⚠ Warning: This project is work-in progress. Everything described here, including the name of the project and the API, is subject to change.
NengoBio is an add-on library for the Nengo spiking neural network simulator. Nengo is used by scientists to construct detailed models of neurobiological systems. However, Nengo and, to some degree, the underlying Neural Engineering Framework, have restrictions that limit the biological plausibility of the created networks. NengoBio lifts some of these restrictions by implementing the following:
- Dale's Principle (:ballot_box_with_check: Fully implemented)
While it is possible to work around this limitation, Nengo usually does not explicitly mark neurons as excitatory or inhibitory. This means that a single can connect to post-neurons both excitatorily and inhibitorily, depending on the sign of the weights computed by of the weight solver. NengoBio marks neurons as either excitatory or inhibitory and accounts for this while solving for connection weights. - Bias current elimination (:ballot_box_with_check: Fully implemented)
The Neural Engineering Framework assumes that each neuron is connected to a constant bias current source. This bias current is used to diversify the avilable neuron tuning curves, yet is a little unrealistic from a biological perspective. NengoBio eliminates the bias current by solving for synaptic weights in current space, effectively decoding the bias current from the pre-population state. - Support for dendritic computation (:ballot_box_with_check: Fully implemented)
Dendritic nonlinearities play a key role in information processing in central nervous systems and can be systematically exploited to perfrom nonlinear, multivariate computations. NengoBio adds support for dendritic computation to Nengo by allowing an arbitrary number of neuron ensembles as pre-objects in a connection. - Support for conductance-based synapses as well as neurons with arbitrary passive dendritic trees (Planned) Dendritic computation relies on nonlinear effects in the dendritic tree and the specific tree topology. NengoBio adds support for arbitrary passive multicompartment neuron models to Nengo.
Dependencies: NengoBio requires Python 3 and depends on numpy>=1.16.3, scipy>=1.2.0, cvxopt>=1.2.2, nengo>=3.0.0.dev0.
Clone this repository by running
git clone https://github.com/astoeckel/nengo_bioYou can then install the package by running the following inside the nengo_bio repository
pip3 install -e .This will automatically install all dependencies. Note that NengoBio currently requires the most recent development version of Nengo, which has to be installed separately.
Assuming that you know how to use Nengo, using NengoBio should be quite simple. Just add the following to your list of imports
import nengo_bio as bioand replace nengo.Ensemble with bio.Ensemble and nengo.Connection with bio.Connection where applicable.
The bio.Ensemble class acts like a normal Nengo ensemble but has two additional parameters: p_exc and p_inh. These parameters describe the relative number of excitatory/inhibitory neurons in the population. Note that p_exc and p_inh have to sum to one. These parameters are only relevant if an ensemble is a pre-object.
Note: Neurons will be assigned a synapse type at build time. If any of p_exc or p_inh is set, each neuron will either be excitatory or inhibitory. Without p_exc and p_inh, the ensemble will behave just like a normal Nengo ensemble.
Warning: bio.Ensemble can be used in conjunction with the normal nengo.Connection class. The excitatory/inhibitory nature of the neurons in a bio.Ensemble will only be taken into account when using bio.Connection (see below).
Examples 1: An ensemble exclusively consisting of excitatory neurons
ens_exc = bio.Ensemble(n_neurons=101, dimensions=1, p_exc=1.0)Examples 2: An ensemble exclusively consisting of inhibitory neurons
ens_inh = bio.Ensemble(n_neurons=101, dimensions=1, p_inh=1.0)Examples 3: An ensemble consisting of 80% excitatory and 20% inhibitory neurons (both lines are equivalent):
ens_mix = bio.Ensemble(n_neurons=101, dimensions=1, p_exc=0.8)
ens_mix = bio.Ensemble(n_neurons=101, dimensions=1, p_inh=0.2)A bio.Connection connection connects n-pre ensembles to a single target ensemble. It will automatically account for the synapse type assigned to each neuron.
-
pre: This can be either a single pre-population or a tuple of pre-populations. The dimensions of the values represented by the pre-populations will be stacked. -
decode_bias(defaultTrue): ifTruethe post-neuron bias current will be decoded from the pre-population instead of being assumed constant. Set this toFalsefor any but the firstbio.connectiontargeting the same post population. -
solver(defaultQPSolver()): anExtendedSolverinstance fromnengo_bio.solvers.ExtendedSolverscan solve for currents and take neuron parameters into account.
Example 1: Simple communication channel between ens_a and ens_b taking neuron/synapse types into account and decoding the bias current:
bio.Connection(ens_a, ens_b)Example 2: 2D communication channel where ens_a, ens_b represent a one-dimensional value and ens_c represents a two-dimensional value.
bio.Connection((ens_a, ens_b), ens_c)Example 3: Linear "Dendritic Computation"
bio.Connection((ens_a, ens_b), ens_c, function=lambda x: np.mean(x))The techniques used in this library are described in more detail in this arXiv preprint: https://arxiv.org/abs/1904.11713. We would appreciate it if you could cite this paper in case you use this library in a published model.
@misc{stoeckel2019passive,
author = {Andreas Stöckel and Chris Eliasmith},
title = {Passive nonlinear dendritic interactions as a general computational resource in functional spiking neural networks},
year = {2019},
eprint = {arXiv:1904.11713},
}nengo_bio -- Extensions to Nengo for more biological plausibility
Copyright (C) 2019 Andreas Stöckel
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