def run(kn=1.0, dt=0.01, nt=1000, coll="linear", scheme="Euler"): config = collision.utils.CollisionConfig.from_json( "./examples/linear_transport/configs/" + "linear" + ".json" ) vmesh = collision.CartesianMesh(config) if coll == "linear": coll_op = collision.LinearCollision(config, vmesh) elif coll == "rbm": coll_op = collision.RandomBatchLinearCollision(config, vmesh) else: raise NotImplementedError( "Collision method {} is not implemented.".format(coll) ) solver = pykinetic.BoltzmannSolver0D(collision_operator=coll_op, kn=kn) if "RK" in scheme: solver.time_integrator = "RK" solver.a = rkcoeff[scheme]["a"] solver.b = rkcoeff[scheme]["b"] solver.c = rkcoeff[scheme]["c"] else: solver.time_integrator = scheme solver.dt = dt domain = pykinetic.Domain([]) state = pykinetic.State(domain, vmesh, 1) qinit(state, vmesh) sol = pykinetic.Solution(state, domain) output_dict = {} sol_frames, macro_frames, ts, l2_errs = ( [copy.deepcopy(sol)], [compute_rho(sol.state, vmesh)], [0.0], l2_err(sol, vmesh), ) pbar = Progbar(nt) for t in range(nt): solver.evolve_to_time(sol) l2_errs.append(l2_err(sol, vmesh)) sol_frames.append([copy.deepcopy(sol), l2_err]) macro_frames.append(compute_rho(sol.state, vmesh)) ts.append(0.0 + (t + 1) * dt) pbar.update(t + 1, finalize=False) pbar.update(nt, finalize=True) output_dict["macro_frames"] = macro_frames output_dict["t"] = ts return output_dict
def run(kn=1.0, tau=0.1, p=1.0, dt=0.01, nt=1000, scheme="Euler"): config = collision.utils.CollisionConfig.from_json( "./configs/penalty.json") vmesh = collision.SpectralMesh(config) coll_op = collision.FSInelasticVHSCollision(config, vmesh) tau = tau * kn print("tau is {}.".format(tau)) if scheme == "BEuler": solver = PenalizationSolver0D(collision_operator=coll_op, penalty=p, kn=kn, heat_bath=tau) solver.time_integrator = "BEuler" else: solver = pykinetic.BoltzmannSolver0D(collision_operator=coll_op, kn=kn, heat_bath=tau) if "RK" in scheme: print("OK") solver.time_integrator = "RK" solver.a = rkcoeff[scheme]["a"] solver.b = rkcoeff[scheme]["b"] solver.c = rkcoeff[scheme]["c"] else: solver.time_integrator = scheme solver.dt = dt domain = pykinetic.Domain([]) state = pykinetic.State(domain, vdof=vmesh.nvs) qinit(state, vmesh) sol = pykinetic.Solution(state, domain) sol_frames = [] T_frames = [] pbar = Progbar(nt) for t in range(nt): solver.evolve_to_time(sol) T_frames.append(vmesh.get_p(sol.q)[-1]) sol_frames.append(copy.deepcopy(sol)) pbar.update(t + 1, finalize=False) pbar.update(nt, finalize=True) return T_frames, sol_frames, vmesh, coll_op, solver
def run(kn=1.0, dt=0.01, nt=1000, eps=(1.0, 1.0), coll="fsm", scheme="Euler"): config = collision.utils.CollisionConfig.from_json("./configs/" + coll + ".json") vmesh = collision.SpectralMesh(config) if coll == "fsm": coll_op = collision.FSInelasticVHSCollision(config, vmesh) elif coll == "rbm": coll_op = collision.RandomBatchCollisionV2(config, vmesh) a, b = eps coll_op.eps = a * vmesh.delta**b else: raise NotImplementedError( "Collision method {} is not implemented.".format(coll)) solver = pykinetic.BoltzmannSolver0D(collision_operator=coll_op, kn=kn) if "RK" in scheme: solver.time_integrator = "RK" solver.a = rkcoeff[scheme]["a"] solver.b = rkcoeff[scheme]["b"] solver.c = rkcoeff[scheme]["c"] else: solver.time_integrator = scheme solver.dt = dt domain = pykinetic.Domain([]) state = pykinetic.State(domain, vdof=vmesh.nvs) qinit(state, vmesh) sol = pykinetic.Solution(state, domain) sol_frames = [] macro_frames = [] pbar = Progbar(nt) for t in range(nt): solver.evolve_to_time(sol) l2_err = (np.sqrt(np.sum( (sol.q - bkw_fn(vmesh, sol.t))**2)) * vmesh.delta) sol_frames.append([copy.deepcopy(sol), l2_err]) macro_frames.append(vmesh.get_p(sol.q)) # sol_frames.append(copy.deepcopy(sol)) pbar.update(t + 1, finalize=False) pbar.update(nt, finalize=True) return macro_frames, sol_frames, vmesh.delta
def run( kn=lambda x, y: 1.0, sigma_s=lambda x, y: 1.0, sigma_a=lambda x, y: 0.0, Q=lambda x, y: 0.0, xmin=[0.0, 0.0], xmax=[1.0, 1.0], nx=40, dt=0.01, nt=1000, coll="linear", scheme="Euler", BC="periodic", f_l=lambda vx, vy: 0.0, f_b=lambda vx, vy: 0.0, f_r=lambda vx, vy: 0.0, f_t=lambda vx, vy: 0.0, init_func=lambda vmesh, u, T, rho: 0.0, ): # Load config config = collision.utils.CollisionConfig.from_json( "./examples/linear_transport/configs/" + "parity_2d" + ".json") # Collision vmesh = collision.PolarMesh(config) # print(vmesh.centers[0], vmesh.weights) if coll == "linear": coll_op = collision.LinearCollision(config, vmesh) elif coll == "rbm": coll_op = collision.RandomBatchLinearCollision(config, vmesh) elif coll == "rbm_symm": coll_op = collision.SymmetricRBMLinearCollision(config, vmesh) else: raise NotImplementedError( "Collision method {} is not implemented.".format(coll)) # x domian x = pykinetic.Dimension(xmin[0], xmax[0], nx, name="x") y = pykinetic.Dimension(xmin[1], xmax[1], nx, name="y") # print(x.centers_with_ghost(2)) domain = pykinetic.Domain([x, y]) # Riemann solver rp = pykinetic.riemann.parity_2D solver = APNeutronTransportSolver2D( rp, [coll_op], kn=kn(x.centers, y.centers), sigma_s=sigma_s(x.centers, y.centers), sigma_a=sigma_a(x.centers, y.centers), Q=Q(x.centers, y.centers), ) # print(solver.kn) solver.order = 1 # solver.lim_type = -1 solver.time_integrator = scheme solver.dt = dt print("dt is {}".format(solver.dt)) # sigma = sigma_s(x.centers, y.centers) + kn( # x.centers, y.centers # ) ** 2 * sigma_a(x.centers, y.centers) # sigma_l, sigma_r = None, None # if isinstance(sigma, np.ndarray): # sigma_l, sigma_r = sigma[0], sigma[-1] # else: # sigma_l = sigma_r = sigma # kn_l, kn_r = None, None # if isinstance(solver.kn, np.ndarray): # kn_l, kn_r = solver.kn[0], solver.kn[-1] # else: # kn_l = kn_r = solver.kn # Boundary conditions def dirichlet_lower_BC(state, dim, t, qbc, auxbc, num_ghost): vx, vy = state.problem_data["v"] if dim.name == "x": for i in range(num_ghost): qbc[::2, i] = -qbc[::2, num_ghost + i] qbc[1::2, i] = ( 2 * (-vx * 2 * qbc[::2, num_ghost] / state.grid.delta[0]) - qbc[1::2, num_ghost + i]) elif dim.name == "y": for i in range(num_ghost): qbc[::2, :, i] = -qbc[::2, :, num_ghost + i] qbc[1::2, :, i] = ( 2 * (-vy * 2 * qbc[::2, :, num_ghost] / state.grid.delta[1]) - qbc[1::2, :, num_ghost + i]) qbc[1, :, i] = -qbc[1, :, i] else: raise ValueError("Dim could be only x or y.") def dirichlet_upper_BC(state, dim, t, qbc, auxbc, num_ghost): vx, vy = state.problem_data["v"] if dim.name == "x": for i in range(num_ghost): qbc[::2, -i - 1] = -qbc[::2, -2 * num_ghost + i] qbc[1::2, -i - 1] = ( 2 * (vx * 2 * qbc[::2, -num_ghost - 1] / state.grid.delta[0]) - qbc[1::2, -2 * num_ghost + i]) elif dim.name == "y": for i in range(num_ghost): qbc[::2, :, -i - 1] = -qbc[::2, :, -2 * num_ghost + i] qbc[1::2, :, -i - 1] = (2 * (vy * 2 * qbc[::2, :, -num_ghost - 1] / state.grid.delta[1]) - qbc[1::2, :, -2 * num_ghost + i]) qbc[1, :, -i - 1] = -qbc[1, :, -i - 1] else: raise ValueError("Dim could be only x or y.") if BC == "periodic": solver.all_bcs = pykinetic.BC.periodic elif BC == "dirichlet": solver.all_bcs = pykinetic.BC.custom solver.user_bc_lower = dirichlet_lower_BC solver.user_bc_upper = dirichlet_upper_BC else: raise ValueError("Given BC type is not avaliable!") state = pykinetic.State(domain, vmesh, 4) state.problem_data["v"] = vmesh.centers state.problem_data["phi"] = phi(solver.kn) state.problem_data["sqrt_phi"] = np.sqrt(phi(solver.kn)) qinit(state, vmesh, solver.kn, init_func) sol = pykinetic.Solution(state, domain) output_dict = {} sol_frames, macro_frames, ts = ( [copy.deepcopy(sol)], [compute_rho(sol.state, vmesh)], [0.0], ) pbar = Progbar(nt) for t in range(nt): solver.evolve_to_time(sol) sol_frames.append(copy.deepcopy(sol)) macro_frames.append(compute_rho(sol.state, vmesh)) ts.append(0.0 + (t + 1) * dt) pbar.update(t + 1, finalize=False) pbar.update(nt, finalize=True) output_dict["macro_frames"] = macro_frames output_dict["mesh"] = state.c_centers output_dict["t"] = ts return output_dict
def run( kn=1.0, sigma_s=lambda x: 1.0, sigma_a=lambda x: 0.0, Q=lambda x: 0.0, xmin=0.0, xmax=1.0, nx=40, dt=0.01, nt=1000, coll="linear", scheme="Euler", BC="periodic", f_l=lambda v: 1.0, f_r=lambda v: 0.0, init_func=lambda vmesh, u, T, rho: 0.0, ): # Load config config = collision.utils.CollisionConfig.from_json( "./linear_transport/configs/" + "linear" + ".json") # Collision vmesh = collision.CartesianMesh(config) if coll == "linear": coll_op = collision.LinearCollision(config, vmesh) elif coll == "rbm": coll_op = collision.RandomBatchLinearCollision(config, vmesh) elif coll == "rbm_symm": coll_op = collision.SymmetricRBMLinearCollision(config, vmesh) else: raise NotImplementedError( "Collision method {} is not implemented.".format(coll)) # x domian x = pykinetic.Dimension(xmin, xmax, nx, name="x") domain = pykinetic.Domain([x]) # Riemann solver rp = pykinetic.riemann.advection_1D solver = DiffusiveRegimeSolver1D( rp, [coll_op], kn=kn(x.centers), sigma_s=sigma_s(x.centers), sigma_a=sigma_a(x.centers), Q=Q(x.centers), ) solver.order = 1 # solver.lim_type = 2 # Time integrator if "RK" in scheme: solver.time_integrator = "RK" solver.a = rkcoeff[scheme]["a"] solver.b = rkcoeff[scheme]["b"] solver.c = rkcoeff[scheme]["c"] else: solver.time_integrator = scheme solver.dt = dt print("dt is {}".format(solver.dt)) # Boundary condition def dirichlet_lower_BC(state, dim, t, qbc, auxbc, num_ghost): v = state.problem_data["v"][0] for i in range(num_ghost): qbc[0, i, v > 0] = f_l(v[v > 0]) def dirichlet_upper_BC(state, dim, t, qbc, auxbc, num_ghost): v = state.problem_data["v"][0] for i in range(num_ghost): qbc[0, -i - 1, v < 0] = f_r(v[v < 0]) if BC == "periodic": solver.bc_lower[0] = pykinetic.BC.periodic solver.bc_upper[0] = pykinetic.BC.periodic elif BC == "dirichlet": solver.bc_lower[0] = pykinetic.BC.custom solver.bc_upper[0] = pykinetic.BC.custom solver.user_bc_lower = dirichlet_lower_BC solver.user_bc_upper = dirichlet_upper_BC else: raise ValueError("Given BC type is not avaliable!") state = pykinetic.State(domain, vmesh, 1) state.problem_data["v"] = vmesh.centers qinit(state, vmesh, init_func) sol = pykinetic.Solution(state, domain) output_dict = {} sol_frames, macro_frames, ts = ( [copy.deepcopy(sol.q)], [compute_rho(sol.state, vmesh)], [0.0], ) pbar = Progbar(nt) for t in range(nt): solver.evolve_to_time(sol) if (t + 1) % 1 == 0: sol_frames.append(copy.deepcopy(sol.q)) macro_frames.append(compute_rho(sol.state, vmesh)) ts.append(sol.t) pbar.update(t + 1, finalize=False) pbar.update(nt, finalize=True) output_dict["f_frames"] = np.asarray(sol_frames)[:, 0] output_dict["macro_frames"] = np.asarray(macro_frames) output_dict["x"] = np.asarray(x.centers) output_dict["t"] = np.asarray(ts) output_dict["v"] = np.asarray(vmesh.centers[0]) return output_dict
def run( kn=1e-4, tau=None, dt=0.001, nt=100, eps=(0.2, 2.0), coll="fsm", scheme="Euler", euler_solver=False, ): config = collision.utils.CollisionConfig.from_json("./configs/" + coll + ".json") vmesh = collision.SpectralMesh(config) if coll == "fsm": coll_op = collision.FSInelasticVHSCollision(config, vmesh) elif coll == "rbm": coll_op = collision.RandomBatchCollisionV2(config, vmesh) a, b = eps coll_op.eps = a * vmesh.delta**b else: raise NotImplementedError( "Collision method {} is not implemented.".format(coll)) rp = pykinetic.riemann.advection_1D solver = pykinetic.BoltzmannSolver1D(rp, coll_op, kn=kn, heat_bath=tau, device="gpu") if "RK" in scheme: solver.time_integrator = "RK" solver.a = rkcoeff[scheme]["a"] solver.b = rkcoeff[scheme]["b"] solver.c = rkcoeff[scheme]["c"] else: solver.time_integrator = scheme solver.dt = dt print("dt is {}".format(solver.dt)) solver.order = 2 solver.lim_type = -1 solver.bc_lower[0] = pykinetic.BC.periodic solver.bc_upper[0] = pykinetic.BC.periodic x = pykinetic.Dimension(0.0, 1.0, 100, name="x") domain = pykinetic.Domain([x]) state = pykinetic.State(domain, vdof=vmesh.nvs) state.problem_data["v"] = vmesh.centers qinit(state, vmesh) sol = pykinetic.Solution(state, domain) output_dict = {} if euler_solver: euler = Euler1D(tau) euler.set_initial(vmesh.get_p(sol.q)[0], 0, 1.0) euler.solve(dt * nt) output_dict["euler_macro"] = euler.macros(2) sol_frames = [] macro_frames = [] pbar = Progbar(nt) for t in range(nt): solver.evolve_to_time(sol) # l2_err = ( # np.sqrt(np.sum((sol.q - bkw_fn(vmesh, sol.t)) ** 2)) # * vmesh.delta # ) # sol_frames.append([copy.deepcopy(sol), l2_err]) macro_frames.append(vmesh.get_p(sol.q)) sol_frames.append(copy.deepcopy(sol)) pbar.update(t + 1, finalize=False) pbar.update(nt, finalize=True) output_dict["macro_frames"] = macro_frames return output_dict
def run( kn=lambda x: 1.0, sigma_s=lambda x: 1.0, sigma_a=lambda x: 0.0, Q=lambda x: 0.0, xmin=0.0, xmax=1.0, nx=40, dt=0.01, nt=1000, coll="linear", scheme="Euler", BC="periodic", f_l=lambda v: 1.0, f_r=lambda v: 0.0, init_func=lambda vmesh, u, T, rho: 0.0, ): # Load config config = collision.utils.CollisionConfig.from_json( "./linear_transport/configs/" + "parity" + ".json") # Collision vmesh = collision.CartesianMesh(config) # print(vmesh.centers[0], vmesh.weights) if coll == "linear": coll_op = collision.LinearCollision(config, vmesh) elif coll == "rbm": coll_op = collision.RandomBatchLinearCollision(config, vmesh) elif coll == "rbm_symm": coll_op = collision.SymmetricRBMLinearCollision(config, vmesh) else: raise NotImplementedError( "Collision method {} is not implemented.".format(coll)) # x domian x = pykinetic.Dimension(xmin, xmax, nx, name="x") # print(x.centers_with_ghost(2)) domain = pykinetic.Domain([x]) # Riemann solver rp = pykinetic.riemann.parity_1D solver = APNeutronTransportSolver1D( rp, [coll_op], kn=kn(x.centers), sigma_s=sigma_s(x.centers), sigma_a=sigma_a(x.centers), Q=Q(x.centers), ) # print(solver.kn) solver.order = 1 # solver.lim_type = -1 solver.time_integrator = scheme solver.dt = dt print("dt is {}".format(solver.dt)) sigma = sigma_s(x.centers) + kn(x.centers)**2 * sigma_a(x.centers) sigma_l, sigma_r = None, None if isinstance(sigma, np.ndarray): sigma_l, sigma_r = sigma[0], sigma[-1] else: sigma_l = sigma_r = sigma kn_l, kn_r = None, None if isinstance(solver.kn, np.ndarray): kn_l, kn_r = solver.kn[0], solver.kn[-1] else: kn_l = kn_r = solver.kn # Boundary conditions def dirichlet_lower_BC(state, dim, t, qbc, auxbc, num_ghost): v = state.problem_data["v"][0] / sigma_l kn_dx = kn_l / state.grid.delta[0] for i in range(num_ghost): qbc[0, i, :] = (f_l(v) - (0.5 - kn_dx * v) * qbc[0, num_ghost, :]) / ( 0.5 + kn_dx * v) for i in range(num_ghost): qbc[1, i, :] = (2 * f_l(v) - (qbc[0, num_ghost - 1, :] + qbc[0, num_ghost, :])) / kn_l - qbc[1, num_ghost, :] def dirichlet_upper_BC(state, dim, t, qbc, auxbc, num_ghost): v = state.problem_data["v"][0] / sigma_r kn_dx = kn_r / state.grid.delta[0] for i in range(num_ghost): qbc[0, -i - 1, :] = (f_r(v) - (0.5 - kn_dx * v) * qbc[0, -num_ghost - 1, :]) / ( 0.5 + kn_dx * v) for i in range(num_ghost): qbc[1, -i - 1, :] = ((qbc[0, -num_ghost, :] + qbc[0, -num_ghost - 1, :]) - 2 * f_r(v)) / kn_r - qbc[1, -num_ghost - 1, :] if BC == "periodic": solver.bc_lower[0] = pykinetic.BC.periodic solver.bc_upper[0] = pykinetic.BC.periodic elif BC == "dirichlet": solver.bc_lower[0] = pykinetic.BC.custom solver.bc_upper[0] = pykinetic.BC.custom solver.user_bc_lower = dirichlet_lower_BC solver.user_bc_upper = dirichlet_upper_BC else: raise ValueError("Given BC type is not avaliable!") state = pykinetic.State(domain, vmesh, 2) state.problem_data["v"] = vmesh.centers state.problem_data["phi"] = phi(solver.kn) state.problem_data["sqrt_phi"] = np.sqrt(phi(solver.kn)) qinit(state, vmesh, solver.kn, init_func) sol = pykinetic.Solution(state, domain) output_dict = {} sol_frames, macro_frames, ts = ( [copy.deepcopy(sol.q)], [compute_rho(sol.state, vmesh)], [0.0], ) pbar = Progbar(nt) for t in range(nt): solver.evolve_to_time(sol) sol_frames.append(copy.deepcopy(sol.q)) macro_frames.append(compute_rho(sol.state, vmesh)) # Test # qbc = solver.qbc # print( # np.max( # np.abs( # 5.0 * np.sin(vmesh.centers[0]) # - ( # 0.5 * (qbc[0, 1] + qbc[0, 2]) # + kn * 0.5 * (qbc[1, 1] + qbc[1, 2]) # ) # ) # ) # ) ts.append(0.0 + (t + 1) * dt) pbar.update(t + 1, finalize=False) pbar.update(nt, finalize=True) output_dict["f_frames"] = np.asarray(sol_frames) output_dict["macro_frames"] = macro_frames output_dict["x"] = x.centers output_dict["t"] = ts output_dict["v"] = np.asarray(vmesh.centers[0]) return output_dict
def run( kn=1.0, sigma_s=lambda x, y: 1.0, sigma_a=lambda x, y: 0.0, Q=lambda x, y: 0.0, xmin=[0.0, 0.0], xmax=[1.0, 1.0], nx=40, dt=0.01, nt=1000, coll="linear", scheme="Euler", BC="periodic", f_l=lambda vx, vy: 0.0, f_b=lambda vx, vy: 0.0, f_r=lambda vx, vy: 0.0, f_t=lambda vx, vy: 0.0, init_func=lambda vmesh, u, T, rho: 0.0, ): # Load config config = collision.utils.CollisionConfig.from_json( "./examples/linear_transport/configs/" + "linear_2d" + ".json" ) # Collision vmesh = collision.PolarMesh(config) if coll == "linear": coll_op = collision.LinearCollision(config, vmesh) elif coll == "rbm": coll_op = collision.RandomBatchLinearCollision(config, vmesh) elif coll == "rbm_symm": coll_op = collision.SymmetricRBMLinearCollision(config, vmesh) else: raise NotImplementedError( "Collision method {} is not implemented.".format(coll) ) # x domian x = pykinetic.Dimension(xmin[0], xmax[0], nx, name="x") y = pykinetic.Dimension(xmin[1], xmax[1], nx, name="y") domain = pykinetic.Domain([x, y]) # Riemann solver rp = pykinetic.riemann.advection_2D solver = DiffusiveRegimeSolver2D( rp, coll_op, kn=kn(x.centers, y.centers), sigma_s=sigma_s(x.centers, y.centers), sigma_a=sigma_a(x.centers, y.centers), Q=Q(x.centers, y.centers), ) solver.order = 1 # solver.lim_type = 2 # Time integrator solver.time_integrator = scheme solver.dt = dt print("dt is {}".format(solver.dt)) # Boundary condition def dirichlet_lower_BC(state, dim, t, qbc, auxbc, num_ghost): vx, vy = state.problem_data["v"] if dim.name == "x": for i in range(num_ghost): qbc[0, i, :, (vx > 0)[0], :] = f_l(vx[(vx > 0)[0]], vy) elif dim.name == "y": for i in range(num_ghost): qbc[0, :, i, :, (vy > 0)[:, 0]] = f_b(vx, vy[(vy > 0)[:, 0]]) else: raise ValueError("Dim could be only x or y.") def dirichlet_upper_BC(state, dim, t, qbc, auxbc, num_ghost): vx, vy = state.problem_data["v"] if dim.name == "x": for i in range(num_ghost): qbc[0, -i - 1, :, (vx < 0)[0], :] = f_r(vx[(vx < 0)[0]], vy) elif dim.name == "y": for i in range(num_ghost): qbc[0, :, -i - 1, :, (vy < 0)[:, 0]] = f_t(vx, vy[(vy < 0)[:, 0]]) else: raise ValueError("Dim could be only 'x' or 'y'.") if BC == "periodic": solver.all_bcs = pykinetic.BC.periodic elif BC == "dirichlet": solver.all_bcs = pykinetic.BC.custom solver.user_bc_lower = dirichlet_lower_BC solver.user_bc_upper = dirichlet_upper_BC else: raise ValueError("Given BC type is not avaliable!") state = pykinetic.State(domain, vmesh, 1) state.problem_data["v"] = vmesh.centers qinit(state, vmesh, init_func) sol = pykinetic.Solution(state, domain) output_dict = {} sol_frames, macro_frames, ts = ( [copy.deepcopy(sol)], [compute_rho(sol.state, vmesh)], [0.0], ) pbar = Progbar(nt) for t in range(nt): solver.evolve_to_time(sol) sol_frames.append(copy.deepcopy(sol)) macro_frames.append(compute_rho(sol.state, vmesh)) ts.append(0.0 + (t + 1) * dt) pbar.update(t + 1, finalize=False) pbar.update(nt, finalize=True) output_dict["macro_frames"] = macro_frames output_dict["mesh"] = state.c_centers output_dict["t"] = ts return output_dict
def run(kn=1e-4, tau=None, p=5.0, dt=0.001, nt=100, scheme="Euler"): config = collision.utils.CollisionConfig.from_json( "./examples/boltzmann/configs/penalty.json") vmesh = collision.SpectralMesh(config) rp = pykinetic.riemann.advection_1D coll_op = collision.FSInelasticVHSCollision(config, vmesh) if scheme == "BEuler": solver = PenalizationSolver1D(rp, coll_op, penalty=p, kn=kn, heat_bath=tau, device="gpu") solver.time_integrator = "BEuler" else: solver = pykinetic.BoltzmannSolver1D(rp, coll_op, kn=kn, heat_bath=tau, device="gpu") if "RK" in scheme: solver.time_integrator = "RK" solver.a = rkcoeff[scheme]["a"] solver.b = rkcoeff[scheme]["b"] solver.c = rkcoeff[scheme]["c"] else: solver.time_integrator = scheme solver.dt = dt print("dt is {}".format(solver.dt)) # solver.order = 2 solver.lim_type = 2 solver.bc_lower[0] = pykinetic.BC.periodic solver.bc_upper[0] = pykinetic.BC.periodic x = pykinetic.Dimension(0.0, 1.0, 100, name="x") domain = pykinetic.Domain([x]) state = pykinetic.State(domain, vdof=vmesh.nvs) state.problem_data["v"] = vmesh.centers qinit(state, vmesh) sol = pykinetic.Solution(state, domain) euler = Euler1D(tau) euler.set_initial(vmesh.get_p(sol.q)[0], 0, 1.0) sol_frames = [] macro_frames = [] pbar = Progbar(nt) for t in range(nt): solver.evolve_to_time(sol) # l2_err = ( # np.sqrt(np.sum((sol.q - bkw_fn(vmesh, sol.t)) ** 2)) # * vmesh.delta # ) # sol_frames.append([copy.deepcopy(sol), l2_err]) macro_frames.append(vmesh.get_p(sol.q)) sol_frames.append(copy.deepcopy(sol)) pbar.update(t + 1, finalize=False) pbar.update(nt, finalize=True) euler.solve(dt * nt) return macro_frames, euler.macros(2)