Exemplo n.º 1
0
import sources_1D as sources
import save_routines as save
import pdb
from simulation_parameters_1D import save_particles, save_fields, te0_equil

if __name__ == '__main__':
    start_time = timer()

    # Initialize simulation: Allocate memory and set time parameters
    print('Initializing arrays...')
    pos, vel, Ie, W_elec, Ib, W_mag, idx, Ep, Bp, temp_N = init.initialize_particles(
    )
    B, E_int, E_half, Ve, Te, Te0 = init.initialize_fields()
    q_dens, q_dens_adv, Ji, ni, nu = init.initialize_source_arrays()
    old_particles, old_fields, temp3De, temp3Db, temp1D,\
                                v_prime, S, T, mp_flux  = init.initialize_tertiary_arrays()

    print('Collecting initial moments...')
    # Collect initial moments and save initial state
    sources.collect_moments(vel, Ie, W_elec, idx, q_dens, Ji, ni, nu)

    if te0_equil == 1:
        init.set_equilibrium_te0(q_dens, Te0)

    DT, max_inc, part_save_iter, field_save_iter, B_damping_array, E_damping_array\
        = init.set_timestep(vel, Te0)

    fields.calculate_E(B, Ji, q_dens, E_int, Ve, Te, Te0, temp3De, temp3Db,
                       temp1D, E_damping_array, 0, DT, 0)

    print('Saving initial conditions...')
Exemplo n.º 2
0
import particles_1D as particles
import fields_1D as fields
import sources_1D as sources
import save_routines as save

import pdb
from simulation_parameters_1D import save_particles, save_fields

if __name__ == '__main__':
    start_time = timer()

    # Initialize simulation: Allocate memory and set time parameters
    pos, vel, Ie, W_elec, Ib, W_mag, idx = init.initialize_particles()
    B, E_int, E_half, Ve, Te, = init.initialize_fields()
    q_dens, q_dens_adv, Ji, ni, nu = init.initialize_source_arrays()
    old_particles, old_fields, temp3D, temp3D2, temp1D = init.initialize_tertiary_arrays(
    )

    DT, max_inc, part_save_iter, field_save_iter = init.set_timestep(vel)

    # Collect initial moments and save initial state
    sources.collect_moments(vel, Ie, W_elec, idx, q_dens, Ji, ni, nu, temp1D)
    fields.calculate_E(B, Ji, q_dens, E_int, Ve, Te, temp3D, temp3D2, temp1D)

    if save_particles == 1:
        save.save_particle_data(DT, part_save_iter, 0, pos, vel)

    if save_fields == 1:
        save.save_field_data(DT, field_save_iter, 0, Ji, E_int, B, Ve, Te,
                             q_dens)

    particles.assign_weighting_TSC(pos, Ib, W_mag, E_nodes=False)
Exemplo n.º 3
0
import fields_1D as fields
import sources_1D as sources
import save_routines as save

from simulation_parameters_1D import save_particles, save_fields, te0_equil

if __name__ == '__main__':
    start_time = timer()

    # Initialize simulation: Allocate memory and set time parameters
    pos, vel, Ie, W_elec, Ib, W_mag, idx, Ep, Bp, temp_N = init.initialize_particles(
    )
    B, E_int, E_half, Ve, Te, Te0 = init.initialize_fields()
    q_dens, q_dens_adv, Ji, ni, nu = init.initialize_source_arrays()
    old_particles, old_fields, temp3De, temp3Db, temp1D,\
                                          v_prime, S, T = init.initialize_tertiary_arrays()

    # Collect initial moments and save initial state
    sources.collect_moments(vel, Ie, W_elec, idx, q_dens, Ji, ni, nu)

    if te0_equil == 1:
        init.set_equilibrium_te0(q_dens, Te0)

    DT, max_inc, part_save_iter, field_save_iter, B_damping_array, E_damping_array\
        = init.set_timestep(vel, Te0)

    fields.calculate_E(B, Ji, q_dens, E_int, Ve, Te, Te0, temp3De, temp3Db,
                       temp1D, E_damping_array)

    if save_particles == 1:
        save.save_particle_data(0, DT, part_save_iter, 0, pos, vel, idx)
Exemplo n.º 4
0
# TODO:
# -- Check initial moments (i.e. verify uniform and expected charge density, zero transverse current density)
# -- Vectorise/Optimize particle loss/injection
# -- Test run :: Does it compile and execute?

if __name__ == '__main__':
    start_time = timer()

    # Initialize simulation: Allocate memory and set time parameters
    pos, vel, Ie, W_elec, Ib, W_mag, idx, Ep, Bp, temp_N = init.initialize_particles(
    )
    B, E_int, E_half, Ve, Te, Te0 = init.initialize_fields()
    q_dens, q_dens_adv, Ji, ni, nu = init.initialize_source_arrays()
    old_particles, old_fields, flux_rem, \
             temp3De, temp3Db, temp1D, v_prime, S, T    = init.initialize_tertiary_arrays()

    # Collect initial moments and save initial state
    sources.collect_velocity_moments(pos, vel, Ie, W_elec, idx, nu, Ji)
    sources.collect_position_moment(pos, Ie, W_elec, idx, q_dens, ni)

    DT, max_inc, part_save_iter, field_save_iter, B_damping_array, E_damping_array\
        = init.set_timestep(vel, Te0)

    fields.calculate_E(B, Ji, q_dens, E_int, Ve, Te, Te0, temp3De, temp3Db,
                       temp1D, E_damping_array)

    if save_particles == 1:
        save.save_particle_data(0, DT, part_save_iter, 0, pos, vel, idx)

    if save_fields == 1: