コード例 #1
0
    def add_es_solver(self, deposition_species = []):
        grid_ES = picmi.Cartesian3DGrid(number_of_cells=self.number_of_cells,
                                        lower_bound=self.lower_bound,
                                        upper_bound=self.upper_bound,
                                        lower_boundary_conditions=self.dir_bc,
                                        upper_boundary_conditions=self.dir_bc)

        self.ES_solver = picmi.ElectrostaticSolver(grid=grid_ES, 
                                                   warp_deposition_species=deposition_species,
                                                   warp_conductors = self.chamber.conductors,
                                                   warp_conductor_dfill = picmi.warp.largepos)

        self.ES_solver.initialize_solver_inputs()
        registersolver(self.ES_solver.solver)
コード例 #2
0
def measure_SEY(Ekin,
                Nmp,
                N_elec_p_mp,
                sey_params_dict,
                xgen=0,
                ygen=0,
                zgen=0,
                thetagen=0,
                phigen=0,
                tot_t=None,
                r_sphere=0.05,
                flag_video=False):

    import numpy as np
    import numpy.random as random
    #from pywarpx import picmi
    from warp import picmi
    from scipy.stats import gaussian_kde
    from warp.particles.Secondaries import Secondaries, warp, top, posC, time
    import matplotlib.pyplot as plt
    import parser
    import scipy.io as sio
    from scipy.constants import m_e
    from scipy.constants import c as c_light
    from io import BytesIO as StringIO
    from mpi4py import MPI

    # Construct PyECLOUD secondary emission object
    import PyECLOUD.sec_emission_model_ECLOUD as seec
    sey_mod = seec.SEY_model_ECLOUD(
        Emax=sey_params_dict['Emax'],
        del_max=sey_params_dict['del_max'],
        R0=sey_params_dict['R0'],
        E_th=sey_params_dict['E_th'],
        sigmafit=sey_params_dict['sigmafit'],
        mufit=sey_params_dict['mufit'],
        secondary_angle_distribution=sey_params_dict[
            'secondary_angle_distribution'])

    ##########################
    # physics parameters
    ##########################

    mysolver = 'ES'  # solver type ('ES'=electrostatic; 'EM'=electromagnetic)

    # --- Beam

    ##########################
    # numerics parameters
    ##########################
    # geometry

    # --- grid
    dh = r_sphere / 10.
    xmin = -r_sphere - 0.001
    xmax = -xmin
    ymin = -r_sphere - 0.001
    ymax = -ymin
    zmin = -r_sphere - 0.001
    zmax = -zmin

    nx = (xmax - xmin) / dh
    ny = (xmax - xmin) / dh
    nz = (xmax - xmin) / dh

    #######################################################
    # compute beam size from normalized emittance and beta
    # Uncomment if data available
    #######################################################

    sigmax = 2e-4
    sigmay = 2.1e-4
    E0 = 0.511 * 1e6
    E = E0 + Ekin
    beam_gamma = E / E0
    beam_beta = np.sqrt(1 - 1 / (beam_gamma * beam_gamma))
    v = beam_beta * c_light

    elec_beam = picmi.Species(particle_type='electron',
                              particle_shape='linear',
                              name='elec_beam')
    #initial_distribution = gauss_dist)

    secelec = picmi.Species(particle_type='electron',
                            particle_shape='linear',
                            name='Secondary electrons')

