Automating the Design of Multi-band Microstrip Antennas via Uniform Cross-Entropy Optimization

TL;DR

This paper introduces a novel Uniform Cross-Entropy optimization method for designing multi-band microstrip antennas efficiently, outperforming other Monte-Carlo techniques in speed and effectiveness, with open-source code provided.

Contribution

The paper presents the first application of Uniform Cross-Entropy optimization for antenna design, demonstrating improved performance and reduced computation time compared to existing methods.

Findings

UCE outperforms Gaussian Processes, Forest optimization, and random search.

UCE converges in approximately 16 minutes.

Open-source code is released for future research use.

Abstract

Automating the design of microstrip antennas has been an active area of research for the past decade. By leveraging machine learning techniques such as Genetic Algorithms (GAs) or, more recently, Deep Neural Networks (DNNs), a number of work have demonstrated the possibility of producing non-trivial antenna geometries that can be efficient in terms of area utilization or be used in complex multi-frequency-band scenarios. However, both GAs and DNNs are notoriously compute-expensive, often requiring hour-long run times in order to produce new antenna geometries. In this paper, we propose to explore the novel use of Cross-Entropy optimization as a Monte-Carlo sampling technique for optimizing the geometry of patch antennas given a target $S_{11}$ scattering parameter curve that a user wants to obtain. We compare our proposed Uniform Cross-Entropy (UCE) method against other popular Monte-Carlo optimization techniques such as Gaussian Processes, Forest optimization and baseline random search approaches. We demonstrate that the proposed UCE technique outperforms the competing methods while still having a reasonable compute complexity, taking around 16 minutes to converge. Finally, our code is released as open-source with the hope of being useful to future research.