Virtual analog modeling of distortion circuits using neural ordinary differential equations

Jan Wilczek; Alec Wright; Vesa Valimaki; Emanuël A. P. Habets

Virtual analog modeling of distortion circuits using neural ordinary differential equations

Jan Wilczek, Alec Wright, Vesa Valimaki, Emanuël A. P. Habets

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

Recent research in deep learning has shown that neural networks can learn differential equations governing dynamical systems. In this paper, we adapt this concept to Virtual Analog (VA) modeling to learn the ordinary differential equations (ODEs) governing the first-order and the second-order diode clipper. The proposed models achieve performance comparable to state-of-the-art recurrent neural networks (RNNs) albeit using fewer parameters. We show that this approach does not require oversampling and allows to increase the sampling rate after the training has completed, which results in increased accuracy. Using a sophisticated numerical solver allows to increase the accuracy at the cost of slower processing. ODEs learned this way do not require closed forms but are still physically interpretable.

Original language	English
Title of host publication	Proceedings of the 25th International Conference on Digital Audio Effects (DAFx20in22)
Editors	Gianpaolo Evangelista, Nicki Holighaus
Place of Publication	Vienna, Austria
Pages	9-16
Number of pages	8
ISBN (Electronic)	9783200085992
Publication status	Published - 6 Sept 2022

Publication series

Name	Proceedings of the International Conference on Digital Audio Effects
ISSN (Print)	2413-6700
ISSN (Electronic)	2413-6689

Keywords / Materials (for Non-textual outputs)

virtual analog
neural networks
distortion circuits

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Wright2022DAFx20in22VirtualAnalogFinal published version, 2.26 MBLicence: Creative Commons: Attribution (CC-BY)

https://www.dafx.de/paper-archive/2022/papers/DAFx20in22_paper_12.pdfLicence: Creative Commons: Attribution (CC-BY)

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Wilczek, J., Wright, A., Valimaki, V., & Habets, E. A. P. (2022). Virtual analog modeling of distortion circuits using neural ordinary differential equations. In G. Evangelista, & N. Holighaus (Eds.), Proceedings of the 25th International Conference on Digital Audio Effects (DAFx20in22) (pp. 9-16). (Proceedings of the International Conference on Digital Audio Effects).. https://www.dafx.de/paper-archive/2022/papers/DAFx20in22_paper_12.pdf

Wilczek, Jan ; Wright, Alec ; Valimaki, Vesa et al. / Virtual analog modeling of distortion circuits using neural ordinary differential equations. Proceedings of the 25th International Conference on Digital Audio Effects (DAFx20in22). editor / Gianpaolo Evangelista ; Nicki Holighaus. Vienna, Austria, 2022. pp. 9-16 (Proceedings of the International Conference on Digital Audio Effects).

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title = "Virtual analog modeling of distortion circuits using neural ordinary differential equations",

abstract = "Recent research in deep learning has shown that neural networks can learn differential equations governing dynamical systems. In this paper, we adapt this concept to Virtual Analog (VA) modeling to learn the ordinary differential equations (ODEs) governing the first-order and the second-order diode clipper. The proposed models achieve performance comparable to state-of-the-art recurrent neural networks (RNNs) albeit using fewer parameters. We show that this approach does not require oversampling and allows to increase the sampling rate after the training has completed, which results in increased accuracy. Using a sophisticated numerical solver allows to increase the accuracy at the cost of slower processing. ODEs learned this way do not require closed forms but are still physically interpretable.",

keywords = "virtual analog, neural networks, distortion circuits",

author = "Jan Wilczek and Alec Wright and Vesa Valimaki and Habets, \{Emanu{\"e}l A. P.\}",

year = "2022",

month = sep,

day = "6",

language = "English",

series = "Proceedings of the International Conference on Digital Audio Effects",

pages = "9--16",

editor = "Gianpaolo Evangelista and Nicki Holighaus",

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Wilczek, J, Wright, A, Valimaki, V & Habets, EAP 2022, Virtual analog modeling of distortion circuits using neural ordinary differential equations. in G Evangelista & N Holighaus (eds), Proceedings of the 25th International Conference on Digital Audio Effects (DAFx20in22). Proceedings of the International Conference on Digital Audio Effects, Vienna, Austria, pp. 9-16. <https://www.dafx.de/paper-archive/2022/papers/DAFx20in22_paper_12.pdf>

Virtual analog modeling of distortion circuits using neural ordinary differential equations. / Wilczek, Jan; Wright, Alec; Valimaki, Vesa et al.
Proceedings of the 25th International Conference on Digital Audio Effects (DAFx20in22). ed. / Gianpaolo Evangelista; Nicki Holighaus. Vienna, Austria, 2022. p. 9-16 (Proceedings of the International Conference on Digital Audio Effects).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

TY - GEN

T1 - Virtual analog modeling of distortion circuits using neural ordinary differential equations

AU - Wilczek, Jan

AU - Wright, Alec

AU - Valimaki, Vesa

AU - Habets, Emanuël A. P.

PY - 2022/9/6

Y1 - 2022/9/6

N2 - Recent research in deep learning has shown that neural networks can learn differential equations governing dynamical systems. In this paper, we adapt this concept to Virtual Analog (VA) modeling to learn the ordinary differential equations (ODEs) governing the first-order and the second-order diode clipper. The proposed models achieve performance comparable to state-of-the-art recurrent neural networks (RNNs) albeit using fewer parameters. We show that this approach does not require oversampling and allows to increase the sampling rate after the training has completed, which results in increased accuracy. Using a sophisticated numerical solver allows to increase the accuracy at the cost of slower processing. ODEs learned this way do not require closed forms but are still physically interpretable.

AB - Recent research in deep learning has shown that neural networks can learn differential equations governing dynamical systems. In this paper, we adapt this concept to Virtual Analog (VA) modeling to learn the ordinary differential equations (ODEs) governing the first-order and the second-order diode clipper. The proposed models achieve performance comparable to state-of-the-art recurrent neural networks (RNNs) albeit using fewer parameters. We show that this approach does not require oversampling and allows to increase the sampling rate after the training has completed, which results in increased accuracy. Using a sophisticated numerical solver allows to increase the accuracy at the cost of slower processing. ODEs learned this way do not require closed forms but are still physically interpretable.

KW - virtual analog

KW - neural networks

KW - distortion circuits

UR - https://dafx2020.mdw.ac.at/proceedings/DAFx20in22Proceedings.pdf

M3 - Conference contribution

T3 - Proceedings of the International Conference on Digital Audio Effects

SP - 9

EP - 16

BT - Proceedings of the 25th International Conference on Digital Audio Effects (DAFx20in22)

A2 - Evangelista, Gianpaolo

A2 - Holighaus, Nicki

CY - Vienna, Austria

ER -

Virtual analog modeling of distortion circuits using neural ordinary differential equations

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