traub_psc_alpha_neuron
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traub_psc_alpha - Traub model according to Borgers 2017
Reduced Traub-Miles Model of a Pyramidal Neuron in Rat Hippocampus [1]_. Parameters obtained from reference [2]_.
Incoming spike events induce a post-synaptic change of current, modelled by an alpha function.
References
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.. [1] R. D. Traub and R. Miles, Neuronal Networks of the Hippocampus,Cam- bridge University Press, Cambridge, UK, 1991.
.. [2] Borgers, C., 2017. An introduction to modeling neuronal dynamics (Vol. 66). Cham: Springer.
See also
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hh_cond_exp_traub
Copyright statement
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This file is part of NEST.
Copyright (C) 2004 The NEST Initiative
NEST is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 2 of the License, or
(at your option) any later version.
NEST is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with NEST. If not, see .
Parameters
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.. csv-table::
:header: "Name", "Physical unit", "Default value", "Description"
:widths: auto
"V_m_init", "mV", "-70mV", "Initial membrane potential"
"C_m", "pF", "100pF", "Membrane capacitance"
"g_Na", "nS", "10000nS", "Sodium peak conductance"
"g_K", "nS", "8000nS", "Potassium peak conductance"
"g_L", "nS", "10nS", "Leak conductance"
"E_Na", "mV", "50mV", "Sodium reversal potential"
"E_K", "mV", "-100mV", "Potassium reversal potential"
"E_L", "mV", "-67mV", "Leak reversal potential (a.k.a. resting potential)"
"V_Tr", "mV", "-20mV", "Spike threshold"
"refr_T", "ms", "2ms", "Duration of refractory period"
"tau_syn_exc", "ms", "0.2ms", "Rise time of the excitatory synaptic alpha function"
"tau_syn_inh", "ms", "2ms", "Rise time of the inhibitory synaptic alpha function"
"I_e", "pA", "0pA", "constant external input current"
State variables
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.. csv-table::
:header: "Name", "Physical unit", "Default value", "Description"
:widths: auto
"V_m", "mV", "V_m_init", "Membrane potential"
"V_m_old", "mV", "V_m_init", "Membrane potential at previous timestep for threshold check"
"refr_t", "ms", "0ms", "Refractory period timer"
"Act_m", "real", "alpha_m_init / (alpha_m_init + beta_m_init)", "Activation variable m for Na"
"Inact_h", "real", "alpha_h_init / (alpha_h_init + beta_h_init)", "Inactivation variable h for Na"
"Act_n", "real", "alpha_n_init / (alpha_n_init + beta_n_init)", "Activation variable n for K"
Equations
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.. math::
\frac{ dAct_{n} } { dt }= \frac 1 { \mathrm{ms} } \left( { (\alpha_{n} \cdot (1 - Act_{n}) - \beta_{n} \cdot Act_{n}) } \right)
.. math::
\frac{ dAct_{m} } { dt }= \frac 1 { \mathrm{ms} } \left( { (\alpha_{m} \cdot (1 - Act_{m}) - \beta_{m} \cdot Act_{m}) } \right)
.. math::
\frac{ dInact_{h} } { dt }= \frac 1 { \mathrm{ms} } \left( { (\alpha_{h} \cdot (1 - Inact_{h}) - \beta_{h} \cdot Inact_{h}) } \right)
.. math::
\frac{ dV_{m} } { dt }= \frac 1 { C_{m} } \left( { (-(I_{Na} + I_{K} + I_{L}) + I_{e} + I_{stim} + I_{syn,exc} - I_{syn,inh}) } \right)
.. math::
\frac{ drefr_{t} } { dt }= \frac{ -1000.0 \cdot \mathrm{ms} } { \mathrm{s} }
Source code
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The model source code can be found in the NESTML models repository here: `traub_psc_alpha_neuron `_.
.. include:: traub_psc_alpha_neuron_characterisation.rst
.. footer::
Generated at 2026-02-04 14:40:55.047151