iaf_cond_beta – Simple conductance based leaky integrate-and-fire neuron model
==============================================================================

Description
+++++++++++

``iaf_cond_beta`` is an implementation of a spiking neuron using IAF dynamics with
conductance-based synapses. Incoming spike events induce a postsynaptic change
of conductance modelled by a beta function. The beta function
is normalized such that an event of weight 1.0 results in a peak current of
1 nS at :math:`t = \tau_{rise\_[ex|in]}`.

.. note::
   Per 2009-04-17, this class has been revised to our newest
   insights into class design. Please use THIS CLASS as a reference
   when designing your own models with nonlinear dynamics.
   One weakness of this class is that it distinguishes between
   inputs to the two synapses by the sign of the synaptic weight.
   It would be better to use ``receptor_types``, cf ``iaf_cond_alpha_mc``.

See also [1]_, [2]_, [3]_, [4]_, [5]_.

Parameters
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The following parameters can be set in the status dictionary.

============= ====== =========================================================
 V_m          mV      Membrane potential
 E_L          mV      Leak reversal potential
 C_m          pF      Capacity of the membrane
 t_ref        ms      Duration of refractory period
 V_th         mV      Spike threshold
 V_reset      mV      Reset potential of the membrane
 E_ex         mV      Excitatory reversal potential
 E_in         mV      Inhibitory reversal potential
 g_L          nS      Leak conductance
 tau_rise_ex  ms      Rise time of the excitatory synaptic beta function
 tau_decay_ex ms      Decay time of the excitatory synaptic beta function
 tau_rise_in  ms      Rise time of the inhibitory synaptic beta function
 tau_decay_in ms      Decay time of the inhibitory synaptic beta function
 I_e          pA      Constant input current
============= ====== =========================================================


Sends
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SpikeEvent

Receives
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SpikeEvent, CurrentEvent, DataLoggingRequest

References
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.. [1] Meffin H, Burkitt AN, Grayden DB (2004). An analytical
       model for the large, fluctuating synaptic conductance state typical of
       neocortical neurons in vivo. Journal of Computational Neuroscience,
       16:159-175.
       DOI: https://doi.org/10.1023/B:JCNS.0000014108.03012.81
.. [2] Bernander O, Douglas RJ, Martin KAC, Koch C (1991). Synaptic background
       activity influences spatiotemporal integration in single pyramidal
       cells.  Proceedings of the National Academy of Science USA,
       88(24):11569-11573.
       DOI: https://doi.org/10.1073/pnas.88.24.11569
.. [3] Kuhn A, Rotter S (2004) Neuronal integration of synaptic input in
       the fluctuation- driven regime. Journal of Neuroscience,
       24(10):2345-2356
       DOI: https://doi.org/10.1523/JNEUROSCI.3349-03.2004
.. [4] Rotter S,  Diesmann M (1999). Exact simulation of time-invariant linear
       systems with applications to neuronal modeling. Biologial Cybernetics
       81:381-402.
       DOI: https://doi.org/10.1007/s004220050570
.. [5] Roth A and van Rossum M (2010). Chapter 6: Modeling synapses.
       in De Schutter, Computational Modeling Methods for Neuroscientists,
       MIT Press.


See also
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:doc:`Neuron <index_neuron>`, :doc:`Integrate-And-Fire <index_integrate-and-fire>`, :doc:`Conductance-Based <index_conductance-based>`