.. _exact_integration: Integrating neural models using exact integration ================================================= The simple integrate-and fire model ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ For the simple integrate-and-fire model the voltage :math:`V` is given as a solution of the equation: .. math:: C\frac{dV}{dt}=I. This is just the derivative of the law of capacitance :math:`Q=CV`. When an input current is applied, the membrane voltage increases with time until it reaches a constant threshold :math:`V_{\text{th}}`, at which point a delta function spike occurs. A shortcoming of the simple integrate-and-fire model is that it implements no time-dependent memory. If the model receives a below-threshold signal at some time, it will retain that voltage boost until it fires again. This characteristic is not in line with observed neuronal behavior. The leaky integrate-and fire model ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ In the leaky integrate-and-fire model, the memory problem is solved by adding a "leak" term :math:`\frac{-1}{R}V` (:math:`R` is the resistance and :math:`\tau=RC`) to the membrane potential: .. math:: \frac{dV}{dt}=\frac{-1}{\tau}V+\frac{1}{C}I. :label: membrane This reflects the diffusion of ions that occurs through the membrane when some equilibrium is not reached in the cell. Solving a homogeneous linear differential equation ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ To solve :math:numref:`membrane` we start by looking at a simpler differential equation: .. math:: \frac{df}{dt}=af\text{, where } f:\mathbb{R}\to\mathbb{R} \text{ and } a\in\mathbb{R}. Here the solution is given by :math:`f(t)=e^{at}`. Solving a non-homogeneous linear differential equation ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When you add another function :math:`g` to the right hand side of our linear differential equation, .. math:: \frac{df}{dt}=af+g this is now a non-homogeneous differential equation. Things (can) become more complicated. Solving it with variation of constants ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ This kind of differential equation is usually solved with "variation of constants" which gives us the following solution: .. math:: f(t)=e^{ct}\int_{0}^t g(s)e^{-cs}ds. This is obviously not a particularly handy solution since calculating the integral in every step is very costly. Solving it with exact integration ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ With exact integration, these costly computations can be avoided. Restrictions to :math:`g` ------------------------- But only for certain functions :math:`g`! I.e. if :math:`g` satisfies (is a solution of): .. math:: \left(\frac{d}{dt}\right)^n g= \sum_{i=1}^{n}a_i\left(\frac{d}{dt}\right)^{i-1} g for some :math:`n\in \mathbb{N}` and a sequence :math:`(a_i)_{i\in\mathbb{N}}\subset \mathbb{R}`. For example this would be the case for :math:`g=\frac{e}{\tau_{syn}}t e^{-t/\tau_{\text{syn}}}` (an alpha funciton), where :math:`\tau_{\text{syn}}` is the rise time. Reformulating the problem ^^^^^^^^^^^^^^^^^^^^^^^^^ The non-homogeneous differential equation is reformulated as a multidimensional homogeneous linear differential equation: .. math:: \frac{d}{dt}y=Ay where .. math:: A=\begin{pmatrix} a_{n} & a_{n-1} & \cdots & \cdots & a_1 & 0 \\ 1 & 0 & \cdots & 0 & 0 & 0 \\ 0 & \ddots & \ddots & \vdots & \vdots & \vdots \\ \vdots & \ddots & \ddots & 0 & 0 & 0 \\ 0 & 0 & \ddots & 1 & 0 & 0 \\ 0 & 0 & \cdots & 0 & \frac{1}{C} & -\frac{1}{\tau} \\ \end{pmatrix} by choosing :math:`y_1,...,y_n` canonically as: .. math:: \begin{align*} y_1 &= \left(\frac{d}{dt}\right)^{n-1}g\\ \vdots &= \vdots\\ y_{n-1} &= \frac{d}{dt}g\\ y_{n} &= g\\ y_{n+1} &= f. \end{align*} This makes ist very easy to determine the solution as .. math:: y(t)= e^{At}y_0 and .. math:: y_{t+h}=y(t+h)=e^{A(t+h)}\cdot y_0=e^{Ah}\cdot e^{At}\cdot y_0=e^{Ah}\cdot y_t. This means that once we have calculated :math:`A`, propagation consists of multiplications only. Example: The leaky integrate and fire model with alpha-function shaped inputs (iaf_psc_alpha) ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ The dynamics of the membrane potential :math:`V` is given by: .. math:: \frac{dV}{dt}=\frac{-1}{\tau}V+\frac{1}{C}I where :math:`\tau` is the membrane time constant and :math:`C` is the capacitance. :math:`I` is the sum of the synaptic currents and any external input: Postsynaptic currents are alpha-shaped, i.e. the time course of the synaptic current :math:`\iota` due to one incoming spike is .. math:: \iota (t)= \frac{e}{\tau_{syn}}t e^{-t/\tau_{\text{syn}}}. The total input :math:`I` to the neuron at a certain time :math:`t` is the sum of all incoming spikes at all grid points in time :math:`t_i\le t` plus an additional piecewise constant external input :math:`I_{\text{ext}}`: .. math:: I(t)=\sum_{i\in\mathbb{N}, t_i\le t }\sum_{k\in S_{t_i}}\hat{\iota}_k \frac{e}{\tau_{\text{syn}}}(t-t_i) e^{-(t-t_i)/\tau_{\text{syn}}}+I_{\text{ext}} :math:`S_t` is the set of indices that deliver a spike to the neuron at time :math:`t`, :math:`\tau_{\text{syn}}` is the rise time and :math:`\iota_k` represents the "weight" of synapse :math:`k`. Exact integration for the iaf_psc_alpha model --------------------------------------------- First we make the substitutions: .. math:: \begin{align*} y_1 &= \frac{d}{dt}\iota+\frac{1}{\tau_{syn}}\iota \\ y_2 &= \iota \\ y_3 &= V \end{align*} for the equation .. math:: \frac{dV}{dt}=\frac{-1}{Tau}V+\frac{1}{C}\iota we get the homogeneous differential equation (for :math:`y=(y_1,y_2,y_3)^t`) .. math:: \frac{d}{dt}y= Ay= \begin{pmatrix} \frac{1}{\tau_{syn}}& 0 & 0\\ 1 & \frac{1}{\tau_{syn}} & 0\\ 0 & \frac{1}{C} & -\frac {1}{\tau} \end{pmatrix} y. The solution of this differential equation is given by :math:`y(t)=e^{At}y(0)` and can be solved stepwise for a fixed time step :math:`h`: .. math:: y_{t+h}=y(t+h)=e^{A(t+h)}y(0)=e^{Ah}e^{At}y(0)=e^{Ah}y(t)=e^{Ah}y_t. The complete update for the neuron can be written as .. math:: y_{t+h}=e^{Ah}y_t + x_{t+h} where .. math:: x_{t+h}+\begin{pmatrix}\frac{e}{\tau_{\text{syn}}}\\0\\0\end{pmatrix}\sum_{k\in S_{t+h}}\hat{\iota}_k as the linearity of the system permits the initial conditions for all spikes arriving at a given grid point to be lumped together in the term :math:`x_{t+h}`. :math:`S_{t+h}` is the set of indices :math:`k\in 1,....,K` of synapses that deliver a spike to the neuron at time :math:`t+h`. The matrix :math:`e^{Ah}` is constructed `in the C++ implementation of the iaf_psc_alpha model `_ in NEST. Every matrix entry is calculated twice. For inhibitory postsynaptic inputs (with a time constant :math:`\tau_{syn_{in}}`) and excitatory postsynaptic inputs (with a time constant :math:`\tau_{syn_{ex}}`). The update is performed `here `_. The first multiplication evolves the external input. The others are the multiplication of the matrix :math:`e^{Ah}` with :math:`y` (for inhibitory and excitatory inputs). If synaptic and membrane time constants become very close, :math:`\tau_m\approx \tau_{syn}`, the matrix :math:`e^{Ah}` becomes numerically unstable. NEST handles this gracefully as described in the `IAF Integration Singularity notebook <../model_details/IAF_Integration_Singularity.ipynb>`_. For more information see [1]_. References ~~~~~~~~~~ .. [1] Rotter V 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