of structural topology optimisation problems. The results obtained from the various optimisation strategies are illustrated and compared. The effect of using many resolutions of design variables on SAʹs searching performance is investigated. It is shown that the technique of MRDV is a powerful tool for the performance enhancement of SA when solving structural topology optimisation. The structural topologies obtained from employing the presented approach are comparable to those obtained from the classical gradient-based method.