Pattern representation and recognition with accelerated analog neuromorphic systems

Mihai A. Petrovici; Sebastian Schmitt; Johann Klähn; David Stöckel; Anna Schroeder; Guillaume Bellec; Johannes Bill; Oliver Breitwieser; Ilja Bytschok; Andreas Grübl; Maurice Güttler; Andreas Hartel; Stephan Hartmann; Dan Husmann; Kai Husmann; Sebastian Jeltsch; Vitali Karasenko; Mitja Kleider; Christoph Koke; Alexander Kononov; Christian Mauch; Paul Müller; Johannes Partzsch; Thomas Pfeil; Stefan Schiefer; Stefan Scholze; Anand Subramoney; Vasilis Thanasoulis; Bernhard Vogginger; Robert Legenstein; Wolfgang Maass; René Schüffny; Christian Mayr; Johannes Schemmel; Karlheinz Meier

doi:10.1109/ISCAS.2017.8050530

Pattern representation and recognition with accelerated analog neuromorphic systems

Mihai A. Petrovici, Sebastian Schmitt, Johann Klähn, David Stöckel, Anna Schroeder, Guillaume Bellec, Johannes Bill, Oliver Breitwieser, Ilja Bytschok, Andreas Grübl, Maurice Güttler, Andreas Hartel, Stephan Hartmann, Dan Husmann, Kai Husmann, Sebastian Jeltsch, Vitali Karasenko, Mitja Kleider, Christoph Koke, Alexander KononovChristian Mauch, Paul Müller, Johannes Partzsch, Thomas Pfeil, Stefan Schiefer, Stefan Scholze, Anand Subramoney, Vasilis Thanasoulis, Bernhard Vogginger, Robert Legenstein, Wolfgang Maass, René Schüffny, Christian Mayr, Johannes Schemmel, Karlheinz Meier

Institut für Grundlagen der Informationsverarbeitung (7080)

Publikation: Beitrag in Buch/Bericht/Konferenzband › Beitrag in einem Konferenzband › Begutachtung

Abstract

Despite being originally inspired by the central nervous system, artificial neural networks have diverged from their biological archetypes as they have been remodeled to fit particular tasks. In this paper, we review several possibilites to reverse map these architectures to biologically more realistic spiking networks with the aim of emulating them on fast, low-power neuromorphic hardware. Since many of these devices employ analog components, which cannot be perfectly controlled, finding ways to compensate for the resulting effects represents a key challenge. Here, we discuss three different strategies to address this problem: the addition of auxiliary network components for stabilizing activity, the utilization of inherently robust architectures and a training method for hardware-emulated networks that functions without perfect knowledge of the system's dynamics and parameters. For all three scenarios, we corroborate our theoretical considerations with experimental results on accelerated analog neuromorphic platforms.

Originalsprache	englisch
Titel	Proceedings - IEEE International Symposium on Circuits and Systems
Herausgeber (Verlag)	Institute of Electrical and Electronics Engineers
Seitenumfang	4
ISBN (elektronisch)	978-146736852-0
DOIs	https://doi.org/10.1109/ISCAS.2017.8050530
Publikationsstatus	Veröffentlicht - 17 März 2017
Veranstaltung	50th IEEE International Symposium on Circuits and Systems: ISCAS 2017 - Baltimore, USA / Vereinigte Staaten Dauer: 28 Mai 2017 → 31 Mai 2017

Konferenz

Konferenz	50th IEEE International Symposium on Circuits and Systems
Land/Gebiet	USA / Vereinigte Staaten
Ort	Baltimore
Zeitraum	28/05/17 → 31/05/17

Fields of Expertise

Information, Communication & Computing

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10.1109/ISCAS.2017.8050530Lizenz: CC BY 4.0

170306043v1Eingereichtes Manuskript, 1,82 MBLizenz: CC BY 4.0

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Petrovici, M. A., Schmitt, S., Klähn, J., Stöckel, D., Schroeder, A., Bellec, G., Bill, J., Breitwieser, O., Bytschok, I., Grübl, A., Güttler, M., Hartel, A., Hartmann, S., Husmann, D., Husmann, K., Jeltsch, S., Karasenko, V., Kleider, M., Koke, C., ... Meier, K. (2017). Pattern representation and recognition with accelerated analog neuromorphic systems. in Proceedings - IEEE International Symposium on Circuits and Systems [8050530] Institute of Electrical and Electronics Engineers. https://doi.org/10.1109/ISCAS.2017.8050530

Pattern representation and recognition with accelerated analog neuromorphic systems. / Petrovici, Mihai A.; Schmitt, Sebastian; Klähn, Johann et al.

Proceedings - IEEE International Symposium on Circuits and Systems. Institute of Electrical and Electronics Engineers, 2017. 8050530.

