Silicon cochleas

André van Schaik; Tara Hamilton; Shih-Chii Liu

Silicon cochleas

André van Schaik, Tara Hamilton, Shih-Chii Liu

Research output: Chapter in Book / Conference Paper › Chapter

Abstract

While the previous chapter was about neuromorphic silicon retinas, this one is on silicon cochleas. The cochlea is biology's sound sensor - it turns vibrations in the air into a neural signal. This chapter briefly explains the operation of the various components of the biological cochlea and introduces circuits that can simulate these components. Silicon cochlea designs typically divide the biological cochlea into several sections that are equally spaced along its length. Each section is then modeled by an electronic circuit. Silicon cochlea designs may be classified as 10 or 20, depending on the coupling between these sections. Circuits for both variants are presented. They may also be classified as active or passive, depending on whether the quality factor of each cochlear section changes as a function of the output signal of the section or not. Details for both implementations are presented. A tree diagram at the end of the chapter illustrates the progression of silicon cochlea modeling.

Original language	English
Title of host publication	Event-Based Neuromorphic Systems
Editors	Shih-Chii Liu, Tobi Delbruck, Giacomo Indiveri, Adrian Whatley, Rodney Douglas
Place of Publication	U.K.
Publisher	Wiley & Sons
Pages	71-89
Number of pages	19
ISBN (Electronic)	9781118927632
ISBN (Print)	9781118927601
Publication status	Published - 2015

Keywords

cochlea
silicon
circuits

Cite this

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abstract = "While the previous chapter was about neuromorphic silicon retinas, this one is on silicon cochleas. The cochlea is biology's sound sensor - it turns vibrations in the air into a neural signal. This chapter briefly explains the operation of the various components of the biological cochlea and introduces circuits that can simulate these components. Silicon cochlea designs typically divide the biological cochlea into several sections that are equally spaced along its length. Each section is then modeled by an electronic circuit. Silicon cochlea designs may be classified as 10 or 20, depending on the coupling between these sections. Circuits for both variants are presented. They may also be classified as active or passive, depending on whether the quality factor of each cochlear section changes as a function of the output signal of the section or not. Details for both implementations are presented. A tree diagram at the end of the chapter illustrates the progression of silicon cochlea modeling.",

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T1 - Silicon cochleas

AU - Schaik, André van

AU - Hamilton, Tara

AU - Liu, Shih-Chii

PY - 2015

Y1 - 2015

N2 - While the previous chapter was about neuromorphic silicon retinas, this one is on silicon cochleas. The cochlea is biology's sound sensor - it turns vibrations in the air into a neural signal. This chapter briefly explains the operation of the various components of the biological cochlea and introduces circuits that can simulate these components. Silicon cochlea designs typically divide the biological cochlea into several sections that are equally spaced along its length. Each section is then modeled by an electronic circuit. Silicon cochlea designs may be classified as 10 or 20, depending on the coupling between these sections. Circuits for both variants are presented. They may also be classified as active or passive, depending on whether the quality factor of each cochlear section changes as a function of the output signal of the section or not. Details for both implementations are presented. A tree diagram at the end of the chapter illustrates the progression of silicon cochlea modeling.

AB - While the previous chapter was about neuromorphic silicon retinas, this one is on silicon cochleas. The cochlea is biology's sound sensor - it turns vibrations in the air into a neural signal. This chapter briefly explains the operation of the various components of the biological cochlea and introduces circuits that can simulate these components. Silicon cochlea designs typically divide the biological cochlea into several sections that are equally spaced along its length. Each section is then modeled by an electronic circuit. Silicon cochlea designs may be classified as 10 or 20, depending on the coupling between these sections. Circuits for both variants are presented. They may also be classified as active or passive, depending on whether the quality factor of each cochlear section changes as a function of the output signal of the section or not. Details for both implementations are presented. A tree diagram at the end of the chapter illustrates the progression of silicon cochlea modeling.

KW - cochlea

KW - silicon

KW - circuits

UR - http://handle.uws.edu.au:8081/1959.7/uws:30126

UR - http://www.UWSAU.eblib.com.AU/EBLWeb/patron/?target=patron&extendedid=P_1895762_0

M3 - Chapter

SN - 9781118927601

SP - 71

EP - 89

BT - Event-Based Neuromorphic Systems

A2 - Liu, Shih-Chii

A2 - Delbruck, Tobi

A2 - Indiveri, Giacomo

A2 - Whatley, Adrian

A2 - Douglas, Rodney

PB - Wiley & Sons

CY - U.K.

ER -

Silicon cochleas

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Keywords

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