Solving PDEs with ModelingToolkit and NeuralPDE

Solving PDEs with ModelingToolkit and NeuralPDE#

Solving Poisson PDE Systems

\[ \partial^{2}_{x}u(x,y) + \partial^{2}_{y}u(x,y) = -\sin (\pi x) \sin (\pi y) \]

with boundary conditions

\[\begin{split} \begin{align} u(0, y) &= 0 \\ u(1, y) &= 0 \\ u(x, 0) &= 0 \\ u(x, 1) &= 0 \\ \end{align} \end{split}\]

where

\(x ∈ [0, 1], y ∈ [0, 1]\)

using NeuralPDE
using Lux
using Plots
using Optimization
using OptimizationOptimJL
using ModelingToolkit
using ModelingToolkit: Interval

[ Info: Precompiling IJuliaExt [2f4121a4-3b3a-5ce6-9c5e-1f2673ce168a]

@variables x y u(..)
Dxx = Differential(x)^2
Dyy = Differential(y)^2

Differential(y) ∘ Differential(y)

2D PDE equations

eq  = Dxx(u(x, y)) + Dyy(u(x, y)) ~ -sinpi(x) * sinpi(y)
\[ \begin{equation} \frac{\mathrm{d}}{\mathrm{d}y} \frac{\mathrm{d}}{\mathrm{d}y} u\left( x, y \right) + \frac{\mathrm{d}}{\mathrm{d}x} \frac{\mathrm{d}}{\mathrm{d}x} u\left( x, y \right) = - \mathrm{sinpi}\left( x \right) \mathrm{sinpi}\left( y \right) \end{equation} \]

Boundary conditions

bcs = [
    u(0, y) ~ 0.0, u(1, y) ~ 0.0,
    u(x, 0) ~ 0.0, u(x, 1) ~ 0.0
]
\[\begin{split} \begin{align} u\left( 0, y \right) =& 0 \\ u\left( 1, y \right) =& 0 \\ u\left( x, 0 \right) =& 0 \\ u\left( x, 1 \right) =& 0 \end{align} \end{split}\]

Space domains

domains = [
    x  Interval(0.0, 1.0),
    y  Interval(0.0, 1.0)
]

2-element Vector{Symbolics.VarDomainPairing}:
 Symbolics.VarDomainPairing(x, 0.0 .. 1.0)
 Symbolics.VarDomainPairing(y, 0.0 .. 1.0)

Build a neural network for the PDE solver.

dim = 2
chain = Lux.Chain(Dense(dim, 16, Lux.σ), Dense(16, 16, Lux.σ), Dense(16, 1))

Chain(
    layer_1 = Dense(2 => 16, sigmoid_fast),  # 48 parameters
    layer_2 = Dense(16 => 16, sigmoid_fast),  # 272 parameters
    layer_3 = Dense(16 => 1),           # 17 parameters
)         # Total: 337 parameters,
          #        plus 0 states.

Discretization method uses PhysicsInformedNN() (PINN).

dx = 0.05
discretization = PhysicsInformedNN(chain, GridTraining(dx))

PhysicsInformedNN{GridTraining{Float64}, Nothing, NeuralPDE.Phi{Chain{@NamedTuple{layer_1::Dense{true, typeof(sigmoid_fast), typeof(glorot_uniform), typeof(zeros32)}, layer_2::Dense{true, typeof(sigmoid_fast), typeof(glorot_uniform), typeof(zeros32)}, layer_3::Dense{true, typeof(identity), typeof(glorot_uniform), typeof(zeros32)}}}, @NamedTuple{layer_1::@NamedTuple{}, layer_2::@NamedTuple{}, layer_3::@NamedTuple{}}}, typeof(NeuralPDE.numeric_derivative), Bool, Nothing, Nothing, Nothing, Base.Pairs{Symbol, Union{}, Tuple{}, @NamedTuple{}}}(Chain(), GridTraining{Float64}(0.05), nothing, NeuralPDE.Phi{Chain{@NamedTuple{layer_1::Dense{true, typeof(sigmoid_fast), typeof(glorot_uniform), typeof(zeros32)}, layer_2::Dense{true, typeof(sigmoid_fast), typeof(glorot_uniform), typeof(zeros32)}, layer_3::Dense{true, typeof(identity), typeof(glorot_uniform), typeof(zeros32)}}}, @NamedTuple{layer_1::@NamedTuple{}, layer_2::@NamedTuple{}, layer_3::@NamedTuple{}}}(Chain(), (layer_1 = NamedTuple(), layer_2 = NamedTuple(), layer_3 = NamedTuple())), NeuralPDE.numeric_derivative, false, nothing, nothing, nothing, LogOptions(50), [1], true, false, Base.Pairs{Symbol, Union{}, Tuple{}, @NamedTuple{}}())

Next we build our PDE system and discretize it. Because this system is time-invariant, the result is an OptimizationProblem.

