Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations

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Presented by

Cameron Meaney

Introduction

In recent years, there has been an enormous growth in the amount of data and computing power available to researchers. Unfortunately, for many real-world scenarios, the cost of data acquisition is simply too high to collect an amount of data sufficient to guarantee robustness or convergence of training algorithms. In such situations, researchers are faced with the challenge of trying to generate results based on partial or incomplete datasets. Regularization techniques or methods, which can artificially inflate the dataset, become particularly useful in these situations; however, such techniques are often highly dependent on the specifics of the problem.

Luckily, in important real-world scenarios that we endeavor to analyze, there is often a wealth of existing information from which we can draw. This existing information commonly manifests in the form of a mathematical model, particularly a set of partial differential equations (PDEs). In this paper, the authors provide a technique for incorporating the information of a physical system contained in a PDE into the optimization of a deep neural network. This technique is most useful in situations where established PDE models exist, but where our amount of available data is too small to guarantee the robustness of convergence in neural network training. In essence, the accompanying PDE model can be used as a regularization agent, constraining the space of acceptable solutions to help the optimization converge more quickly and more accurately.

Problem Setup

Consider the following general PDE,

\begin{align*} u_t + N[u;\vec{\lambda}] = 0, \end{align*}

where [math]\displaystyle{ u }[/math] is the function we wish to find, subscripts denote partial derivatives, [math]\displaystyle{ \vec{\lambda} }[/math] is the set of parameters on which the PDE depends, and [math]\displaystyle{ N }[/math] is a differential, potentially nonlinear operator. This general form encompasses a wide array of PDEs used across the physical sciences including conservation laws, diffusion processes, advection-diffusion-reaction systems, and kinetic equations. Suppose that we have noisy measurements of the PDE solution, [math]\displaystyle{ u }[/math], scattered across the spatio-temporal input domain. Then, we are interested in answering two questions about the physical system:

(1) Given fixed model parameters, [math]\displaystyle{ \vec{\lambda} }[/math], what can be said about the unknown hidden state [math]\displaystyle{ u(t,x) }[/math]?

and

(2) What set of parameters, [math]\displaystyle{ \vec{\lambda} }[/math], best describes the observed data for this PDE system?

Data-Driven Solutions of PDEs

We will begin by attempting to answer the first of the questions above. Specifically, if given a small number of noisy measurements of the solution of the PDE

\begin{align*} u_t + N[u] = 0, \end{align*}

can we estimate the full solution, [math]\displaystyle{ u(t,x) }[/math], by approximating it with a deep neural network? Note that [math]\displaystyle{ \vec{\lambda} }[/math] no longer appears in the operator because we assume those values to be known. Approximating the solution of the PDE with neural network results in what the authors refer to as a 'Physics-Informed Neural Network' (PINN). Importantly, this technique is most useful when we are in the small-data regime - for if we had lots of data, it simply wouldn't be necessary to include information from the PDE because the data alone would be sufficient. In these examples, we are seeking to learn from a very small amount of data which makes information from the PDE necessary to include in order to generate meaningful results.

The paper details two cases of data: continuous-time and discrete-time. Both cases are detailed individually below.


Continuous-Time Models

Consider the case where our noisy measurements of the solution are randomly scattered across the Spatio-temporal input domain. This case is referred to as the continuous-time case. We define the function

\begin{align*} f = u_t + N[u] \end{align*}

as the left-hand side of the PDE above. Now assume that the PDE solution, [math]\displaystyle{ u(t,x) }[/math], can be approximated by a deep neural network. Therefore, the function [math]\displaystyle{ f(t,x) }[/math] can also be approximated by a neural network since it is simply a function of [math]\displaystyle{ u(t,x) }[/math]. In order to calculate [math]\displaystyle{ f(t,x) }[/math] as a function of [math]\displaystyle{ u(t,x) }[/math], derivatives of the network [math]\displaystyle{ u(t,x) }[/math] will need to be taken with respect to its inputs. This network differentiation is accomplished using a technique called automatic differentiation [2]. Importantly, the weights of the two neural networks will be shared, since [math]\displaystyle{ f(t,x) }[/math] is simply a function of [math]\displaystyle{ u(t,x) }[/math]. The key idea in finding this shared set of weights is to train the networks with a loss function that has two distinct parts. The first part quantifies how well the neural network satisfies the known data points and is given by:

\begin{align*} MSE_u = \frac{1}{N_u} \sum_{i=1}^{N_u} [u(t_u^i,x_u^i) - u^i]^2 \end{align*}

where the summation is over the set of known data points. The second part of the loss function quantifies how well the neural network satisfies the PDE and is given by:

\begin{align*} MSE_f = \frac{1}{N_u} \sum_{i=1}^{N_u} [f(t_u^i,x_u^i)]^2. \end{align*}

Notice that since [math]\displaystyle{ f }[/math] is all the PDE terms moved to one side of the equation, the closer that [math]\displaystyle{ f }[/math] is to zero, the better that the neural network satisfies to PDE. The full loss function used in the optimization is then taken to be the sum of these two parts:

\begin{align*} MSE = MSE_u + MSE_f. \end{align*}

By using this loss function in the optimization, information from both the known data and the known physics (from PDE) can be incorporated into the neural network. This effectively regularizes the optimization, allowing for the network to learn from a smaller number of data points than would otherwise be necessary. An example of this method can be seen in the example below including figures 1 and 2.