    ##########################
    # Numeric components
    ##########################

    if mysolver == 'ES':
        lower_boundary_conditions = ['dirichlet', 'dirichlet', 'dirichlet']
        upper_boundary_conditions = ['dirichlet', 'dirichlet', 'dirichlet']
    if mysolver == 'EM':
        lower_boundary_conditions = ['open', 'open', 'open']
        upper_boundary_conditions = ['open', 'open', 'open']

    grid = picmi.Cartesian3DGrid(
        number_of_cells=[nx, ny, nz],
        lower_bound=[xmin, ymin, zmin],
        upper_bound=[xmax, ymax, zmax],
        lower_boundary_conditions=lower_boundary_conditions,
        upper_boundary_conditions=upper_boundary_conditions)  #,
    #warpx_max_grid_size=32)

    if mysolver == 'ES':
        solver = picmi.ElectrostaticSolver(grid=grid)

    if mysolver == 'EM':
        smoother = picmi.BinomialSmoother(n_pass=[[1], [1], [1]],
                                          compensation=[[False], [False],
                                                        [False]],
                                          stride=[[1], [1], [1]],
                                          alpha=[[0.5], [0.5], [0.5]])

        solver = picmi.ElectromagneticSolver(
            grid=grid,
            method='CKC',
            cfl=1.,
            source_smoother=smoother,
            #                                     field_smoother = smoother,
            warp_l_correct_num_Cherenkov=False,
            warp_type_rz_depose=0,
            warp_l_setcowancoefs=True,
            warp_l_getrho=False)

    ##########################
    # Simulation setup
    ##########################
    sphere = picmi.warp.Sphere(r_sphere)
    box = picmi.warp.Box(xmax - xmin, ymax - ymin, zmax - zmin)
    wall = box - sphere
    sim = picmi.Simulation(solver=solver,
                           verbose=1,
                           cfl=1.0,
                           warp_initialize_solver_after_generate=1)

    sim.conductors = wall

    beam_layout = picmi.PseudoRandomLayout(n_macroparticles=10**5, seed=3)

    sim.add_species(elec_beam,
                    layout=beam_layout,
                    initialize_self_field=solver == 'EM')

    sim.add_species(secelec, layout=None, initialize_self_field=False)

    #########################
    # Add Dipole
    ########################

    vmod = picmi.warp.clight * np.sqrt(1 - 1. / (beam_gamma**2))
    vxgen = vmod * np.sin(thetagen) * np.cos(phigen)
    vygen = vmod * np.sin(thetagen) * np.sin(phigen)
    vzgen = vmod * np.cos(thetagen)

    def nonlinearsource():
        Nmp_inj = Nmp * (top.it == 3)
        x = xgen * np.ones(Nmp_inj)
        y = ygen * np.ones(Nmp_inj)
        z = zgen * np.ones(Nmp_inj)
        vx = vxgen * np.ones(Nmp_inj)
        vy = vygen * np.ones(Nmp_inj)
        vz = vzgen * np.ones(Nmp_inj)
        elec_beam.wspecies.addparticles(x=x,
                                        y=y,
                                        z=z,
                                        vx=vx,
                                        vy=vy,
                                        vz=vz,
                                        gi=1. / beam_gamma,
                                        w=N_elec_p_mp)

    picmi.warp.installuserinjection(nonlinearsource)

    ##########################
    # simulation run
    ##########################
    sim.step(1)
    solver.solver.installconductor(sim.conductors, dfill=picmi.warp.largepos)
    sim.step(1)

    pp = warp.ParticleScraper(sim.conductors,
                              lsavecondid=1,
                              lsaveintercept=1,
                              lcollectlpdata=1)

    sec = Secondaries(conductors=sim.conductors,
                      l_usenew=1,
                      pyecloud_secemi_object=sey_mod,
                      pyecloud_nel_mp_ref=N_elec_p_mp,
                      pyecloud_fact_clean=1e-16,
                      pyecloud_fact_split=1.5)

    sec.add(incident_species=elec_beam.wspecies,
            emitted_species=secelec.wspecies,
            conductor=sim.conductors)

