ANNarchy: a code generation approach to neural simulations on parallel hardware

Vitay, Julien, Dinkelbach, Helge Ülo, Hamker, Fred Henrik

07 October 2015

Many modern neural simulators focus on the simulation of networks of spiking neurons on parallel hardware. Another important framework in computational neuroscience, rate-coded neural networks, is mostly difficult or impossible to implement using these simulators. We present here the ANNarchy (Artificial Neural Networks architect) neural simulator, which allows to easily define and simulate rate-coded and spiking networks, as well as combinations of both. The interface in Python has been designed to be close to the PyNN interface, while the definition of neuron and synapse models can be specified using an equation-oriented mathematical description similar to the Brian neural simulator. This information is used to generate C++ code that will efficiently perform the simulation on the chosen parallel hardware (multi-core system or graphical processing unit). Several numerical methods are available to transform ordinary differential equations into an efficient C++code. We compare the parallel performance of the simulator to existing solutions.

Python

Netzwerk

Code

Parallelrechner

Technische Universität Chemnitz

Publikationsfonds

neural simulator

Python

rate-coded networks

spiking networks

parallel computing

code generation

Technische Universität Chemnitz

Publication funds

ddc:004

C++

Python

Netzwerk

Code

Parallelrechner

ANNarchy: a code generation approach to neural simulations on parallel hardware

Vitay, Julien, Dinkelbach, Helge Ülo, Hamker, Fred Henrik

07 October 2015

Many modern neural simulators focus on the simulation of networks of spiking neurons on parallel hardware. Another important framework in computational neuroscience, rate-coded neural networks, is mostly difficult or impossible to implement using these simulators. We present here the ANNarchy (Artificial Neural Networks architect) neural simulator, which allows to easily define and simulate rate-coded and spiking networks, as well as combinations of both. The interface in Python has been designed to be close to the PyNN interface, while the definition of neuron and synapse models can be specified using an equation-oriented mathematical description similar to the Brian neural simulator. This information is used to generate C++ code that will efficiently perform the simulation on the chosen parallel hardware (multi-core system or graphical processing unit). Several numerical methods are available to transform ordinary differential equations into an efficient C++code. We compare the parallel performance of the simulator to existing solutions.

info:eu-repo/classification/ddc/004

ddc:004