Optimizing Synaptic Conductance Calculation for Network Simulations

William W. Lytton

doi:10.1162/neco.1996.8.3.501

Optimizing Synaptic Conductance Calculation for Network Simulations

William W. Lytton

Physiology / Pharmacology

SUNY Downstate Health Sciences University

Research output: Contribution to journal › Article › peer-review

44 Scopus citations

Abstract

High computational requirements in realistic neuronal network simulations have led to attempts to realize implementation efficiencies while maintaining as much realism as possible. Since the number of synapses in a network will generally far exceed the number of neurons, simulation of synaptic activation may be a large proportion of total processing time. We present a consolidating algorithm based on a recent biophysically-inspired simplified Markov model of the synapse. Use of a single lumped state variable to represent a large number of converging synaptic inputs results in substantial speed-ups.

Original language	English
Pages (from-to)	501-509
Number of pages	9
Journal	Neural Computation
Volume	8
Issue number	3
DOIs	https://doi.org/10.1162/neco.1996.8.3.501
State	Published - Apr 1 1996

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10.1162/neco.1996.8.3.501

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title = "Optimizing Synaptic Conductance Calculation for Network Simulations",

abstract = "High computational requirements in realistic neuronal network simulations have led to attempts to realize implementation efficiencies while maintaining as much realism as possible. Since the number of synapses in a network will generally far exceed the number of neurons, simulation of synaptic activation may be a large proportion of total processing time. We present a consolidating algorithm based on a recent biophysically-inspired simplified Markov model of the synapse. Use of a single lumped state variable to represent a large number of converging synaptic inputs results in substantial speed-ups.",

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AB - High computational requirements in realistic neuronal network simulations have led to attempts to realize implementation efficiencies while maintaining as much realism as possible. Since the number of synapses in a network will generally far exceed the number of neurons, simulation of synaptic activation may be a large proportion of total processing time. We present a consolidating algorithm based on a recent biophysically-inspired simplified Markov model of the synapse. Use of a single lumped state variable to represent a large number of converging synaptic inputs results in substantial speed-ups.

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DO - 10.1162/neco.1996.8.3.501

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Optimizing Synaptic Conductance Calculation for Network Simulations

Abstract

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