Last updated:
0 purchases
brainpy 2.6.0.post20240803
BrainPy is a flexible, efficient, and extensible framework for computational neuroscience and brain-inspired computation based on the Just-In-Time (JIT) compilation (built on top of JAX, Taichi, Numba, and others). It provides an integrative ecosystem for brain dynamics programming, including brain dynamics building, simulation, training, analysis, etc.
Website (documentation and APIs): https://brainpy.readthedocs.io/en/latest
Source: https://github.com/brainpy/BrainPy
Bug reports: https://github.com/brainpy/BrainPy/issues
Source on OpenI: https://git.openi.org.cn/OpenI/BrainPy
Installation
BrainPy is based on Python (>=3.8) and can be installed on Linux (Ubuntu 16.04 or later), macOS (10.12 or later), and Windows platforms.
For detailed installation instructions, please refer to the documentation: Quickstart/Installation
Using BrainPy with docker
We provide a docker image for BrainPy. You can use the following command to pull the image:
$ docker pull brainpy/brainpy:latest
Then, you can run the image with the following command:
$ docker run -it --platform linux/amd64 brainpy/brainpy:latest
Using BrainPy with Binder
We provide a Binder environment for BrainPy. You can use the following button to launch the environment:
Ecosystem
BrainPy: The solution for the general-purpose brain dynamics programming.
brainpy-examples: Comprehensive examples of BrainPy computation.
brainpy-datasets: Neuromorphic and Cognitive Datasets for Brain Dynamics Modeling.
《神经计算建模实战》 (Neural Modeling in Action)
第一届神经计算建模与编程培训班 (First Training Course on Neural Modeling and Programming)
第二届神经计算建模与编程培训班 (Second Training Course on Neural Modeling and Programming)
Citing
BrainPy is developed by a team in Neural Information Processing Lab at Peking University, China.
Our team is committed to the long-term maintenance and development of the project.
If you are using brainpy, please consider citing the corresponding papers.
Ongoing development plans
We highlight the key features and functionalities that are currently under active development.
We also welcome your contributions
(see Contributing to BrainPy).
model and data parallelization on multiple devices for dense connection models
model parallelization on multiple devices for sparse spiking network models
data parallelization on multiple devices for sparse spiking network models
pipeline parallelization on multiple devices for sparse spiking network models
multi-compartment modeling
measurements, analysis, and visualization methods for large-scale spiking data
Online learning methods for large-scale spiking network models
Classical plasticity rules for large-scale spiking network models
For personal and professional use. You cannot resell or redistribute these repositories in their original state.
There are no reviews.