    # --- set weights of secondary electrons
    #secelec.wspecies.getw()[...] = elecb.wspecies.getw()[0]

    # define shortcuts
    pw = picmi.warp
    em = solver.solver
    step = pw.step
    top.dt = dh / v

    n_step = 0
    tot_nsteps = int(np.ceil((tot_t / top.dt)))
    n_primelecs = []
    n_secelecs = []
    n_mp_primelecs = []
    n_mp_secelecs = []
    secelecs_dist = []
    primelecs_dist = []

    for n_step in range(tot_nsteps + 1):
        step(1)
        n_primelecs.append(np.sum(elec_beam.wspecies.getw()))
        n_secelecs.append(np.sum(secelec.wspecies.getw()))
        n_mp_primelecs.append(np.shape(elec_beam.wspecies.getw())[0])
        n_mp_secelecs.append(np.shape(secelec.wspecies.getw())[0])
        if flag_video:
            secelecs_dist.append(np.sum(secelec.wspecies.get_density(),
                                        axis=1))
            primelecs_dist.append(
                np.sum(elec_beam.wspecies.get_density(), axis=1))

    dict_out = {}
    dict_out['SEY'] = np.sum(secelec.wspecies.getw()) / (Nmp * N_elec_p_mp)
    dict_out['n_primelecs'] = np.array(n_primelecs)
    dict_out['n_secelecs'] = np.array(n_secelecs)
    dict_out['n_mp_primelecs'] = np.array(n_mp_primelecs)
    dict_out['n_mp_secelecs'] = np.array(n_mp_secelecs)
    dict_out['secelecs_dist'] = np.array(secelecs_dist)
    dict_out['primelecs_dist'] = np.array(primelecs_dist)
    dict_out['xmesh'] = solver.solver.xmesh.copy()
    dict_out['ymesh'] = solver.solver.ymesh.copy()
    dict_out['zmesh'] = solver.solver.zmesh.copy()

    #angle_dist =np.arctan(np.divide(secelec.wspecies.getvy(),secelec.wspecies.getvx()))
    #dict_out['angle_dist'] = angle_dist
    return dict_out
コード例 #3
0
def measure_SEY(Ekin):


    import numpy as np
    import numpy.random as random
    #from pywarpx import picmi
    from warp import picmi
    from scipy.stats import gaussian_kde
    from warp.particles.Secondaries import Secondaries, warp, top, posC, time
    import matplotlib.pyplot as plt
    import parser
    import scipy.io as sio
    from scipy.constants import m_e
    from scipy.constants import c as c_light
    from io import BytesIO as StringIO
    from mpi4py import MPI
    ##########################
    # physics parameters
    ##########################

    mysolver = 'ES' # solver type ('ES'=electrostatic; 'EM'=electromagnetic)

    # --- Beam

    ##########################
    # numerics parameters
    ##########################
    # geometry
    r = 0.005
    l = 0.1

    # --- grid
    dh = r/10.
    xmin = -2*r + 0.001
    xmax = -xmin
    ymin = -2*r + 0.001
    ymax = -ymin
    zmin = -l - 0.001
    zmax = l

    nx = (xmax-xmin)/dh
    ny = (xmax-xmin)/dh
    nz = (xmax-xmin)/dh

    #######################################################
    # compute beam size from normalized emittance and beta
    # Uncomment if data available
    #######################################################

    sigmax = 2e-4
    sigmay = 2.1e-4
    E0 = 0.511*1e6
    E = E0 + Ekin
    beam_gamma = E/E0
    beam_beta = np.sqrt(1-1/(beam_gamma*beam_gamma))
    v = beam_beta*c_light 

    elec_beam = picmi.Species(particle_type = 'electron',
                         particle_shape = 'linear',
                         name = 'elec_beam')
                         #initial_distribution = gauss_dist)


    secelec = picmi.Species(particle_type = 'electron',
                            particle_shape = 'linear',
                            name = 'Secondary electrons')

