Exemple #1
0
    read_data = precice.read_data()

    # Update the coupling expression with the new read data
    precice.update_coupling_expression(coupling_expression, read_data)

    dt.assign(np.min([fenics_dt, precice_dt]))

    # Compute solution u^n+1, use bcs u_D^n+1, u^n and coupling bcs
    solve(a == L, u_np1, bcs)

    # Write data to preCICE according to which problem is being solved
    if problem is ProblemType.DIRICHLET:
        # Dirichlet problem reads temperature and writes flux on boundary to Neumann problem
        determine_gradient(V_g, u_np1, flux)
        precice.write_data(flux)
    elif problem is ProblemType.NEUMANN:
        # Neumann problem reads flux and writes temperature on boundary to Dirichlet problem
        precice.write_data(u_np1)

    precice_dt = precice.advance(dt(0))

    if precice.is_action_required(precice.action_read_iteration_checkpoint()
                                  ):  # roll back to checkpoint
        u_cp, t_cp, n_cp = precice.retrieve_checkpoint()
        u_n.assign(u_cp)
        t = t_cp
        n = n_cp
    else:  # update solution
        u_n.assign(u_np1)
        t += dt
Exemple #2
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    if precice.is_action_required(precice.action_write_iteration_checkpoint()):  # write checkpoint
        precice.store_checkpoint(u_n, t, n)

    read_data = precice.read_data()

    # Update the coupling expression with the new read data
    precice.update_coupling_expression(coupling_expression, read_data)

    dt.assign(np.min([fenics_dt, precice_dt]))

    # Compute solution
    solve(a == L, u_np1, bcs)

    # Dirichlet problem obtains flux from solution and sends flux on boundary to Neumann problem
    fluxes = fluxes_from_temperature_full_domain(F_known_u, V, k)
    precice.write_data(fluxes)

    precice_dt = precice.advance(dt(0))

    if precice.is_action_required(precice.action_read_iteration_checkpoint()):  # roll back to checkpoint
        u_cp, t_cp, n_cp = precice.retrieve_checkpoint()
        u_n.assign(u_cp)
        t = t_cp
        n = n_cp
    else:  # update solution
        u_n.assign(u_np1)
        t += dt
        n += 1

    if precice.is_time_window_complete():
        # if abs(t % dt_out) < 10e-5:  # output if t is a multiple of dt_out
Exemple #3
0
    b_forces = b.copy(
    )  # b is the same for every iteration, only forces change

    for ps in Forces_x:
        ps.apply(b_forces)
    for ps in Forces_y:
        ps.apply(b_forces)

    assert (b is not b_forces)
    solve(A, u_np1.vector(), b_forces)

    dt = Constant(np.min([precice_dt, fenics_dt]))

    # Write new displacements to preCICE
    u_delta = project(u_np1 - u_ref, V)
    precice.write_data(u_delta)

    # Call to advance coupling, also returns the optimum time step value
    precice_dt = precice.advance(dt(0))

    # Either revert to old step if timestep has not converged or move to next timestep
    if precice.is_action_required(precice.action_read_iteration_checkpoint()
                                  ):  # roll back to checkpoint
        u_cp, t_cp, n_cp = precice.retrieve_checkpoint()
        u_n.assign(u_cp)
        t = t_cp
        n = n_cp
    else:
        u_n.assign(u_np1)
        t += float(dt)
        n += 1