Discrete-Time Models

Now consider the case where our available data is not randomly scattered across the spatio-temporal domain, but rather only present at two particular times. This is known as the discrete-time case and occurs frequently in real-world examples such as when dealing with discrete pictures or medical images with no data between them. This case can be dealt with in the same manner as the continuous case with a few small adjustments. To adapt the PINN technique to discrete-time models, we must leverage Runge-Kutta methods - a technique for numerical solutions of differential equations. Runge-Kutta methods approximate the solution of a differential equation at the next numerical time step by first approximating the solution at a set of intermediate points between the time steps, then using these values to predict the value of the function at the full time step. The number of intermediate points used to predict the end solution is called the stages of the Runge-Kutta method - for example, a method where four intermediate values are approximated is called a four-stage method.. The general form of a Runge-Kutta method with [math]\displaystyle{ q }[/math] stages is given by:

\begin{align*} u^{n+c_i} &= u^n - \Delta t \sum^q_{j=1} a_{ij} N[u^{n+c_j}], ~ i = 1,...,q \\ u^{n+1} &= u^n - \Delta t \sum^q_{j=1} b_j N[u^{n+c_j}] \end{align*}

where [math]\displaystyle{ u^{n+c_j} = u(t^n + c_j \Delta t, x) }[/math] and [math]\displaystyle{ u^{n+1} = u(t^{n+1}, x) }[/math] (note that [math]\displaystyle{ c_j\lt 1 ~ \forall ~ j=1,...,q }[/math]). This general form includes both explicit and implicit time-stepping schemes.

In the continuous-time case, we had approximated the function [math]\displaystyle{ u(t,x) }[/math] by a neural network and trained a shared set of weights belonging to [math]\displaystyle{ u(t,x) }[/math] and [math]\displaystyle{ f(t,x) }[/math]. Therefore, our neural network approximation for [math]\displaystyle{ u(t,x) }[/math] had two inputs and one output. In the discrete case, instead of creating a neural netowrk which takes [math]\displaystyle{ t }[/math] and [math]\displaystyle{ x }[/math] as input and outputs the value of [math]\displaystyle{ u(t,x) }[/math], we create a neural network which only takes [math]\displaystyle{ x }[/math] as input and outputs all of the intermediate stages of the Runge-Kutta time-stepping scheme, [math]\displaystyle{ [u^{n+c_j}] }[/math] for [math]\displaystyle{ i=1,...,q }[/math]. Therefore, the PINN that we create here has one input and [math]\displaystyle{ q }[/math] outputs. Importantly, information from the PDE is now incorporated into the Runge-Kutta time-stepping scheme, so we do not need to add a term to the loss function to include it. Instead, our discrete-time loss function consists of two parts - one to quantify agreement with the data at the time of the initial data snapshot and one to quantify the agreement with data at the final data snapshot. To find the predictions at the two snapshots, the Runge-Kutta will need to be inverted and solved for the initial and final cases as functions of the stages, which is easily done. However, notice that each Runge-Kutta stage produces its own prediction for the snapshots, so our loss function will need to incorporate all of these predictions. Accordingly, our new loss function becomes:

\begin{align*} SSE = SSE_n + SSE_{n+1} \end{align*}

where

\begin{align*} SSE_n = \sum^q_{j=1} \sum^{N_n}_{i=1} (u^n_j(x^{n,i}) - u^{n,i})^2, \end{align*}

\begin{align*} SSE_{n+1} = \sum^q_{j=1} \sum^{N_{n+1}}_{i=1} (u^{n+1}_j(x^{n+1,i}) - u^{n+1,i})^2, \end{align*}

[math]\displaystyle{ N_n }[/math] is the number of data points at [math]\displaystyle{ t_n }[/math], and [math]\displaystyle{ N_{n+1} }[/math] is the number of data points at [math]\displaystyle{ t_{n+1} }[/math]. For an example of the discrete-time data case, see the example below including figure 3.