    ##########################
    # Numeric components
    ##########################

    if mysolver=='ES':
        lower_boundary_conditions = ['dirichlet', 'dirichlet', 'dirichlet']
        upper_boundary_conditions = ['dirichlet', 'dirichlet', 'dirichlet']
    if mysolver=='EM':
        lower_boundary_conditions = ['open', 'open', 'open']
        upper_boundary_conditions = ['open', 'open', 'open']


    grid = picmi.Cartesian3DGrid(number_of_cells = [nx, ny, nz],
                                 lower_bound = [xmin, ymin, zmin],
                                 upper_bound = [xmax, ymax, zmax],
                                 lower_boundary_conditions = lower_boundary_conditions,
                                 upper_boundary_conditions = upper_boundary_conditions)#,
    #warpx_max_grid_size=32)

    if mysolver=='ES':
        solver = picmi.ElectrostaticSolver(grid = grid)

    if mysolver=='EM':
        smoother = picmi.BinomialSmoother(n_pass = [[1], [1], [1]],
                                          compensation = [[False], [False], [False]],
                                          stride = [[1], [1], [1]],
                                          alpha = [[0.5], [0.5], [0.5]])

        solver = picmi.ElectromagneticSolver(grid = grid,
                                             method = 'CKC',
                                             cfl = 1.,
                                             source_smoother = smoother,
        #                                     field_smoother = smoother,
                                             warp_l_correct_num_Cherenkov = False,
                                             warp_type_rz_depose = 0,
                                             warp_l_setcowancoefs = True,
                                             warp_l_getrho = False)


    ##########################
    # Simulation setup
    ##########################
    wall = picmi.warp.YCylinderOut(r,l)

    sim = picmi.Simulation(solver = solver,
                           verbose = 1,
                           cfl = 1.0,
                           warp_initialize_solver_after_generate = 1)

    sim.conductors = wall

    beam_layout = picmi.PseudoRandomLayout(n_macroparticles = 10**5, seed = 3)

    sim.add_species(elec_beam, layout=beam_layout,
                    initialize_self_field = solver=='EM')

    sim.add_species(secelec, layout=None, initialize_self_field=False)

    #########################
    # Add Dipole
    #########################
    bunch_w = 1

    def nonlinearsource():
        NP = 1000*(top.it==3)
        x = 0*np.ones(NP)
        y = 0*np.ones(NP)
        z = 0*np.ones(NP)
        vx = np.zeros(NP)
        vy = np.zeros(NP)
        vz = picmi.warp.clight*np.sqrt(1-1./(beam_gamma**2))
        elec_beam.wspecies.addparticles(x=x,y=y,z=z,vx=vx,vy=vy,vz=vz,gi = 1./beam_gamma, w=bunch_w)

    picmi.warp.installuserinjection(nonlinearsource)


    ##########################
    # simulation run
    ##########################
    sim.step(1)
    solver.solver.installconductor(sim.conductors, dfill = picmi.warp.largepos)
    sim.step(1)


    pp = warp.ParticleScraper(sim.conductors,lsavecondid=1,lsaveintercept=1,lcollectlpdata=1)

    ####################################
    # Set material parameters from file
    ####################################

    def set_params_user(maxsec, matnum):
        dict = parser.pos2dic('LHC_inj_72bx5.in')
        
        posC.matsurf = dict['matsurf']
        posC.iprob = dict['iprob']
        
        posC.enpar = dict['enpar']
        
        posC.pnpar= dict['pnpar']
        
        posC.dtspk = dict['dtspk']
        posC.dtotpk = dict['dtotpk']
        posC.pangsec = dict['pangsec']
        posC.pr = dict['pr']
        posC.sige = dict['sige']
        posC.Ecr = dict['Ecr']
        posC.E0tspk = dict['E0tspk']
        posC.E0epk = dict['E0epk']
        posC.E0w = dict['E0w']
        posC.rpar1 = dict['rpar'][0]
        posC.rpar2 = dict['rpar'][1]
        posC.tpar1 = dict['tpar'][0]
        posC.tpar2 = dict['tpar'][1]
        posC.tpar3 = dict['tpar'][2]
        posC.tpar4 = dict['tpar'][3]
        posC.tpar5 = dict['tpar'][4]
        posC.tpar6 = dict['tpar'][5]
        posC.epar1 = dict['epar'][0]
        posC.epar2 = dict['epar'][1]
        posC.P1rinf = dict['P1rinf']
        posC.P1einf = dict['P1einf']
        posC.P1epk = dict['P1epk']
        posC.powts = dict['powts']
        posC.powe = dict['powe']
        posC.qr = dict['qr']