@named pde_system = PDESystem(eq, bcs, domains, [x, y], [u(x, y)])
prob = discretize(pde_system, discretization)

OptimizationProblem. In-place: true
u0: ComponentVector{Float64}(layer_1 = (weight = [0.35971200466156006 -0.2037937194108963; 0.1393420696258545 0.5225875377655029; … ; -0.13923890888690948 0.18260620534420013; 0.4451419413089752 0.1468936800956726], bias = [0.0; 0.0; … ; 0.0; 0.0;;]), layer_2 = (weight = [-0.4216949939727783 -0.06320850551128387 … 0.16946706175804138 -0.22122304141521454; -0.11275719851255417 -0.2728542983531952 … -0.1621120572090149 0.2045103758573532; … ; 0.15988630056381226 0.09907838702201843 … -0.2601696848869324 -0.2974882423877716; -0.15108203887939453 -0.2304273545742035 … -0.0949699729681015 0.025790985673666], bias = [0.0; 0.0; … ; 0.0; 0.0;;]), layer_3 = (weight = [0.17299450933933258 0.5610336065292358 … -0.5511547923088074 -0.5100366473197937], bias = [0.0;;]))

alg = OptimizationOptimJL.BFGS()

BFGS{LineSearches.InitialStatic{Float64}, LineSearches.HagerZhang{Float64, Base.RefValue{Bool}}, Nothing, Nothing, Flat}(LineSearches.InitialStatic{Float64}
  alpha: Float64 1.0
  scaled: Bool false
, LineSearches.HagerZhang{Float64, Base.RefValue{Bool}}
  delta: Float64 0.1
  sigma: Float64 0.9
  alphamax: Float64 Inf
  rho: Float64 5.0
  epsilon: Float64 1.0e-6
  gamma: Float64 0.66
  linesearchmax: Int64 50
  psi3: Float64 0.1
  display: Int64 0
  mayterminate: Base.RefValue{Bool}
, nothing, nothing, Flat())

Callback function

larr = Float64[]
callback = function (p, l)
    push!(larr, l)
    return false
end

#1 (generic function with 1 method)

Solve the problem.

res = Optimization.solve(prob, alg, callback = callback, maxiters=1500)
plot(larr, xlabel="Iters", title="Loss", yscale=:log10, lab="Loss")

Plot the predicted solution of the PDE and compare it with the analytical solution to see the relative error.

xs, ys = [infimum(d.domain):dx/10:supremum(d.domain) for d in domains]
analytic_sol_func(x,y) = (sinpi(x)*sinpi(y))/(2pi^2)

phi = discretization.phi
u_predict = reshape([first(phi([x, y], res.u)) for x in xs for y in ys], (length(xs), length(ys)))
u_real = reshape([analytic_sol_func(x, y) for x in xs for y in ys], (length(xs), length(ys)))
diff_u = abs.(u_predict .- u_real)

201×201 Matrix{Float64}:
 3.70554e-5  3.29239e-5  2.89012e-5  2.49825e-5  …  5.02658e-5   5.7982e-5
 3.68977e-5  3.29307e-5  2.90651e-5  2.52963e-5     5.47063e-5   6.23888e-5
 3.67626e-5  3.29521e-5  2.92359e-5  2.56095e-5     5.89002e-5   6.65435e-5
 3.66458e-5  3.29841e-5  2.94099e-5  2.59189e-5     6.28553e-5   7.0454e-5
 3.65432e-5  3.30229e-5  2.95836e-5  2.62213e-5     6.65789e-5   7.41281e-5
 3.64508e-5  3.30649e-5  2.97537e-5  2.65136e-5  …  7.00784e-5   7.75733e-5
 3.63649e-5  3.31067e-5  2.99172e-5  2.67932e-5     7.33607e-5   8.07968e-5
 3.62821e-5  3.31451e-5  3.00713e-5  2.70574e-5     7.64326e-5   8.38056e-5
 3.61992e-5  3.31773e-5  3.02132e-5  2.7304e-5      7.93006e-5   8.66066e-5
 3.61131e-5  3.32005e-5  3.03406e-5  2.75307e-5     8.19712e-5   8.92063e-5
 3.60211e-5  3.32122e-5  3.04513e-5  2.77356e-5  …  8.44503e-5   9.16111e-5
 3.59204e-5  3.32101e-5  3.05431e-5  2.7917e-5      8.6744e-5    9.38271e-5
 3.58089e-5  3.3192e-5   3.06142e-5  2.80732e-5     8.8858e-5    9.58602e-5
 ⋮                                               ⋱               ⋮
 9.91457e-7  2.3647e-6   3.698e-6    4.99244e-6     7.68185e-5   7.89867e-5
 1.59197e-6  3.00006e-6  4.36572e-6  5.69016e-6  …  8.29704e-5   8.53556e-5
 2.23181e-6  3.67617e-6  5.07547e-6  6.43107e-6     8.91654e-5   9.17697e-5
 2.91032e-6  4.39252e-6  5.82691e-6  7.21497e-6     9.53975e-5   9.82228e-5
 3.62675e-6  5.14851e-6  6.61956e-6  8.04152e-6     0.00010166   0.000104709
 4.38017e-6  5.94338e-6  7.45283e-6  8.91028e-6     0.000107948  0.00011122
 5.16954e-6  6.77625e-6  8.326e-6    9.8207e-6   …  0.000114253  0.000117751
 5.99364e-6  7.64609e-6  9.23821e-6  1.07721e-5     0.000120569  0.000124293
 6.85111e-6  8.55172e-6  1.01885e-5  1.17636e-5     0.000126889  0.00013084
 7.74044e-6  9.49181e-6  1.11756e-5  1.27942e-5     0.000133205  0.000137383
 8.65993e-6  1.04649e-5  1.21984e-5  1.3863e-5      0.000139509  0.000143914
 9.60772e-6  1.14692e-5  1.32552e-5  1.49685e-5  …  0.000145794  0.000150426

p1 = plot(xs, ys, u_real, linetype=:contourf, title = "analytic");
p2 = plot(xs, ys, u_predict, linetype=:contourf, title = "predict");
p3 = plot(xs, ys, diff_u, linetype=:contourf, title = "error");
plot(p1, p2, p3)