Translucent Photonic Frequency-Domain Neuron with Unamplified Concatenation of Neural Sub-Circuits

Margareta Vania Stephanie; Lam Pham; Tibor Grasser; Michael Waltl; Bernhard Schrenk

Translucent Photonic Frequency-Domain Neuron with Unamplified Concatenation of Neural Sub-Circuits

Margareta Vania Stephanie (Autor:in und Vortragende:r), Lam Pham, Tibor Grasser, Michael Waltl, Bernhard Schrenk

TU Wien

Publikation: Beitrag in Buch oder Tagungsband › Beitrag in Tagungsband mit Posterpräsentation › Begutachtung

Abstract

We demonstrate frequency-domain neural signal processing for linear weighted summation and non-linear ReLU activation, using a flexible interconnect to synthesize both sub-circuits. We show that neural network sub-circuits can drive each other without amplification and confirm a low <1.5% penalty in accuracy for concatenated operation.

Originalsprache	Englisch
Titel	Proceedings 2024 European Conference on Optical Communications 2024
Erscheinungsort	Frankfurt, Germany
Seiten	790-793
Seitenumfang	4
Publikationsstatus	Veröffentlicht - 2024
Veranstaltung	2024 European Conference on Optical Communications (ECOC): 50th European Conference on Optical Communication - Frankfurt, Frankfurt, Deutschland Dauer: 22 Sept. 2024 → 26 Sept. 2024

Konferenz

Konferenz	2024 European Conference on Optical Communications (ECOC)
Kurztitel	ECOC 2024
Land/Gebiet	Deutschland
Stadt	Frankfurt
Zeitraum	22/09/24 → 26/09/24

Research Field

Enabling Digital Technologies
Multimodal Analytics

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ecoc24_translucent

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title = "Translucent Photonic Frequency-Domain Neuron with Unamplified Concatenation of Neural Sub-Circuits",

abstract = "We demonstrate frequency-domain neural signal processing for linear weighted summation and non-linear ReLU activation, using a flexible interconnect to synthesize both sub-circuits. We show that neural network sub-circuits can drive each other without amplification and confirm a low <1.5% penalty in accuracy for concatenated operation.",

author = "Stephanie, {Margareta Vania} and Lam Pham and Tibor Grasser and Michael Waltl and Bernhard Schrenk",

year = "2024",

language = "English",

pages = "790--793",

booktitle = "Proceedings 2024 European Conference on Optical Communications 2024",

note = "2024 European Conference on Optical Communications (ECOC) : 50th European Conference on Optical Communication, ECOC 2024 ; Conference date: 22-09-2024 Through 26-09-2024",

}

Translucent Photonic Frequency-Domain Neuron with Unamplified Concatenation of Neural Sub-Circuits. / Stephanie, Margareta Vania (Autor:in und Vortragende:r); Pham, Lam; Grasser, Tibor et al.
Proceedings 2024 European Conference on Optical Communications 2024. Frankfurt, Germany, 2024. S. 790-793 W2A.44.

Publikation: Beitrag in Buch oder Tagungsband › Beitrag in Tagungsband mit Posterpräsentation › Begutachtung

TY - CHAP

T1 - Translucent Photonic Frequency-Domain Neuron with Unamplified Concatenation of Neural Sub-Circuits

AU - Pham, Lam

AU - Grasser, Tibor

AU - Waltl, Michael

AU - Schrenk, Bernhard

A2 - Stephanie, Margareta Vania

PY - 2024

Y1 - 2024

N2 - We demonstrate frequency-domain neural signal processing for linear weighted summation and non-linear ReLU activation, using a flexible interconnect to synthesize both sub-circuits. We show that neural network sub-circuits can drive each other without amplification and confirm a low <1.5% penalty in accuracy for concatenated operation.

AB - We demonstrate frequency-domain neural signal processing for linear weighted summation and non-linear ReLU activation, using a flexible interconnect to synthesize both sub-circuits. We show that neural network sub-circuits can drive each other without amplification and confirm a low <1.5% penalty in accuracy for concatenated operation.

M3 - Conference Proceedings with Poster Presentation

SP - 790

EP - 793

BT - Proceedings 2024 European Conference on Optical Communications 2024

CY - Frankfurt, Germany

T2 - 2024 European Conference on Optical Communications (ECOC)

Y2 - 22 September 2024 through 26 September 2024

ER -

Translucent Photonic Frequency-Domain Neuron with Unamplified Concatenation of Neural Sub-Circuits

Abstract

Konferenz

Research Field

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