This repository allows you to solve forward and inverse problems related to partial differential equations (PDEs) using finite basis physics-informed neural networks (FBPINNs).
🔥 MAJOR UPDATE 🔥: we have rewritten the
fbpinns
library in JAX: it now runs 10-1000X faster than the original PyTorch code (by parallelising subdomain computations usingjax.vmap
) and scales to 1000s+ subdomains. We have also added extra functionality: you can now solve inverse problems, add arbitrary types of boundary/data constraints, define irregular/multilevel domain decompositions and custom subdomain networks, and the high-level interface is much more flexible and easier to use. See the Release note for more info.
FBPINNs are described in detail here: Finite Basis Physics-Informed Neural Networks (FBPINNs): a scalable domain decomposition approach for solving differential equations, B. Moseley, T. Nissen-Meyer and A. Markham, Jul 2023 Advances in Computational Mathematics. See the slides from our 2023 Maths4DL conference talk here.
Fig 1: FBPINN vs PINN solving the high-frequency 1D harmonic oscillator
- Physics-informed neural networks (PINNs) are a popular approach for solving forward and inverse problems related to PDEs
- However, PINNs often struggle to solve problems with high frequencies and/or multi-scale solutions
- This is due to the spectral bias of neural networks and the heavily increasing complexity of the PINN optimisation problem
- FBPINNs improve the performance of PINNs in this regime by combining them with domain decomposition, individual subdomain normalisation and flexible subdomain training schedules
- Empirically, FBPINNs significantly outperform PINNs (in terms of accuracy and computational efficiency) when solving problems with high frequencies and multi-scale solutions (Fig 1 and 2)
Fig 2: FBPINN solution of the (2+1)D wave equation with multiscale sources
Fig 3: FBPINN workflow overview
To improve the scalability of PINNs to high frequency/ multiscale solutions:
-
FBPINNs divide the problem domain into many small, overlapping subdomains (Fig 3).
-
A neural network is placed within each subdomain, and the solution to the PDE is defined as the summation over all subdomain networks.
-
Each subdomain network is locally confined to its subdomain by multiplying it by a smooth, differentiable window function.
-
Finally, the inputs of each network are individually normalised over their subdomain.
The hypothesis is that this "divide and conquer" approach significantly reduces the complexity of the PINN optimisation problem. Furthermore, individual subdomain normalisation ensures the "effective" frequency each subdomain network sees is low, reducing the effect of spectral bias.
Fig 4: Solving the time-dependent Burgers' equation using a time-stepping subdomain scheduler
Another advantage of using domain decomposition is that we can control which parts of the domain are solved at each training step.
This is useful if we want to control how boundary conditions are communicated across the domain.
For example, we can define a time-stepping scheduler to solve time-dependent PDEs, and learn the solution forwards in time from a set of initial conditions (Fig 4).
This is done by specifying a subdomain scheduler (from fbpinns.schedulers
), which defines which subdomains are actively training and which subdomains have fixed parameters at each training step.
fbpinns
only requires Python libraries to run.
JAX is used as the main computational engine for
fbpinns
.
To install fbpinns
, we recommend setting up a new Python environment, for example:
conda create -n fbpinns python=3 # Using conda
conda activate fbpinns
then cloning this repository:
git clone git@github.com:benmoseley/FBPINNs.git
and running this command in the base FBPINNs/
directory (will also install all of the dependencies):
pip install -e .
Note this installs the
fbpinns
package in "editable mode" - you can make changes to the source code and they are immediately present in the package.
Forward and inverse PDE problems are defined and solved by carrying out the following steps:
- Define the problem domain, by selecting or defining your own
fbpinns.domains.Domain
class - Define the PDE to solve, and any problem constraints (such as boundary conditions or data constraints), by selecting or defining your own
fbpinns.problems.Problem
class - Define the domain decomposition used by the FBPINN, by selecting or defining your own
fbpinns.decompositions.Decomposition
class - Define the neural network placed in each subdomain, by selecting or defining your own
fbpinns.networks.Network
class - Keep track of all the training hyperparameters by passing these classes and their initialisation values to a
fbpinns.constants.Constants
object - Start the FBPINN training by instantiating a
fbpinns.trainers.FBPINNTrainer
using theConstants
object.
