arXiv:2602.09037v1 Announce Type: new
Abstract: We present a machine-learning-driven inverse design framework for systematically engineering three-dimensional microwave cavity resonators that support modes with nonzero electromagnetic helicity. In contrast to heuristic approaches to cavity design, helicity maximisation is formulated as a boundary-shape optimisation problem, enabling systematic exploration of complex boundary-shape parameter spaces and the identification of high-helicity designs that are difficult to predict using heuristic design rules alone. We applied this framework to several cavity families composed of smooth, edge-free components, including globally twisted cavities with control-point-defined cross-sections realised in both linear and ring configurations, cavities defined by the intersection of orthogonal prisms, sphere-subtracted cylindrical cavities, and parametrised surface resonators. Two gradient-free optimisation strategies, a genetic algorithm and Bayesian optimisation, were independently employed to explore compact sets of design parameters for these geometries and to optimise a scaled-helicity figure of merit for the dominant helical mode, evaluated via finite-element eigenmode analysis. Robustness to manufacturing tolerances was quantified by applying Gaussian geometric perturbations to the optimised cavities and evaluating statistical robustness metrics that penalise sensitivity to geometric variation.