Showing posts with label delay differential equations. Show all posts
Showing posts with label delay differential equations. Show all posts
Simulating neurons or how to solve delay differential equations in R
I discussed earlier how the action potential of a neuron can be modelled via the Hodgkin-Huxely equations. Here I will present a simple model that describes how action potentials can be generated and propagated across neurons. The tricky bit here is that I use delay differential equations (DDE) to take into account the propagation time of the signal across the network.
My model is based on the paper: Epileptiform activity in a neocortical network: a mathematical model by F. Giannakopoulos, U. Bihler, C. Hauptmann and H. J. Luhmann. The article presents a flexible and efficient modelling framework for:
My model is based on the paper: Epileptiform activity in a neocortical network: a mathematical model by F. Giannakopoulos, U. Bihler, C. Hauptmann and H. J. Luhmann. The article presents a flexible and efficient modelling framework for:
- large populations with arbitrary geometry
- different synaptic connections with individual dynamic characteristics
- cell specific axonal dynamics
13 Nov 2012
07:25
bursting
,
dede
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delay differential equations
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deSolve
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Dynamical Systems
,
FitzHugh-Nagumo
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Hodgkin-Huxley
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Hopf-Bifurcation
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neuron
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R
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Tutorials
