Note

Go to the end to download the full example code.

2.4.9 Solver comparison

This example shows how to set up solvers explicitly and how to extract diagnostic information.

Deviation: 8.2e-05, 0.00018, 8.7e-05, 8.7e-05, 8.9e-05, explicit Euler solver, explicit, adaptive Runge-Kutta solver, implicit solver, Crank-Nicolson solver, Adam-Bashforth solver, scipy solver
Diagnostic information for explicit Euler solver:
{'controller': {'mpi_run': False, 't_start': 0, 't_end': 1.0, 'profiler': {'solver': 0.0017511810000030437, 'tracker': 4.437899998777084e-05, 'compilation': 6.069168525000009}, 'solver_start': '2026-05-05 18:55:04.720111+00:00', 'successful': True, 'stop_reason': 'Reached final time', 'solver_duration': '0:00:00.001789', 't_final': 1.0}, 'package_version': 'unknown', 'solver': {'class': 'EulerSolver', 'pde_class': 'DiffusionPDE', 'dt': 0.001, 'steps': 1000, 'dt_adaptive': False, 'stochastic': False, 'backend': {'name': 'numba', 'implementation': 'numba'}, 'post_step_data': None}}

Diagnostic information for explicit, adaptive Runge-Kutta solver:
{'controller': {'mpi_run': False, 't_start': 0, 't_end': 1.0, 'profiler': {'solver': 0.0005241710000092326, 'tracker': 5.754000000024462e-05, 'compilation': 7.335004675999997}, 'solver_start': '2026-05-05 18:55:12.062881+00:00', 'successful': True, 'stop_reason': 'Reached final time', 'solver_duration': '0:00:00.000573', 't_final': 1.0}, 'package_version': 'unknown', 'solver': {'class': 'RungeKuttaSolver', 'pde_class': 'DiffusionPDE', 'dt': 0.19412002092845687, 'steps': 12, 'dt_adaptive': True, 'stochastic': False, 'backend': {'name': 'numba', 'implementation': 'numba'}, 'dt_statistics': {'min': 0.001, 'max': 0.16349004074869758, 'mean': 0.08333333333333331, 'std': 0.05139510352101069, 'count': 12.0}, 'post_step_data': None}}

Diagnostic information for implicit solver:
{'controller': {'mpi_run': False, 't_start': 0, 't_end': 1.0, 'profiler': {'solver': 0.008239202999988038, 'tracker': 4.53300000060608e-05, 'compilation': 4.183707419000001}, 'solver_start': '2026-05-05 18:55:16.256981+00:00', 'successful': True, 'stop_reason': 'Reached final time', 'solver_duration': '0:00:00.008278', 't_final': 1.0}, 'package_version': 'unknown', 'solver': {'class': 'ImplicitSolver', 'pde_class': 'DiffusionPDE', 'dt': 0.001, 'steps': 1000, 'dt_adaptive': False, 'stochastic': False, 'backend': {'name': 'numba', 'implementation': 'numba'}, 'function_evaluations': 0, 'post_step_data': None}}

Diagnostic information for Crank-Nicolson solver:
{'controller': {'mpi_run': False, 't_start': 0, 't_end': 1.0, 'profiler': {'solver': 0.012532235000008995, 'tracker': 4.89189999939299e-05, 'compilation': 6.193302885999998}, 'solver_start': '2026-05-05 18:55:22.465004+00:00', 'successful': True, 'stop_reason': 'Reached final time', 'solver_duration': '0:00:00.012575', 't_final': 1.0}, 'package_version': 'unknown', 'solver': {'class': 'CrankNicolsonSolver', 'pde_class': 'DiffusionPDE', 'dt': 0.001, 'steps': 1000, 'dt_adaptive': False, 'stochastic': False, 'backend': {'name': 'numba', 'implementation': 'numba'}, 'function_evaluations': 0, 'post_step_data': None}}

Diagnostic information for Adam-Bashforth solver:
{'controller': {'mpi_run': False, 't_start': 0, 't_end': 1.0, 'profiler': {'solver': 3.8223737510000007, 'tracker': 5.521900000360347e-05, 'compilation': 1.8731575179999993}, 'solver_start': '2026-05-05 18:55:24.359720+00:00', 'successful': True, 'stop_reason': 'Reached final time', 'solver_duration': '0:00:03.823144', 't_final': 1.0}, 'package_version': 'unknown', 'solver': {'class': 'AdamsBashforthSolver', 'pde_class': 'DiffusionPDE', 'dt': 0.001, 'steps': 1000, 'dt_adaptive': False, 'stochastic': False, 'backend': {'name': 'numba', 'implementation': 'numba'}, 'post_step_data': None}}

Diagnostic information for scipy solver:
{'controller': {'mpi_run': False, 't_start': 0, 't_end': 1.0, 'profiler': {'solver': 0.6572316179999973, 'tracker': 4.3169999997871855e-05, 'compilation': 0.0013824410000040643}, 'solver_start': '2026-05-05 18:55:28.186833+00:00', 'successful': True, 'stop_reason': 'Reached final time', 'solver_duration': '0:00:00.657357', 't_final': np.float64(1.0)}, 'package_version': 'unknown', 'solver': {'class': 'ScipySolver', 'pde_class': 'DiffusionPDE', 'dt': 0.001, 'steps': 61, 'stochastic': False, 'backend': {'name': 'numba', 'implementation': 'numba'}}}


import pde

# initialize the grid, an initial condition, and the PDE
grid = pde.UnitGrid([32, 32])
field = pde.ScalarField.random_uniform(grid, -1, 1)
eq = pde.DiffusionPDE()


def run_solver(solver, label):
    """Helper function testing the solver."""
    controller = pde.Controller(solver, t_range=1, tracker=None)
    sol = controller.run(field, dt=1e-3)
    sol.label = label + " solver"
    print(f"Diagnostic information for {sol.label}:")
    print(controller.diagnostics)
    print()
    return sol


# try different solvers
solutions = [
    run_solver(pde.EulerSolver(eq), "explicit Euler"),
    run_solver(
        pde.RungeKuttaSolver(eq, adaptive=True), "explicit, adaptive Runge-Kutta"
    ),
    run_solver(pde.ImplicitSolver(eq), "implicit"),
    run_solver(pde.CrankNicolsonSolver(eq), "Crank-Nicolson"),
    run_solver(pde.AdamsBashforthSolver(eq), "Adam-Bashforth"),
    run_solver(pde.ScipySolver(eq), "scipy"),
]

# plot both fields and give the deviation as the title
deviations = [(solutions[0] - sol).fluctuations for sol in solutions]
title = "Deviation: " + ", ".join(f"{deviation:.2g}" for deviation in deviations[1:])
pde.FieldCollection(solutions).plot(title=title, arrangement=(2, 3))

Total running time of the script: (0 minutes 30.862 seconds)