For example, to solve the 1D harmonic oscillator problem shown above (Fig 1):
import numpy as np
from fbpinns.domains import RectangularDomainND
from fbpinns.problems import HarmonicOscillator1D
from fbpinns.decompositions import RectangularDecompositionND
from fbpinns.networks import FCN
from fbpinns.constants import Constants
from fbpinns.trainers import FBPINNTrainer
c = Constants(
domain=RectangularDomainND,# use a 1D problem domain [0, 1]
domain_init_kwargs=dict(
xmin=np.array([0,]),
xmax=np.array([1,]),
),
problem=HarmonicOscillator1D,# solve the 1D harmonic oscillator problem
problem_init_kwargs=dict(
d=2, w0=80,# define the ODE parameters
),
decomposition=RectangularDecompositionND,# use a rectangular domain decomposition
decomposition_init_kwargs=dict(
subdomain_xs=[np.linspace(0,1,15)],# use 15 equally spaced subdomains
subdomain_ws=[0.15*np.ones((15,))],# with widths of 0.15
unnorm=(0.,1.),# define unnormalisation of the subdomain networks
),
network=FCN,# place a fully-connected network in each subdomain
network_init_kwargs=dict(
layer_sizes=[1,32,1],# with 2 hidden layers
),
ns=((200,),),# use 200 collocation points for training
n_test=(500,),# use 500 points for testing
n_steps=20000,# number of training steps
optimiser_kwargs=dict(learning_rate=1e-3),
show_figures=True,# display plots during training
)
run = FBPINNTrainer(c)
run.train()# start training the FBPINN
The FBPINNTrainer
will automatically start outputting training statistics, plots and tensorboard summaries. The tensorboard summaries can be viewed by installing tensorboard and then running tensorboard --logdir results/summaries/
You can easily train a PINN using the same hyperparameters above, using:
from fbpinns.trainers import PINNTrainer
c["network_init_kwargs"] = dict(layer_sizes=[1,64,64,1])# use a larger neural network
run = PINNTrainer(c)
run.train()# start training a PINN on the same problem
See the examples folder for more advanced examples covering:
- how to define your own
Problem
class - how to use hard boundary constraints
- how to solve an inverse problem
- how to use subdomain scheduling
I get the error: RuntimeError: This version of jaxlib was built using AVX instructions, which your CPU and/or operating system do not support.
when using Apple GPUs.
- As of this commit, JAX only has experimental support for Apple GPUs. Either build JAX from source or install a CPU-only version using conda:
pip uninstall jax jaxlib
andconda install jax -c conda-forge
How do I train FBPINNs using a GPU?
- Exactly the same code should run on a GPU automatically, without needing any modification. Make sure you have installed the GPU version of JAX, and that JAX can see your GPU devices (e.g. by checking
jax.devices()
)
But I don't know JAX!?
- We highly recommend becoming familiar with JAX - it is a fantastic, general-purpose library for accelerated differentiable computing. But even if you don't want to learn JAX, that's ok - all of the front-end classes (
Domain
,Problem
,Decomposition
, andNetwork
) can be defined with only basic understanding ofjax.numpy
(which is essentially the same asnumpy
anyway).
How are FBPINNs different to other PINN + domain decomposition methods?
- In contrast to other PINN + domain decomposition methods (such as XPINNs), FBPINNs by their mathematical construction do not require additional interface terms in their loss function, and their solution is continuous across subdomain interfaces. Essentially, FBPINNs can just be thought of as defining a custom neural network architecture for PINNs - everything else stays the same.
If you find FBPINNs useful and use them in your own work, please use the following citations:
@article{Moseley2023,
author = {Moseley, Ben and Markham, Andrew and Nissen-Meyer, Tarje},
doi = {10.1007/S10444-023-10065-9},
journal = {Advances in Computational Mathematics 2023 49:4},
month = {jul},
number = {4},
pages = {1--39},
publisher = {Springer},
title = {{Finite basis physics-informed neural networks (FBPINNs): a scalable domain decomposition approach for solving differential equations}},
url = {https://link.springer.com/article/10.1007/s10444-023-10065-9},
volume = {49},
year = {2023}
}
@article{Dolean2024,
author = {Dolean, Victorita and Heinlein, Alexander and Mishra, Siddhartha and Moseley, Ben},
doi = {https://doi.org/10.1016/j.cma.2024.117116},
issn = {0045-7825},
journal = {Computer Methods in Applied Mechanics and Engineering},
pages = {117116},
title = {{Multilevel domain decomposition-based architectures for physics-informed neural networks}},
url = {https://www.sciencedirect.com/science/article/pii/S0045782524003724},
volume = {429},
year = {2024}
}
To reproduce the exact results of our original FBPINN paper: Finite Basis Physics-Informed Neural Networks (FBPINNs): a scalable domain decomposition approach for solving differential equations, B. Moseley, T. Nissen-Meyer and A. Markham, Jul 2023 Advances in Computational Mathematics, you will need to use the legacy PyTorch FBPINN implementation, which is available at this commit.
To reproduce the results of our paper: Multilevel domain decomposition-based architectures for physics-informed neural networks, please see this branch.
Please raise a GitHub issue or feel free to contact us.