Exact Simulation of Integrate-and-fire Models with Exponential Currents
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Neural networks can be simulated exactly using event-driven strategies, in which the algorithm advances directly from one spike to the next spike. It applies to neuron models for which we have (1) an explicit expression for the evolution of the state variables between spikes and (2) an explicit test on the state variables that predicts whether and when a spike will be emitted. In a previous work, we proposed a method that allows exact simulation of an integrate-and-fire model with exponential conductances, with the constraint of a single synaptic time constant. In this note, we propose a method, based on polynomial root finding, that applies to integrate-and-fire models with exponential currents, with possibly many different synaptic time constants. Models can include biexponential synaptic currents and spike-triggered adaptation currents.
Susi G, Garces P, Paracone E, Cristini A, Salerno M, Maestu F Sci Rep. 2021; 11(1):12160.
PMID: 34108523 PMC: 8190312. DOI: 10.1038/s41598-021-91513-8.
Simulation of Large Scale Neural Models With Event-Driven Connectivity Generation.
Azevedo Carvalho N, Contassot-Vivier S, Buhry L, Martinez D Front Neuroinform. 2020; 14:522000.
PMID: 33154719 PMC: 7591773. DOI: 10.3389/fninf.2020.522000.
Back-Propagation Learning in Deep Spike-By-Spike Networks.
Rotermund D, Pawelzik K Front Comput Neurosci. 2019; 13:55.
PMID: 31456677 PMC: 6700320. DOI: 10.3389/fncom.2019.00055.
Perfect Detection of Spikes in the Linear Sub-threshold Dynamics of Point Neurons.
Krishnan J, Porta Mana P, Helias M, Diesmann M, Napoli E Front Neuroinform. 2018; 11:75.
PMID: 29379430 PMC: 5770835. DOI: 10.3389/fninf.2017.00075.
NEVESIM: event-driven neural simulation framework with a Python interface.
Pecevski D, Kappel D, Jonke Z Front Neuroinform. 2014; 8:70.
PMID: 25177291 PMC: 4132371. DOI: 10.3389/fninf.2014.00070.