    sec=Secondaries(conductors=sim.conductors, set_params_user  = set_params_user,
                    l_usenew=1)

    sec.add(incident_species = elec_beam.wspecies,
            emitted_species  = secelec.wspecies,
            conductor        = sim.conductors)

    # --- set weights of secondary electrons
    #secelec.wspecies.getw()[...] = elecb.wspecies.getw()[0]

    # define shortcuts
    pw = picmi.warp
    em = solver.solver
    step=pw.step
    top.dt = dh/v

    n_step = 0
    tot_t = 2*r/v
    tot_nsteps = int(tot_t/top.dt)
    for n_step in range(tot_nsteps):
        step(1)
    secondaries_count = np.sum(secelec.wspecies.getw())

    return secondaries_count/1000
コード例 #4
0
def warp_pyecloud_dipole(z_length=None,
                         nx=None,
                         ny=None,
                         nz=None,
                         n_bunches=None,
                         b_spac=None,
                         beam_gamma=None,
                         sigmax=None,
                         sigmay=None,
                         sigmat=None,
                         bunch_intensity=None,
                         init_num_elecs=None,
                         init_num_elecs_mp=None,
                         By=None,
                         pyecloud_nel_mp_ref=None,
                         dt=None,
                         pyecloud_fact_clean=None,
                         pyecloud_fact_split=None,
                         chamber_type=None,
                         flag_save_video=None,
                         enable_trap=True,
                         Emax=None,
                         del_max=None,
                         R0=None,
                         E_th=None,
                         sigmafit=None,
                         mufit=None,
                         secondary_angle_distribution=None,
                         N_mp_max=None,
                         N_mp_target=None):

    import numpy as np
    import numpy.random as random
    from warp import picmi
    from scipy.stats import gaussian_kde
    from warp.particles.Secondaries import Secondaries, top, warp, time
    import matplotlib.pyplot as plt
    import scipy.io as sio
    from io import BytesIO as StringIO
    from scipy.constants import c as clight
    import sys
    import PyECLOUD.myfilemanager as mfm
    import os

    # Construct PyECLOUD secondary emission object
    import PyECLOUD.sec_emission_model_ECLOUD as seec
    sey_mod = seec.SEY_model_ECLOUD(Emax=Emax,
                                    del_max=del_max,
                                    R0=R0,
                                    E_th=E_th,
                                    sigmafit=sigmafit,
                                    mufit=mufit,
                                    secondary_angle_distribution='cosine_3D')

    ##########################
    # physics parameters
    ##########################

    mysolver = 'ES'  # solver type ('ES'=electrostatic; 'EM'=electromagnetic)

    ##########################
    # numerics parameters
    ##########################

    # --- grid

    zs_dipo = -0.5 * z_length
    ze_dipo = 0.5 * z_length
    r = 23.e-3
    h = 18.e-3
    l = z_length

    unit = 1e-3
    ghost = 1e-3
    xmin = -r - ghost
    xmax = r + ghost
    ymin = -r - ghost
    ymax = r + ghost
    zmin = zs_dipo - 50 * unit
    zmax = ze_dipo + 50 * unit

    if chamber_type == 'LHC':
        chamber_area = 0.0014664200235342726
    elif chamber_type == 'rect':
        chamber_area = 4 * r * h

    ##########################
    # Beam parameters
    ##########################
    sigmaz = sigmat * picmi.clight
    t_offs = b_spac - 6 * sigmat
    bunch_w = 1e6
    bunch_macro_particles = bunch_intensity / bunch_w

