In many cases one may accidentally write down a DAE that is not easily solvable
by numerical methods. In this tutorial, we will walk through an example of a
pendulum which accidentally generates an index-3 DAE, and show how to use the
modelingtoolkitize to correct the model definition before solving.
using ModelingToolkit
using LinearAlgebra
using OrdinaryDiffEq
using Plots
function pendulum!(du, u, p, t)
x, dx, y, dy, T = u
g, L = p
du[1] = dx
du[2] = T * x
du[3] = dy
du[4] = T * y - g
du[5] = x^2 + y^2 - L^2
return nothing
end
pendulum_fun! = ODEFunction(pendulum!, mass_matrix = Diagonal([1, 1, 1, 1, 0]))
u0 = [1.0, 0, 0, 0, 0]
p = [9.8, 1]
tspan = (0, 10.0)
pendulum_prob = ODEProblem(pendulum_fun!, u0, tspan, p)
traced_sys = modelingtoolkitize(pendulum_prob)
pendulum_sys = structural_simplify(dae_index_lowering(traced_sys))
prob = ODAEProblem(pendulum_sys, [], tspan)
sol = solve(prob, Tsit5(), abstol = 1e-8, reltol = 1e-8)
plot(sol, idxs = states(traced_sys))
In this tutorial, we will look at the pendulum system:
As a good DifferentialEquations.jl user, one would follow the mass matrix DAE tutorial to arrive at code for simulating the model:
using OrdinaryDiffEq, LinearAlgebra
function pendulum!(du, u, p, t)
x, dx, y, dy, T = u
g, L = p
du[1] = dx
du[2] = T * x
du[3] = dy
du[4] = T * y - g
du[5] = x^2 + y^2 - L^2
end
pendulum_fun! = ODEFunction(pendulum!, mass_matrix = Diagonal([1, 1, 1, 1, 0]))
u0 = [1.0, 0, 0, 0, 0];
p = [9.8, 1];
tspan = (0, 10.0);
pendulum_prob = ODEProblem(pendulum_fun!, u0, tspan, p)
solve(pendulum_prob, Rodas4())
However, one will quickly be greeted with the unfortunate message:
┌ Warning: First function call produced NaNs. Exiting.
└ @ OrdinaryDiffEq C:\Users\accou\.julia\packages\OrdinaryDiffEq\yCczp\src\initdt.jl:76
┌ Warning: Automatic dt set the starting dt as NaN, causing instability.
└ @ OrdinaryDiffEq C:\Users\accou\.julia\packages\OrdinaryDiffEq\yCczp\src\solve.jl:485
┌ Warning: NaN dt detected. Likely a NaN value in the state, parameters, or derivative value caused this outcome.
└ @ SciMLBase C:\Users\accou\.julia\packages\SciMLBase\DrPil\src\integrator_interface.jl:325
Did you implement the DAE incorrectly? No. Is the solver broken? No.
It turns out that this is a property of the DAE that we are attempting to solve.
This kind of DAE is known as an index-3 DAE. For a complete discussion of DAE
index, see this article.
Essentially, the issue here is that we have 4 differential variables (x, v_x, y, v_y)
and one algebraic variable T (which we can know because there is no D(T)
term in the equations). An index-1 DAE always satisfies that the Jacobian of
the algebraic equations is non-singular. Here, the first 4 equations are
differential equations, with the last term the algebraic relationship. However,
the partial derivative of x^2 + y^2 - L^2 w.r.t. T is zero, and thus the
Jacobian of the algebraic equations is the zero matrix, and thus it's singular.
This is a rapid way to see whether the DAE is index 1!
The problem with higher order DAEs is that the matrices used in Newton solves are singular or close to singular when applied to such problems. Because of this fact, the nonlinear solvers (or Rosenbrock methods) break down, making them difficult to solve. The classic paper DAEs are not ODEs goes into detail on this and shows that many methods are no longer convergent when index is higher than one. So, it's not necessarily the fault of the solver or the implementation: this is known.
But that's not a satisfying answer, so what do you do about it?
It turns out that higher order DAEs can be transformed into lower order DAEs. If you differentiate the last equation two times and perform a substitution, you can arrive at the following set of equations:
Note that this is mathematically-equivalent to the equation that we had before,
but the Jacobian w.r.t. T of the algebraic equation is no longer zero because
of the substitution. This means that if you wrote down this version of the model,
it will be index-1 and solve correctly! In fact, this is how DAE index is
commonly defined: the number of differentiations it takes to transform the DAE
into an ODE, where an ODE is an index-0 DAE by substituting out all of the
algebraic relationships.
However, requiring the user to sit there and work through this process on
potentially millions of equations is an unfathomable mental overhead. But,
we can avoid this by using methods like
the Pantelides algorithm
for automatically performing this reduction to index 1. While this requires the
ModelingToolkit symbolic form, we use modelingtoolkitize to transform
the numerical code into symbolic code, run dae_index_lowering lowering,
then transform back to numerical code with ODEProblem, and solve with a
numerical solver. Let's try that out:
traced_sys = modelingtoolkitize(pendulum_prob)
pendulum_sys = structural_simplify(dae_index_lowering(traced_sys))
prob = ODEProblem(pendulum_sys, Pair[], tspan)
sol = solve(prob, Rodas4())
using Plots
plot(sol, idxs = states(traced_sys))
Note that plotting using states(traced_sys) is done so that any
variables which are symbolically eliminated, or any variable reordering
done for enhanced parallelism/performance, still show up in the resulting
plot and the plot is shown in the same order as the original numerical
code.
Note that we can even go a bit further. If we use the ODAEProblem
constructor, we can remove the algebraic equations from the states of the
system and fully transform the index-3 DAE into an index-0 ODE which can
be solved via an explicit Runge-Kutta method:
traced_sys = modelingtoolkitize(pendulum_prob)
pendulum_sys = structural_simplify(dae_index_lowering(traced_sys))
prob = ODAEProblem(pendulum_sys, Pair[], tspan)
sol = solve(prob, Tsit5(), abstol = 1e-8, reltol = 1e-8)
plot(sol, idxs = states(traced_sys))
And there you go: this has transformed the model from being too hard to solve with implicit DAE solvers, to something that is easily solved with explicit Runge-Kutta methods for non-stiff equations.