Command: iaf_psc_exp

Name:
iaf_psc_exp - Leaky integrate-and-fire neuron model with exponential PSCs.

Description:
iaf_psc_expp is an implementation of a leaky integrate-and-fire model with exponential shaped postsynaptic currents (PSCs) according to [1]. Thus, postsynaptic currents have an infinitely short rise time. The threshold crossing is followed by an absolute refractory period (t_ref) during which the membrane potential is clamped to the resting potential and spiking is prohibited. The linear subthresold dynamics is integrated by the Exact Integration scheme [2]. The neuron dynamics is solved on the time grid given by the computation step size. Incoming as well as emitted spikes are forced to that grid. An additional state variable and the corresponding differential equation represents a piecewise constant external current. The general framework for the consistent formulation of systems with neuron like dynamics interacting by point events is described in [2]. A flow chart can be found in [3].

Remarks:
The present implementation uses individual variables for the components of the state vector and the non-zero matrix elements of the propagator. Because the propagator is a lower triangular matrix no full matrix multiplication needs to be carried out and the computation can be done "in place" i.e. no temporary state vector object is required. The template support of recent C++ compilers enables a more succinct formulation without loss of runtime performance already at minimal optimization levels. A future version of iaf_psc_exp will probably address the problem of efficient usage of appropriate vector and matrix objects.

Parameters:
The following parameters can be set in the status dictionary. E_L double - Resting membrane potential in mV. C_m double - Capacity of the membrane in pF tau_m double - Membrane time constant in ms. tau_syn_ex double - Time constant of postsynaptic excitatory currents in ms tau_syn_in double - Time constant of postsynaptic inhibitory currents in ms t_ref double - Duration of refractory period (V_m = V_reset) in ms. V_m double - Membrane potential in mV V_th double - Spike threshold in mV. V_reset double - Reset membrane potential after a spike in mV. I_e double - Constant input current in pA. t_spike double - Point in time of last spike in ms. Note: tau_m != tau_syn_{ex,in} is required by the current implementation to avoid a degenerate case of the ODE describing the model [1]. For very similar values, numerics will be unstable.

References:
[1] Misha Tsodyks, Asher Uziel, and Henry Markram (2000) Synchrony Generation in Recurrent Networks with Frequency-Dependent Synapses, The Journal of Neuroscience, 2000, Vol. 20 RC50 p. 1-5 [2] Rotter S & Diesmann M (1999) Exact simulation of time-invariant linear systems with applications to neuronal modeling. Biologial Cybernetics 81:381-402. [3] Diesmann M, Gewaltig M-O, Rotter S, & Aertsen A (2001) State space analysis of synchronous spiking in cortical neural networks. Neurocomputing 38-40:565-571.

Sends:
SpikeEvent

Receives:
SpikeEvent, CurrentEvent, DataLoggingRequest
SeeAlso: iaf_psc_exp_ps

FirstVersion:
March 2006

Author:
Moritz Helias

Source:
/home/abuild/rpmbuild/BUILD/nest-2.4.1/models/iaf_psc_exp.h

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Name:	iaf_psc_exp - Leaky integrate-and-fire neuron model with exponential PSCs.
Description:	iaf_psc_expp is an implementation of a leaky integrate-and-fire model with exponential shaped postsynaptic currents (PSCs) according to [1]. Thus, postsynaptic currents have an infinitely short rise time. The threshold crossing is followed by an absolute refractory period (t_ref) during which the membrane potential is clamped to the resting potential and spiking is prohibited. The linear subthresold dynamics is integrated by the Exact Integration scheme [2]. The neuron dynamics is solved on the time grid given by the computation step size. Incoming as well as emitted spikes are forced to that grid. An additional state variable and the corresponding differential equation represents a piecewise constant external current. The general framework for the consistent formulation of systems with neuron like dynamics interacting by point events is described in [2]. A flow chart can be found in [3].
Remarks:	The present implementation uses individual variables for the components of the state vector and the non-zero matrix elements of the propagator. Because the propagator is a lower triangular matrix no full matrix multiplication needs to be carried out and the computation can be done "in place" i.e. no temporary state vector object is required. The template support of recent C++ compilers enables a more succinct formulation without loss of runtime performance already at minimal optimization levels. A future version of iaf_psc_exp will probably address the problem of efficient usage of appropriate vector and matrix objects.
Parameters:	The following parameters can be set in the status dictionary. E_L double - Resting membrane potential in mV. C_m double - Capacity of the membrane in pF tau_m double - Membrane time constant in ms. tau_syn_ex double - Time constant of postsynaptic excitatory currents in ms tau_syn_in double - Time constant of postsynaptic inhibitory currents in ms t_ref double - Duration of refractory period (V_m = V_reset) in ms. V_m double - Membrane potential in mV V_th double - Spike threshold in mV. V_reset double - Reset membrane potential after a spike in mV. I_e double - Constant input current in pA. t_spike double - Point in time of last spike in ms. Note: tau_m != tau_syn_{ex,in} is required by the current implementation to avoid a degenerate case of the ODE describing the model [1]. For very similar values, numerics will be unstable.
References:	[1] Misha Tsodyks, Asher Uziel, and Henry Markram (2000) Synchrony Generation in Recurrent Networks with Frequency-Dependent Synapses, The Journal of Neuroscience, 2000, Vol. 20 RC50 p. 1-5 [2] Rotter S & Diesmann M (1999) Exact simulation of time-invariant linear systems with applications to neuronal modeling. Biologial Cybernetics 81:381-402. [3] Diesmann M, Gewaltig M-O, Rotter S, & Aertsen A (2001) State space analysis of synchronous spiking in cortical neural networks. Neurocomputing 38-40:565-571.
Sends:	SpikeEvent
Receives:	SpikeEvent, CurrentEvent, DataLoggingRequest
SeeAlso:	`iaf_psc_exp_ps`
FirstVersion:	March 2006
Author:	Moritz Helias
Source:	/home/abuild/rpmbuild/BUILD/nest-2.4.1/models/iaf_psc_exp.h