    #######################################################
    # compute beam size from normalized emittance and beta
    # Uncomment if data available
    #######################################################
    bunch_rms_size = [sigmax, sigmay, sigmaz]
    bunch_rms_velocity = [0., 0., 0.]
    bunch_centroid_position = [0, 0, zs_dipo - 10 * unit]
    bunch_centroid_velocity = [0., 0., beam_gamma * picmi.constants.c]

    beam = picmi.Species(particle_type='proton',
                         particle_shape='linear',
                         name='beam')

    lower_bound = [-r, -h, zs_dipo]
    upper_bound = [r, h, ze_dipo]
    temp_file_name = 'temp_mps_info.h5'

    ########################################################
    # if checkopoint is found reload it,
    # otherwise start from scratch
    ########################################################
    if not os.path.exists(temp_file_name):
        x0 = random.uniform(lower_bound[0], upper_bound[0], init_num_elecs_mp)
        y0 = random.uniform(lower_bound[1], upper_bound[1], init_num_elecs_mp)
        z0 = random.uniform(lower_bound[2], upper_bound[2], init_num_elecs_mp)
        vx0 = np.zeros(init_num_elecs_mp)
        vy0 = np.zeros(init_num_elecs_mp)
        vz0 = np.zeros(init_num_elecs_mp)

        w0 = float(init_num_elecs) / float(init_num_elecs_mp)
        b_pass_prev = 0
    else:
        print('############################################################')
        print('Temp distribution found. Regenarating and restarting')
        print('############################################################')
        dict_init_dist = mfm.dict_of_arrays_and_scalar_from_h5(temp_file_name)
        # Load particles status
        xold = dict_init_dist['x_mp']
        yold = dict_init_dist['y_mp']
        zold = dict_init_dist['z_mp']
        uxold = dict_init_dist['ux_mp']
        uyold = dict_init_dist['uy_mp']
        uzold = dict_init_dist['uz_mp']
        wold = dict_init_dist['w_mp']
        # Reload the outputs and other auxiliary stuff
        numelecs = dict_init_dist['numelecs']
        elecs_density = dict_init_dist['elecs_density']
        N_mp = dict_init_dist['N_mp']
        b_pass_prev = dict_init_dist['b_pass'] - 1
        # compute the velocities
        invgamma = np.sqrt(
            1 - picmi.clight**2 /
            (np.square(uxold) + np.square(uyold) + np.square(uzold)))
        vxold = np.multiply(invgamma, uxold)
        vyold = np.multiply(invgamma, uxold)
        vzold = np.multiply(invgamma, uxold)
        # perform the regeneration
        x0, y0, z0, vx0, vy0, vz0, w0, N_mpaa = perform_regeneration(
            N_mp_target, xold, yold, zold, vxold, vyold, vzold, wold)
        print('DEBUG N_mp: %d' % len(x0))
    electron_background_dist = picmi.ParticleListDistribution(x=x0,
                                                              y=y0,
                                                              z=z0,
                                                              vx=vx0,
                                                              vy=vy0,
                                                              vz=vz0,
                                                              weight=w0)

    elecb = picmi.Species(particle_type='electron',
                          particle_shape='linear',
                          name='Electron background',
                          initial_distribution=electron_background_dist)

    secelec = picmi.Species(particle_type='electron',
                            particle_shape='linear',
                            name='Secondary electrons')

    ##########################
    # Numeric components
    ##########################

    if mysolver == 'ES':
        lower_boundary_conditions = ['dirichlet', 'dirichlet', 'dirichlet']
        upper_boundary_conditions = ['dirichlet', 'dirichlet', 'dirichlet']
    if mysolver == 'EM':
        lower_boundary_conditions = ['open', 'open', 'open']
        upper_boundary_conditions = ['open', 'open', 'open']

