Nullcline-based design of a silicon neuron

Arindam Basu; Paul E. Hasler

doi:10.1109/TCSI.2010.2048772

Nullcline-based design of a silicon neuron

Arindam Basu
, Paul E. Hasler

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

64 Citations (Scopus)

Abstract

In this paper, we describe the design of a silicon neuron that exhibits type-I neural excitability, i.e., the frequency of spiking of the neuron approaches arbitrarily close to zero as the input current is reduced. Our design creates a conductance-based silicon model that can exhibit a saddle-node bifurcation. We present simulations and measured data from circuits fabricated in 0.35-μm CMOS that demonstrate both saddle-node bifurcation on invariant circle and saddle-homoclinic bifurcation. In our design, concepts from nonlinear dynamics are used not only for the analysis but also for the synthesis of the circuit. This leads to a nullcline-based methodology that enables a strategic approach for biasing the circuit in the desired regime in parameter space. Combined with the ability to set local biases (e.g., floating gates), this methodology should largely minimize mismatch in arrays of silicon neurons of this kind. The presented circuit is the most power efficient design reported so far, and we hope to fabricate larger arrays of this neuron to explore network behavior. © 2006 IEEE.

Original language	English
Article number	5473081
Pages (from-to)	2938-2947
Journal	IEEE Transactions on Circuits and Systems I: Regular Papers
Volume	57
Issue number	11
DOIs	https://doi.org/10.1109/TCSI.2010.2048772
Publication status	Published - 2010
Externally published	Yes

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Publication details (e.g. title, author(s), publication statuses and dates) are captured on an “AS IS” and “AS AVAILABLE” basis at the time of record harvesting from the data source. Suggestions for further amendments or supplementary information can be sent to [email protected].

Research Keywords

Ion-channel dynamics
nullcline
saddle-node bifurcation
silicon neuron
type-I membrane

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title = "Nullcline-based design of a silicon neuron",

abstract = "In this paper, we describe the design of a silicon neuron that exhibits type-I neural excitability, i.e., the frequency of spiking of the neuron approaches arbitrarily close to zero as the input current is reduced. Our design creates a conductance-based silicon model that can exhibit a saddle-node bifurcation. We present simulations and measured data from circuits fabricated in 0.35-μm CMOS that demonstrate both saddle-node bifurcation on invariant circle and saddle-homoclinic bifurcation. In our design, concepts from nonlinear dynamics are used not only for the analysis but also for the synthesis of the circuit. This leads to a nullcline-based methodology that enables a strategic approach for biasing the circuit in the desired regime in parameter space. Combined with the ability to set local biases (e.g., floating gates), this methodology should largely minimize mismatch in arrays of silicon neurons of this kind. The presented circuit is the most power efficient design reported so far, and we hope to fabricate larger arrays of this neuron to explore network behavior. {\textcopyright} 2006 IEEE.",

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AU - Hasler, Paul E.

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PY - 2010

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N2 - In this paper, we describe the design of a silicon neuron that exhibits type-I neural excitability, i.e., the frequency of spiking of the neuron approaches arbitrarily close to zero as the input current is reduced. Our design creates a conductance-based silicon model that can exhibit a saddle-node bifurcation. We present simulations and measured data from circuits fabricated in 0.35-μm CMOS that demonstrate both saddle-node bifurcation on invariant circle and saddle-homoclinic bifurcation. In our design, concepts from nonlinear dynamics are used not only for the analysis but also for the synthesis of the circuit. This leads to a nullcline-based methodology that enables a strategic approach for biasing the circuit in the desired regime in parameter space. Combined with the ability to set local biases (e.g., floating gates), this methodology should largely minimize mismatch in arrays of silicon neurons of this kind. The presented circuit is the most power efficient design reported so far, and we hope to fabricate larger arrays of this neuron to explore network behavior. © 2006 IEEE.

AB - In this paper, we describe the design of a silicon neuron that exhibits type-I neural excitability, i.e., the frequency of spiking of the neuron approaches arbitrarily close to zero as the input current is reduced. Our design creates a conductance-based silicon model that can exhibit a saddle-node bifurcation. We present simulations and measured data from circuits fabricated in 0.35-μm CMOS that demonstrate both saddle-node bifurcation on invariant circle and saddle-homoclinic bifurcation. In our design, concepts from nonlinear dynamics are used not only for the analysis but also for the synthesis of the circuit. This leads to a nullcline-based methodology that enables a strategic approach for biasing the circuit in the desired regime in parameter space. Combined with the ability to set local biases (e.g., floating gates), this methodology should largely minimize mismatch in arrays of silicon neurons of this kind. The presented circuit is the most power efficient design reported so far, and we hope to fabricate larger arrays of this neuron to explore network behavior. © 2006 IEEE.

KW - Ion-channel dynamics

KW - nullcline

KW - saddle-node bifurcation

KW - silicon neuron

KW - type-I membrane

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DO - 10.1109/TCSI.2010.2048772

M3 - RGC 21 - Publication in refereed journal

SN - 1549-8328

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EP - 2947

JO - IEEE Transactions on Circuits and Systems I: Regular Papers

JF - IEEE Transactions on Circuits and Systems I: Regular Papers

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M1 - 5473081

ER -

Nullcline-based design of a silicon neuron

Abstract

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