Litcius/Paper detail

Programmable wave-based analog computing machine: a metastructure that designs metastructures

Dimitrios C. Tzarouchis, Brian Edwards, Nader Engheta

2025Nature Communications23 citationsDOIOpen Access PDF

Abstract

The ability to perform mathematical computations using metastructures is an emergent paradigm that carries the potential of wave-based analog computing to the realm of near-speed-of-light, low-loss, compact devices. We theoretically introduce and experimentally verify the concept of a reconfigurable metastructure that performs analog complex mathematical computations using electromagnetic waves. Reconfigurable, RF-based components endow our device with the ability to perform stationary and non-stationary iterative algorithms. After demonstrating matrix inversion (stationary problem), we use the machine to tackle two major non-stationary problems: root finding with Newton’s method and inverse design (constrained optimization) via the Lagrange multiplier method. The platform enables possible avenues for wave-based, analog computations for general linear algebraic problems and beyond in compact, ultrafast, and parallelized ways. This study introduces and validates a reconfigurable metastructure that uses electromagnetic waves to perform analog complex-valued mathematical computations. This device executes both stationary and non-stationary algorithms, such as matrix inversion and optimization.

Topics & Concepts

Computer scienceMaterials scienceNeural Networks and Reservoir ComputingPhotonic and Optical DevicesOptical Network Technologies