Analogue computing with metamaterials

Despite their widespread use for performing advanced computational tasks, digital signal processors suffer from several restrictions, including low speed, high power consumption and complexity, caused by costly analogue-to-digital converters. For this reason, there has recently been a surge of inter...

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Veröffentlicht in:	Nature reviews. Materials 2021-03, Vol.6 (3), p.207-225
Hauptverfasser:	Zangeneh-Nejad, Farzad, Sounas, Dimitrios L., Alù, Andrea, Fleury, Romain
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Schlagworte:	639/166/987 639/624/399/1015 Analog to digital conversion Analog to digital converters Biomaterials Chemistry and Materials Science Complexity Computation Condensed Matter Physics Differential equations Digital signal processors Edge detection Image processing Light speed Low speed Machine learning Materials Science Metamaterials Nanotechnology Optical and Electronic Materials Optical communication Parallel operation Power consumption Review Article Signal processing Wave packets Wave propagation
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description	Despite their widespread use for performing advanced computational tasks, digital signal processors suffer from several restrictions, including low speed, high power consumption and complexity, caused by costly analogue-to-digital converters. For this reason, there has recently been a surge of interest in performing wave-based analogue computations that avoid analogue-to-digital conversion and allow massively parallel operation. In particular, novel schemes for wave-based analogue computing have been proposed based on artificially engineered photonic structures, that is, metamaterials. Such kinds of computing systems, referred to as computational metamaterials, can be as fast as the speed of light and as small as its wavelength, yet, impart complex mathematical operations on an incoming wave packet or even provide solutions to integro-differential equations. These much-sought features promise to enable a new generation of ultra-fast, compact and efficient processing and computing hardware based on light-wave propagation. In this Review, we discuss recent advances in the field of computational metamaterials, surveying the state-of-the-art metastructures proposed to perform analogue computation. We further describe some of the most exciting applications suggested for these computing systems, including image processing, edge detection, equation solving and machine learning. Finally, we provide an outlook for the possible directions and the key problems for future research. Metamaterials provide a platform to leverage optical signals for performing specific-purpose computational tasks with ultra-fast speeds. This Review surveys the basic principles, recent advances and promising future directions for wave-based-metamaterial analogue computing systems.
doi_str_mv	10.1038/s41578-020-00243-2
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subjects	639/166/987 639/624/399/1015 Analog to digital conversion Analog to digital converters Biomaterials Chemistry and Materials Science Complexity Computation Condensed Matter Physics Differential equations Digital signal processors Edge detection Image processing Light speed Low speed Machine learning Materials Science Metamaterials Nanotechnology Optical and Electronic Materials Optical communication Parallel operation Power consumption Review Article Signal processing Wave packets Wave propagation
title	Analogue computing with metamaterials
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