BrainPy is an integrative framework for computational neuroscience and brain-inspired computation. Three core functions are provided in BrainPy:
- General numerical solvers for ODEs and SDEs (support for DDEs and FDEs will come soon).
- Neurodynamics simulation tools for brain objects, such like neurons, synapses and networks (support for soma and dendrites will come soon).
- Neurodynamics analysis tools for differential equations, including phase plane analysis and bifurcation analysis (support for continuation analysis and sensitive analysis will come soon).
Moreover, BrainPy is designed to effectively satisfy your basic requirements:
- Easy to learn and use, because BrainPy is only based on Python language and has little dependency requirements;
- Highly flexible and transparent, because BrainPy endows the users with the fully data/logic flow control;
- Simulation can be guided with the analysis, because the same code in BrainPy can not only be used for simulation, but also for dynamics analysis;
- Efficient running speed, because BrainPy is compatible with the latest JIT compilers or any other accelerating framework you prefer (below we list the speed comparison based on Numba JIT).
BrainPy is a backend-independent neural simulator. Users can define models with any backend they prefer. Intrinsically, BrainPy supports the array/tensor-oriented backends such like NumPy, PyTorch, and TensorFlow, it also supports the JIT compilers such as Numba on CPU or CUDA devices. Extending BrainPy to support other backend frameworks you prefer is very easy. The details please see documents coming soon.
BrainPy is based on Python (>=3.7), and the following packages are required to be installed to use BrainPy:
- NumPy >= 1.13
- Matplotlib >= 3.3
Install BrainPy by using pip:
> pip install -U brainpy-simulatorInstall BrainPy by using conda:
> conda install brainpy-simulator -c brainpyInstall BrainPy from source:
> pip install git+https://github.com/PKU-NIP-Lab/BrainPy
> # or
> pip install git+https://git.openi.org.cn/OpenI/BrainPy
> # or
> pip install -e git://github.com/PKU-NIP-Lab/BrainPy.git@V1.0.0- Website (including documentations): https://brainpy.readthedocs.io/
- Source code: https://github.com/PKU-NIP-Lab/BrainPy or https://git.openi.org.cn/OpenI/BrainPy
- Bug reports: https://github.com/PKU-NIP-Lab/BrainPy/issues or Email to adaduo@outlook.com
- Examples from papers: https://brainmodels.readthedocs.io/en/latest/from_papers.html
Here list several simple examples for neurodynamics simulation and analysis. Comprehensive examples and tutorials please see BrainModels.
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The Hodgkin–Huxley neuron model. |
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The AMPA synapse model. |
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Implementation of the paper: Wang, Xiao-Jing, and György Buzsáki. “Gamma oscillation by synaptic inhibition in a hippocampal interneuronal network model.” Journal of neuroscience 16.20 (1996): 6402-6413. |
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Implementation of the paper: Van Vreeswijk, Carl, and Haim Sompolinsky. “Chaos in neuronal networks with balanced excitatory and inhibitory activity.” Science 274.5293 (1996): 1724-1726. |
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Implementation of the paper: Si Wu, Kosuke Hamaguchi, and Shun-ichi Amari. "Dynamics and computation of continuous attractors." Neural computation 20.4 (2008): 994-1025. |
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Phase plane analysis of the INa,p+-IK model, where "input" is 50., and "Vn_half" is -45.. |
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Codimension 1 bifurcation analysis of FitzHugh Nagumo model, in which "a" is equal to 0.7, and "Iext" is varied in [0., 1.]. |
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Codimension 2 bifurcation analysis of FitzHugh Nagumo model, in which "a" is varied in [0.5, 1.0], and "Iext" is varied in [0., 1.]. |