Publikation: Beitrag in Buch/Bericht/Konferenzband › Beitrag in einem Konferenzband › Begutachtung

Petrovici, MA, Schmitt, S, Klähn, J, Stöckel, D, Schroeder, A, Bellec, G, Bill, J, Breitwieser, O, Bytschok, I, Grübl, A, Güttler, M, Hartel, A, Hartmann, S, Husmann, D, Husmann, K, Jeltsch, S, Karasenko, V, Kleider, M, Koke, C, Kononov, A, Mauch, C, Müller, P, Partzsch, J, Pfeil, T, Schiefer, S, Scholze, S, Subramoney, A, Thanasoulis, V, Vogginger, B, Legenstein, R , Maass, W, Schüffny, R, Mayr, C, Schemmel, J & Meier, K 2017, Pattern representation and recognition with accelerated analog neuromorphic systems. in Proceedings - IEEE International Symposium on Circuits and Systems., 8050530, Institute of Electrical and Electronics Engineers, 50th IEEE International Symposium on Circuits and Systems, Baltimore, USA / Vereinigte Staaten, 28/05/17. https://doi.org/10.1109/ISCAS.2017.8050530

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title = "Pattern representation and recognition with accelerated analog neuromorphic systems",

abstract = "Despite being originally inspired by the central nervous system, artificial neural networks have diverged from their biological archetypes as they have been remodeled to fit particular tasks. In this paper, we review several possibilites to reverse map these architectures to biologically more realistic spiking networks with the aim of emulating them on fast, low-power neuromorphic hardware. Since many of these devices employ analog components, which cannot be perfectly controlled, finding ways to compensate for the resulting effects represents a key challenge. Here, we discuss three different strategies to address this problem: the addition of auxiliary network components for stabilizing activity, the utilization of inherently robust architectures and a training method for hardware-emulated networks that functions without perfect knowledge of the system's dynamics and parameters. For all three scenarios, we corroborate our theoretical considerations with experimental results on accelerated analog neuromorphic platforms.",

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AU - Petrovici, Mihai A.

AU - Schmitt, Sebastian

AU - Klähn, Johann

AU - Stöckel, David

AU - Schroeder, Anna

AU - Bellec, Guillaume

AU - Bill, Johannes

AU - Breitwieser, Oliver

AU - Bytschok, Ilja

AU - Grübl, Andreas

AU - Güttler, Maurice

AU - Hartel, Andreas

AU - Hartmann, Stephan

AU - Husmann, Dan

AU - Husmann, Kai

AU - Jeltsch, Sebastian

AU - Karasenko, Vitali

AU - Kleider, Mitja

AU - Koke, Christoph

AU - Kononov, Alexander

AU - Mauch, Christian

AU - Müller, Paul

AU - Partzsch, Johannes

AU - Pfeil, Thomas

AU - Schiefer, Stefan

AU - Scholze, Stefan

AU - Subramoney, Anand

AU - Thanasoulis, Vasilis

AU - Vogginger, Bernhard

AU - Legenstein, Robert

AU - Maass, Wolfgang

AU - Schüffny, René

AU - Mayr, Christian

AU - Schemmel, Johannes

AU - Meier, Karlheinz

N1 - accepted at ISCAS 2017

PY - 2017/3/17

Y1 - 2017/3/17

N2 - Despite being originally inspired by the central nervous system, artificial neural networks have diverged from their biological archetypes as they have been remodeled to fit particular tasks. In this paper, we review several possibilites to reverse map these architectures to biologically more realistic spiking networks with the aim of emulating them on fast, low-power neuromorphic hardware. Since many of these devices employ analog components, which cannot be perfectly controlled, finding ways to compensate for the resulting effects represents a key challenge. Here, we discuss three different strategies to address this problem: the addition of auxiliary network components for stabilizing activity, the utilization of inherently robust architectures and a training method for hardware-emulated networks that functions without perfect knowledge of the system's dynamics and parameters. For all three scenarios, we corroborate our theoretical considerations with experimental results on accelerated analog neuromorphic platforms.

AB - Despite being originally inspired by the central nervous system, artificial neural networks have diverged from their biological archetypes as they have been remodeled to fit particular tasks. In this paper, we review several possibilites to reverse map these architectures to biologically more realistic spiking networks with the aim of emulating them on fast, low-power neuromorphic hardware. Since many of these devices employ analog components, which cannot be perfectly controlled, finding ways to compensate for the resulting effects represents a key challenge. Here, we discuss three different strategies to address this problem: the addition of auxiliary network components for stabilizing activity, the utilization of inherently robust architectures and a training method for hardware-emulated networks that functions without perfect knowledge of the system's dynamics and parameters. For all three scenarios, we corroborate our theoretical considerations with experimental results on accelerated analog neuromorphic platforms.

KW - q-bio.NC

KW - cs.NE

KW - stat.ML

U2 - 10.1109/ISCAS.2017.8050530

DO - 10.1109/ISCAS.2017.8050530

M3 - Conference paper

BT - Proceedings - IEEE International Symposium on Circuits and Systems

PB - Institute of Electrical and Electronics Engineers

T2 - 50th IEEE International Symposium on Circuits and Systems

Y2 - 28 May 2017 through 31 May 2017

ER -

Pattern representation and recognition with accelerated analog neuromorphic systems

Abstract

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