mcculloch_pitts_neuron – Binary deterministic neuron with Heaviside activation function


The mcculloch_pitts_neuron is an implementation of a binary neuron that is irregularly updated as Poisson time points [1]. At each update point the total synaptic input h into the neuron is summed up, passed through a Heaviside gain function \(g(h) = H(h-\theta)\), whose output is either 1 (if input is above) or 0 (if input is below threshold theta).

The time constant \(\tau_m\) is defined as the mean inter-update-interval that is drawn from an exponential distribution with this parameter. Using this neuron to reproduce simulations with asynchronous update [1], the time constant needs to be chosen as \(\tau_m = dt \times N\), where \(dt\) is the simulation time step and \(N\) the number of neurons in the original simulation with asynchronous update. This ensures that a neuron is updated on average every \(\tau_m\) ms. Since in the original paper [1] neurons are coupled with zero delay, this implementation follows this definition. It uses the update scheme described in [3] to maintain causality: The incoming events in time step \(t_i\) are taken into account at the beginning of the time step to calculate the gain function and to decide upon a transition. In order to obtain delayed coupling with delay \(d\), the user has to specify the delay \(d+h\) upon connection, where \(h\) is the simulation time step.

See also [2].




Membrane time constant (mean inter-update-interval)



Threshold for sigmoidal activation function

Special requirements for binary neurons

As the mcculloch_pitts_neuron is a binary neuron, the user must ensure that the following requirements are observed. NEST does not enforce them. Breaching the requirements can lead to meaningless results.

  1. Binary neurons must only be connected to other binary neurons.

  2. No more than one connection must be created between any pair of binary neurons. When using probabilistic connection rules, specify 'allow_autapses': False to avoid accidental creation of multiple connections between a pair of neurons.

  3. Binary neurons can be driven by current-injecting devices, but not by spike generators.

  4. Activity of binary neurons can only be recored using a spin_detector or correlospinmatrix_detector.




See also

Neuron, Binary

Examples using this model