Data-Driven Discovery of PDEs

After having answered the first question, we can turn our focus to the second question. Specifically, if given a small amount of noisy measurements of the solution of the PDE

\begin{align*} u_t + N[u;\vec{\lambda}] = 0, \end{align*}

can we estimate the values of the parameters, [math]\displaystyle{ \vec{\lambda} }[/math], that best describe the observed data? The principle difference now is that we no longer know the values of the parameters [math]\displaystyle{ \vec{\lambda} }[/math] appearing in the PDE. In conventional modelling, a parameter estimation technique would need to be first applied to the dataset which would rely on assuming the form of the PDE. Conventional parameter fitted techniques are often sensitive to noisy data, leading to errors in results generated with these fitted parameters. However, with PINNs, this parameter fitting can be done simultaneously with the training of the neural network. This change in procedure allows our parameter fitting to not simply identify the parameters that best fit the data given the PDE, but rather to find the parameters which best describe the data while using the PDE as a regularizer. The neural network training procedure is, in essence, unchanged other than we now treat the PDE parameters as trainable parameters of the neural network. Since the discovery case outlined here is an extension of the solution case outlined above, the examples given below include unknown parameters and therefore cover the full procedure.

Examples

While many examples are given in the paper, three particular ones are detailed here to demonstrate the simplicity and utility of the PINN method.

Continuous-Time Example

For an example of the continuous-time method in action, consider a problem involving Burger's equation, given by:

\begin{align*} &u_t + uu_x - (0.01/\pi)u_{xx} = 0, ~ x \in [-1,1], ~ t \in [0,1], \\ &u(0,x) = -\sin(\pi x), \\ &u(t, -1) = u(t,1) = 0. \end{align*}

Notably, Burger's equation is known as a challenging problem to solve using conventional methods because of the shock (discontinuity) formation after sufficiently large time. However, using PINNs, this shockwave is easily handled.

Assume that we are given noisy measurements of the solution of Burger's equation scattered across the spatio-temporal domain. Also assume that we do not know the values of the parameters in Burger's equation - we only know the equation form:

\begin{align*} &u_t + \lambda_1 uu_x - \lambda_2 u_{xx} = 0. \end{align*}

Additionally, we also assume that we are ignorant of the initial conditions and boundary conditions which generate the solution. Importantly, information from the initial and boundary conditions is contained in the known data points. We define the function [math]\displaystyle{ f(t,x) }[/math] as:

\begin{align*} f = u_t + \lambda_1 uu_x - \lambda_2 u_{xx} \end{align*}

and assume that [math]\displaystyle{ u(t,x) }[/math] is approximated by a deep neural network - hence creating a PINN. Then, the shared parameters of the neural networks for [math]\displaystyle{ u(t,x) }[/math] and [math]\displaystyle{ f(t,x) }[/math] as well as the parameters [math]\displaystyle{ \lambda_1 }[/math] and [math]\displaystyle{ \lambda_2 }[/math] are simultaneously learned by minimizing the combined loss function [math]\displaystyle{ MSE = MSE_u + MSE_f }[/math] as defined above.

For this example, assume that we have 2000 data points across the entire spatio-temporal domain (representing a mere 2.0% of the known data). The correct values of the parameters which are used to generate the data points are [math]\displaystyle{ \lambda_1 = 1.0 }[/math] and [math]\displaystyle{ \lambda_2 = 0.01/\pi }[/math]. Also assume that the value of the solution for each of the known data points is randomly perturbed by up to 1% of its value - making the dataset noisy. This problem is trained using the procedure outlined above with a deep neural network of 9 layers with 20 neurons per hidden layer and using the L-BFGS optimizer.

The results of this example can be seen in figure 1. In the top panel, the exact solution can be seen with the data points selected for training pointed out. In the middle panel, a comparison of the exact and predicted solutions can be seen for three different times showing the accuracy of the PINN prediction. In the bottom panel, a comparison of the exact and predicted parameter values can also be seen. Also included in this bottom panel is the parameter predictions for the noiseless data case for comparison. Notice the remarkable accuracy with which the PINN is able to predict the full solution and the correct parameter values in both noisy and noiseless cases. In figure 2, a comparison of the error in the predicted parameter values for different amounts of known data and noise is shown.

Figure 1

Figure 2

Discrete-Time Example

For a discrete-time example, let us again consider the Burger's equation but only allow ourselves data at two time snapshots. Specifically, our known data consists of 199 points at time [math]\displaystyle{ t=0.1 }[/math] and 201 points at time [math]\displaystyle{ t=0.9 }[/math]. The correct parameter values and dataset noise is the same as in the continuous case and the procedure is as explained in the discrete-time section above. The neural network consists of four layers with 50 neurons per hidden layer. We choose the number of Runge-Kutta stages to be [math]\displaystyle{ q=500 }[/math], meaning that we approximate the solution at 500 intermediate time points. Note that the theoretical error estimates for a Runge-Kutta scheme with 500 stages is far below machine precision (truncation error of [math]\displaystyle{ O(\Delta t^{2q}) }[/math]).