    grid = picmi.Cartesian3DGrid(
        number_of_cells=[nx, ny, nz],
        lower_bound=[xmin, ymin, zmin],
        upper_bound=[xmax, ymax, zmax],
        lower_boundary_conditions=lower_boundary_conditions,
        upper_boundary_conditions=upper_boundary_conditions)

    if mysolver == 'ES':
        solver = picmi.ElectrostaticSolver(grid=grid)

    if mysolver == 'EM':
        smoother = picmi.BinomialSmoother(n_pass=[[1], [1], [1]],
                                          compensation=[[False], [False],
                                                        [False]],
                                          stride=[[1], [1], [1]],
                                          alpha=[[0.5], [0.5], [0.5]])
        solver = picmi.ElectromagneticSolver(
            grid=grid,
            method='CKC',
            cfl=1.,
            source_smoother=smoother,
            warp_l_correct_num_Cherenkov=False,
            warp_type_rz_depose=0,
            warp_l_setcowancoefs=True,
            warp_l_getrho=False)

    ##########################
    # Simulation setup
    ##########################

    pipe = picmi.warp.ZCylinderOut(r, l, condid=1)

    if chamber_type == 'rect':
        upper_box = picmi.warp.YPlane(y0=h, ysign=1, condid=1)
        lower_box = picmi.warp.YPlane(y0=-h, ysign=-1, condid=1)
        left_box = picmi.warp.XPlane(x0=r, xsign=1, condid=1)
        right_box = picmi.warp.XPlane(x0=-r, xsign=-1, condid=1)

        sim = picmi.Simulation(solver=solver,
                               verbose=1,
                               cfl=1.0,
                               warp_initialize_solver_after_generate=1)

        sim.conductors = upper_box + lower_box + left_box + right_box

    elif chamber_type == 'LHC':
        pipe = picmi.warp.ZCylinderOut(r, l, condid=1)
        upper_box = picmi.warp.YPlane(y0=h, ysign=1, condid=1)
        lower_box = picmi.warp.YPlane(y0=-h, ysign=-1, condid=1)

        sim = picmi.Simulation(solver=solver,
                               verbose=1,
                               cfl=1.0,
                               warp_initialize_solver_after_generate=1)

        sim.conductors = pipe + upper_box + lower_box

    beam_layout = picmi.PseudoRandomLayout(n_macroparticles=10**5, seed=3)

    sim.add_species(beam,
                    layout=beam_layout,
                    initialize_self_field=solver == 'EM')

    elecb_layout = picmi.PseudoRandomLayout(n_macroparticles=init_num_elecs_mp,
                                            seed=3)

    sim.add_species(elecb,
                    layout=elecb_layout,
                    initialize_self_field=solver == 'EM')
    sim.add_species(secelec, layout=None, initialize_self_field=False)
    #########################
    # Add Dipole
    #########################
    picmi.warp.addnewdipo(zs=zs_dipo, ze=ze_dipo, by=By)

    def time_prof(t):
        val = 0
        sigmat = sigmaz / picmi.clight
        for i in range(1, n_bunches + 1):
            val += bunch_macro_particles * 1. / np.sqrt(
                2 * np.pi * sigmat * sigmat) * np.exp(
                    -(t - i * b_spac + t_offs) * (t - i * b_spac + t_offs) /
                    (2 * sigmat * sigmat)) * picmi.warp.top.dt
        return val

    def nonlinearsource():
        NP = int(time_prof(top.time))
        x = random.normal(bunch_centroid_position[0], bunch_rms_size[0], NP)
        y = random.normal(bunch_centroid_position[1], bunch_rms_size[1], NP)
        z = bunch_centroid_position[2]
        vx = random.normal(bunch_centroid_velocity[0], bunch_rms_velocity[0],
                           NP)
        vy = random.normal(bunch_centroid_velocity[1], bunch_rms_velocity[1],
                           NP)
        vz = picmi.warp.clight * np.sqrt(1 - 1. / (beam_gamma**2))
        beam.wspecies.addparticles(x=x,
                                   y=y,
                                   z=z,
                                   vx=vx,
                                   vy=vy,
                                   vz=vz,
                                   gi=1. / beam_gamma,
                                   w=bunch_w)

    picmi.warp.installuserinjection(nonlinearsource)

