Photonic Reservoir Computer with Output Expansion for Unsupervized Parameter Drift Compensation

Jaël Pauwels; Guy Van der Sande; Guy Verschaffelt; Serge Massar

doi:10.3390/e23080955

Photonic Reservoir Computer with Output Expansion for Unsupervized Parameter Drift Compensation

Jaël Pauwels, Guy Van der Sande, Guy Verschaffelt, Serge Massar

Onderzoeksoutput: Article › peer review

4 Citaten (Scopus)

98 Downloads (Pure)

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We present a method to improve the performance of a reservoir computer by keeping the reservoir fixed and increasing the number of output neurons. The additional neurons are nonlinear functions, typically chosen randomly, of the reservoir neurons. We demonstrate the interest of this expanded output layer on an experimental opto-electronic system subject to slow parameter drift which results in loss of performance. We can partially recover the lost performance by using the output layer expansion. The proposed scheme allows for a trade-off between performance gains and system complexity.

Originele taal-2	English
Artikelnummer	955
Aantal pagina's	19
Tijdschrift	Entropy
Volume	23
Nummer van het tijdschrift	8
DOI's	https://doi.org/10.3390/e23080955
Status	Published - 26 jul 2021

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10.3390/e23080955Licentie: CC BY

Pauwels-entropy-23-00955-2021Final published version, 1,07 MBLicentie: CC BY

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Link to publication in Scopus

FWOAL906: Space division multiplexing in standaard multimode optische vezels op basis van het herkennen van speckle patronen
Verschaffelt, G.
1/01/19 → 31/12/22
Project: Fundamenteel
FWOTM861: Hoog performante optische reservoir computing gebaseerd op spatiaal gedistribueerde systemen
Van Der Sande, G., Verschaffelt, G. & Pauwels, J.
1/10/17 → 30/09/21
Project: Fundamenteel
OZR3101: Bilaterale Samenwerking ikv gemeenschappelijk doctoraatsproject: Bench Fee voor Joint PhD VUB-ULB, Pauwels Jaël
Van Der Sande, G.
21/02/17 → 28/02/20
Project: Fundamenteel

Citeer dit

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Photonic Reservoir Computer with Output Expansion for Unsupervized Parameter Drift Compensation

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Projecten

FWOAL906: Space division multiplexing in standaard multimode optische vezels op basis van het herkennen van speckle patronen

FWOTM861: Hoog performante optische reservoir computing gebaseerd op spatiaal gedistribueerde systemen

OZR3101: Bilaterale Samenwerking ikv gemeenschappelijk doctoraatsproject: Bench Fee voor Joint PhD VUB-ULB, Pauwels Jaël

Citeer dit