Title :
Computationally Efficient Multi-Fidelity Bayesian Support Vector Regression Modeling of Planar Antenna Input Characteristics
Author :
Jacobs, J.P. ; Koziel, Slawomir ; Ogurtsov, Stanislav
Author_Institution :
Dept. of Electr., Electron. & Comput. Eng., Univ. of Pretoria, Pretoria, South Africa
Abstract :
Bayesian support vector regression (BSVR) modeling of planar antennas with reduced training sets for computational efficiency is presented. Coarse-discretization electromagnetic (EM) simulations are exploited in order to find a reduced number of fine-discretization training points for establishing a high-fidelity BSVR model of the antenna. As demonstrated using three planar antennas with different response types, the proposed technique allows substantial reduction (up to 48%) of the computational effort necessary to set up the fine-discretization training data sets for the high-fidelity models with negligible loss in predictive power. The accuracy of the reduced-data BSVR models is confirmed by their successful use within a space mapping optimization/design algorithm.
Keywords :
electrical engineering computing; optimisation; planar antennas; regression analysis; support vector machines; BSVR modeling; Bayesian support vector regression modeling; coarse-discretization electromagnetic simulations; computational efficiency; computationally efficient multifidelity; high-fidelity BSVR model; planar antennas; predictive power; reduced-data BSVR models; space mapping optimization-design algorithm; the fine-discretization training data sets; Antennas; Data models; Geometry; Optimization; Radio frequency; Training; Training data; Gaussian processes; microwave antennas; optimization; predictive models; support vector machines;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
DOI :
10.1109/TAP.2012.2220513
