Underwater Acoustic Lens Design Using Topology Optimization

Structural and Multidisciplinary Optimization, 2017

Journal of Mechanical Science and Technology, 2016

JASA Express Letters

A broadband acoustic lens is designed based on the principle of reciprocity and gradient-based optimization. Acoustic reciprocity is used to define the pressure at the focal point due to a source located in a far-field and to relate the response by a configuration of scatterers for an incident plane wave. The pressure at the focal point is maximized by rearranging the scatterers and supplying the gradients of absolute pressure at the focal point with respect to scatterer positions. Numerical examples are given for clusters of cylindrical voids and sets of elastic thin shells in water.

The Proceedings of Mechanical Engineering Congress, Japan, 2012

Physical Review B, 2004

arXiv (Cornell University), 2004

Applied Physics Letters, 2010

In this paper a technique to design three dimensional (3D) devices to focus acoustic waves composed of scattering elements is proposed. The devices are designed and optimized in two dimensions (2D) with the help of a genetic algorithm and the 2D multiple scattering formalism. The transition from 2D to 3D is made by applying a rotation operation to the optimized design, thus passing from a set of 2D circular scatters to their equivalent 3D concentric rings of circular section and finite dimensions, considerably improving its performance. The method has been applied to the design and theoretical characterization of a single-focus acoustic lens and a tunable lens capable of changing the focal length with frequency. A prototype lens was fabricated using aluminum rings clamped to a rigid frame, obtaining a good agreement between theory and experiment.

Structural and Multidisciplinary Optimization, 2017

APPLIED PHYSICS LETTERS, 2018

2020 SoutheastCon, 2020