FEM AND EVOLUTION STRATEGIES IN THE OPTIMAL-DESIGN OF ELECTROMAGNETIC DEVICES

In this paper the application of evolution strategies for the optimal design of electromagnetic devices is investigated. The corresponding field analysis Is performed by the finite element method. These strategies which are relatively new In electrical engineering involve a simplified simulation of biological evolution. They are especially advantageous in case of strongly nonlinear optimization problems. The three strategies used are the called (1+1), the (1, 6) and the (10.100) schemes. They are compared with the Gauss-Seidel method In the example of a dipole magnet to be optimized In order to obtain a homogeneous magnetic field under the pole. Both a two-dimensional and a three-dimensional model have been investigated with both linear and nonlinear material characteristics assumed. © 1990 IEEE