The results of this example can be seen in figure 3. In the figure, the top panel shows the exact solution of Burger's equation with the known data at [math]\displaystyle{ t=0.1 }[/math] and [math]\displaystyle{ t=0.9 }[/math]. In the middle panel, the exact solution and predicted solution are compared at the two time snapshots. In the bottom panel, the predicted parameter values are reported for noisy and noiseless data. Notice the accuracy with which the network can predict the parameter values.

Figure 3

Navier-Stokes with Pressure

Naturally, there are many extensions to the base problem that the PINN method tackles. One fascinating example of this is illustrated in the following example.

Consider the Navier-Stokes equations in two dimensions, given by:

\begin{align*} u_t + \lambda_1 ( uu_x + vu_y) = -p_x + \lambda_2 (u_xx + u_yy) \\ v_t + \lambda_1 (uv_x + vv_y) = -p_y + \lambda_2 (v_xx + v_yy) \end{align*}

where [math]\displaystyle{ u }[/math] and [math]\displaystyle{ v }[/math] are the [math]\displaystyle{ x }[/math] and [math]\displaystyle{ y }[/math] components of the fluid velocity. In these equations, not only are there two unknown parameters, [math]\displaystyle{ \lambda_1 }[/math] and [math]\displaystyle{ \lambda_2 }[/math], but there is also an entire unknown pressure field, [math]\displaystyle{ p(t,x,y) }[/math]. Based on the physics of the problem, we can assume that there is a scalar function [math]\displaystyle{ \psi }[/math] which satisfies [math]\displaystyle{ \psi_y = u }[/math] and [math]\displaystyle{ \psi_x = -v }[/math]. Assume that we have noisy measurements of the velocity field scattered across the spatio-temporal domain. We approximate [math]\displaystyle{ \psi }[/math] with a PINN, proceeding as we did in the continuous case above with the addition of also approximating the pressure field with a neural network. With each training batch, the weights of both networks are updated. We can compute the components of the velocity by differentiating the network for [math]\displaystyle{ \psi }[/math] and using these values as input to our loss function. Our full loss function is defined as in the continuous case, but note that the term quantifying the satisfaction of the PDEs will depend on the pressure network.

We allow ourselves 1% of the total data and optimize the network as we did before. The network has 9 layers with 20 neurons per hidden layer. The results of this optimization can be seen in figure 4. Notice again the remarkable accuracy that the PINN can achieve in the predictions of the full solution, parameter values, and pressure field. Interestingly, the predicted pressure field is off by a additive constant. This is not a surprise, as the pressure only appears in the PDEs in a gradient, meaning that it is only determinable up to an additive constant. Nonetheless, the PINN is able to predict its gradient with high accuracy.

Figure 4

Critiques

Although this paper has presented very interesting results and makes a bridge between machine learning and classical computational physics, some questions are still unanswered. For example, how deep should the neural network be? How much data is needed? Why the optimizer is not suffering from being trapped at local optima for the parameters of the differential operators ? Can weight initialization and data normalization be improved? Why these methods seem to be very robust to noise in data? How can uncertainty in predictions be interpreted which hints us to the concept of interpretable AI. The answers to these questions can be next steps for this research direction.

In this paper, a Quasi-Newton optimizer has been used to update parameters. Although they are more powerful that second order optimizers, however, due to their computational load, they are not the common choice in today's deep learning packages. Considering this, do the first order optimizers handle updating the weights in such a problem? Or they may get stuck in local minima? There is no such experiment in the paper.

Conclusion

This paper introduces physics-informed neural networks, a novel type of function-approximator neural network that utilizes existing information on physical systems in order to train using a small amount of data. It does this by incorporating information from a governing PDE model into the loss function. It allows for the prediction of the full solution, incorporation of noise into the measurements, estimation of model parameters appearing in the PDE, and approximation of auxiliary functions appearing in the PDE. This procedure can be carried out for different types of data - most notably for continuous-time and discrete-time data, both of which are common in real-world applications.

PINNs are a powerful technique with many possible extensions. This paper and related papers by this group have received many citations for their work with PINN. In fact, they have recently patented their method in the United States [3].

The code used to implement PINNs and generate the figures is all freely available on GitHub [4]. It is quite easy to go through and learn - although unfortunately, it is written in TensorFlow v1.

References

[1] Raissi, M., Perdikaris, P., & Karniadakis, G. E. (2019). Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational Physics, 378, 686–707.

[2] A. G. Baydin, B. A. Pearlmutter, A. A. Radul, J. M. Siskind, Automatic differentiation in machine learning: a survey, arXiv preprint arXiv:1502.05767 (2015).

[3] https://patents.google.com/patent/US20200293594A1/en

[4] https://github.com/maziarraissi/PINNs