2021
DOI: 10.21203/rs.3.rs-783820/v1
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Short-wavelength Reverberant Wave Systems for Enhanced Reservoir Computing

Abstract: Machine learning (ML) has found widespread application over a broad range of important tasks. To enhance ML performance, researchers have investigated computational architectures whose physical implementations promise compactness, high-speed execution, physical robustness, and low energy cost. Here, we experimentally demonstrate an approach that uses the high sensitivity of reverberant short wavelength waves for physical realization and enhancement of computational power of a type of ML known as reservoir comp… Show more

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Cited by 3 publications
(3 citation statements)
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“…[24,85,86] Ultimately, ex-perimental validation of all these ideas will be indispensable in the future. Moreover, our proposed smart on-chip EM environment can be endowed with a second functionality related to wave-based analog signal-processing by bringing recent proposals of wave processing in (programmable) scattering enclosures for matrix multiplication, [87] signal differentiation, [83] or reservoir computing [88] to the chip scale. Such analog "over-the-air" computing holds the promise to be faster and more energy efficient than its electronic digital counterpart for specific computational operations, paving the way to hybrid analog-digital processing chips.…”
Section: Discussionmentioning
confidence: 99%
“…[24,85,86] Ultimately, ex-perimental validation of all these ideas will be indispensable in the future. Moreover, our proposed smart on-chip EM environment can be endowed with a second functionality related to wave-based analog signal-processing by bringing recent proposals of wave processing in (programmable) scattering enclosures for matrix multiplication, [87] signal differentiation, [83] or reservoir computing [88] to the chip scale. Such analog "over-the-air" computing holds the promise to be faster and more energy efficient than its electronic digital counterpart for specific computational operations, paving the way to hybrid analog-digital processing chips.…”
Section: Discussionmentioning
confidence: 99%
“…Finally, we note that in the future the smart on-chip EM environment that we propose can be endowed with a second functionality related to wave-based analog signalprocessing by bringing recent proposals of wave processing in (programmable) scattering enclosures for matrix multiplication [47], signal differentiation [48], or reservoir computing [49] to the chip scale. Such analog "over-theair" computing holds the promise to be faster and more energy efficient than its electronic digital counterpart for specific computational operations, paving the way to hybrid analog-digital processing chips.…”
Section: Discussionmentioning
confidence: 99%
“…However, equipped with programmable meta-atoms, its scattering properties can be judiciously tuned such that it performs a programmable linear transformation. 236,237 Ideas for adding non-linearities include the use of diode-loaded ports 238 and input-signal-dependent time modulation. 239 The bulkiness of 3D volumetric scattering enclosures appears at first sight a major obstacle to integrability.…”
Section: Complex Scattering Systemmentioning
confidence: 99%