SciANN is a Keras wrapper for scientific computations and physics-informed deep learning.
SciANN is a high-level artificial neural networks API, written in Python using Keras and TensorFlow backends. It is developed with a focus on enabling fast experimentation with different networks architectures and with emphasis on scientific computations, physics informed deep learing, and inversion. Being able to start deep-learning in a very few lines of code is key to doing good research.
Use SciANN if you need a deep learning library that:
- Allows for easy and fast prototyping.
- Allows the use of complex deep neural networks.
- Takes advantage TensorFlow and Keras features including seamlessly running on CPU and GPU.
For more details, check out our review paper at https://arxiv.org/abs/2005.08803 and the documentation at SciANN.com.
Cite SciANN in your publications if it helps your research:
@article{haghighat2021sciann,
title={SciANN: A Keras/TensorFlow wrapper for scientific computations and physics-informed deep learning using artificial neural networks},
author={Haghighat, Ehsan and Juanes, Ruben},
journal={Computer Methods in Applied Mechanics and Engineering},
volume={373},
pages={113552},
year={2021},
publisher={Elsevier}
}
SciANN is compatible with: Python 2.7-3.6.
Have questions or like collaborations, email Ehsan Haghighat.
The core data structure of SciANN is a Functional
, a way to organize inputs (Variables
) and outputs (Fields
) of a network.
Targets are imposed on Functional
instances using Constraint
s.
The SciANN model (SciModel
) is formed from inputs (Variables
) and targets(Constraints
). The model is then trained by calling the solve
function.
Here is the simplest SciANN
model:
from sciann import Variable, Functional, SciModel
from sciann.constraints import Data
x = Variable('x')
y = Functional('y')
# y_true is a Numpy array of (N,1) -- with N as number of samples.
model = SciModel(x, Data(y))
This is associated to the simplest neural network possible, i.e. a linear relation between the input variable x
and the output variable y
with only two parameters to be learned.
Plotting a network is as easy as passing a file_name to the SciModel:
model = SciModel(x, Data(y), plot_to_file='file_path')
Once your model looks good, perform the learning with .solve()
:
# x_true is a Numpy array of (N,1) -- with N as number of samples.
model.train(x_true, y_true, epochs=5, batch_size=32)
You can iterate on your training data in batches and in multiple epochs. Please check Keras documentation on model.fit
for more information on possible options.
You can evaluate the model any time on new data:
classes = model.predict(x_test, batch_size=128)
In the application folder of the repository, you will find some examples of Linear Elasticity, Flow, Flow in Porous Media, etc.
Before installing SciANN, you need to install the TensorFlow and Keras.
You may also consider installing the following optional dependencies:
- cuDNN (recommended if you plan on running Keras on GPU).
- HDF5 and h5py (required if you plan on saving Keras/SciANN models to disk).
- graphviz and pydot (used by visualization utilities to plot model graphs).
Then, you can install SciANN itself. There are two ways to install SciANN:
- Install SciANN from PyPI (recommended):
Note: These installation steps assume that you are on a Linux or Mac environment.
If you are on Windows, you will need to remove sudo
to run the commands below.
sudo pip install sciann
If you are using a virtualenv, you may want to avoid using sudo:
pip install sciann
- Alternatively: install SciANN from the GitHub source:
First, clone SciANN using git
:
git clone https://github.com/sciann/sciann.git
Then, cd
to the SciANN folder and run the install command:
sudo python setup.py install
or
sudo pip install .
Scientific Computational with Artificial Neural Networks.
Scientific computations include solving ODEs, PDEs, Integration, Differentiation, Curve Fitting, etc.