Firing rate of the leaky integrate-and-fire neuron with stochastic conductance-based synaptic inputs with short decay times
Publication
, Journal Article
Oleskiw, TD; Bair, W; Shea-Brown, E; Brunel, N
February 25, 2020
We compute the firing rate of a leaky integrate-and-fire (LIF) neuron with stochastic conductance-based inputs in the limit when synaptic decay times are much shorter than the membrane time constant. A comparison of our analytical results to numeric simulations is presented for a range of biophysically-realistic parameters.
Duke Scholars
Publication Date
February 25, 2020
Citation
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ICMJE
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Oleskiw, T. D., Bair, W., Shea-Brown, E., & Brunel, N. (2020). Firing rate of the leaky integrate-and-fire neuron with stochastic
conductance-based synaptic inputs with short decay times.
Oleskiw, Timothy D., Wyeth Bair, Eric Shea-Brown, and Nicolas Brunel. “Firing rate of the leaky integrate-and-fire neuron with stochastic
conductance-based synaptic inputs with short decay times,” February 25, 2020.
Oleskiw TD, Bair W, Shea-Brown E, Brunel N. Firing rate of the leaky integrate-and-fire neuron with stochastic
conductance-based synaptic inputs with short decay times. 2020 Feb 25;
Oleskiw, Timothy D., et al. Firing rate of the leaky integrate-and-fire neuron with stochastic
conductance-based synaptic inputs with short decay times. Feb. 2020.
Oleskiw TD, Bair W, Shea-Brown E, Brunel N. Firing rate of the leaky integrate-and-fire neuron with stochastic
conductance-based synaptic inputs with short decay times. 2020 Feb 25;
Publication Date
February 25, 2020