Unsupervised Surrogate-Assisted Synthesis of Free-Form Planar Antenna Topologies for IoT Applications

TL;DR

This paper introduces an unsupervised, surrogate-assisted framework for automatically designing free-form planar antennas for IoT, reducing manual effort and bias while optimizing performance across multiple frequency bands.

Contribution

It proposes a novel variable-fidelity, surrogate-assisted approach for unsupervised antenna topology synthesis, integrating automatic generation, classification, and bi-stage tuning.

Findings

Successfully designed bandwidth-enhanced patch antennas for 5-7 GHz bands.

Demonstrated the effectiveness of the surrogate-assisted classifier in topology selection.

Extensive benchmarks validate the proposed framework's performance and generated antenna topologies.

Abstract

Design of antenna structures for Internet of Things (IoT) applications is a challenging problem. Contemporary radiators are often subject to a number of electric and/or radiation-related requirements, but also constraints imposed by specifics of IoT systems and/or intended operational environments. Conventional approaches to antenna design typically involve manual development of topology intertwined with its tuning. Although proved useful, the approach is prone to errors and engineering bias. Alternatively, geometries can be generated and optimized without supervision of the designer. The process can be controlled by suitable algorithms to determine and then adjust the antenna geometry according to the specifications. Unfortunately, automatic design of IoT radiators is associated with challenges such as determination of desirable geometries or high optimization cost. In this work, a variable-fidelity framework for performance-oriented development of free-form antennas represented using the generic simulation models is proposed. The method employs a surrogate-assisted classifier capable of identifying a suitable radiator topology from a set of automatically generated (and stored for potential re-use) candidate designs. The obtained geometry is then subject to a bi-stage tuning performed using a gradient-based optimization engine. The presented framework is demonstrated based on six numerical experiments concerning unsupervised development of bandwidth-enhanced patch antennas dedicated to work within 5 GHz to 6 GHz and 6 GHz to 7 GHz bands, respectively. Extensive benchmarks of the method, as well as the generated topologies are also performed.