    ##########################
    # simulation run
    ##########################
    sim.step(1)
    solver.solver.installconductor(sim.conductors, dfill=picmi.warp.largepos)
    sim.step(1)

    pp = warp.ParticleScraper(sim.conductors,
                              lsavecondid=1,
                              lsaveintercept=1,
                              lcollectlpdata=1)

    sec = Secondaries(conductors=sim.conductors,
                      l_usenew=1,
                      pyecloud_secemi_object=sey_mod,
                      pyecloud_nel_mp_ref=pyecloud_nel_mp_ref,
                      pyecloud_fact_clean=pyecloud_fact_clean,
                      pyecloud_fact_split=pyecloud_fact_split)

    sec.add(incident_species=elecb.wspecies,
            emitted_species=secelec.wspecies,
            conductor=sim.conductors)

    sec.add(incident_species=secelec.wspecies,
            emitted_species=secelec.wspecies,
            conductor=sim.conductors)

    # just some shortcuts
    pw = picmi.warp
    step = pw.step

    if mysolver == 'ES':
        pw.top.dt = dt

    def myplots(l_force=0):
        if l_force or pw.top.it % 10 == 0:
            plt.close()
            (Nx, Ny, Nz) = np.shape(secelec.wspecies.get_density())
            fig, axs = plt.subplots(1, 2, figsize=(12, 4.5))
            fig.subplots_adjust(left=0.05,
                                bottom=0.1,
                                right=0.97,
                                top=0.94,
                                wspace=0.15)
            d = secelec.wspecies.get_density() + elecb.wspecies.get_density(
            ) + beam.wspecies.get_density()
            d2 = secelec.wspecies.get_density() + elecb.wspecies.get_density()
            im1 = axs[0].imshow(d[:, :, Nz / 2].T,
                                cmap='jet',
                                origin='lower',
                                vmin=0.2 * np.min(d2[:, :, Nz / 2]),
                                vmax=0.8 * np.max(d2[:, :, Nz / 2]),
                                extent=[xmin, xmax, ymin, ymax])
            axs[0].set_xlabel('x [m]')
            axs[0].set_ylabel('y [m]')
            axs[0].set_title('e- density')
            fig.colorbar(
                im1,
                ax=axs[0],
            )
            im2 = axs[1].imshow(d[Nx / 2, :, :],
                                cmap='jet',
                                origin='lower',
                                vmin=0.2 * np.min(d2[Nx / 2, :, :]),
                                vmax=0.8 * np.max(d2[Nx / 2, :, :]),
                                extent=[zmin, zmax, ymin, ymax],
                                aspect='auto')
            axs[1].set_xlabel('z [m]')
            axs[1].set_ylabel('y [m]')
            axs[1].set_title('e- density')
            fig.colorbar(im2, ax=axs[1])
            n_step = top.time / top.dt
            figname = 'images/%d.png' % n_step
            plt.savefig(figname)

    if flag_save_video:
        pw.installafterstep(myplots)
        myplots(1)

    ntsteps_p_bunch = b_spac / top.dt
    tot_nsteps = int(np.ceil(b_spac * (n_bunches) / top.dt))
    t_start = b_pass_prev * b_spac
    tstep_start = int(round(t_start / top.dt))

    # pre-allocate outputs
    if not os.path.exists('temp_mps_info.h5'):
        numelecs = np.zeros(tot_nsteps)
        elecs_density = np.zeros((tot_nsteps, nx + 1, ny + 1, 3))
        beam_density = np.zeros((tot_nsteps, nx + 1, ny + 1, 3))
        N_mp = np.zeros(tot_nsteps)

    dict_out = {}

    # aux variables
    b_pass = 0
    perc = 10
    original = sys.stdout
    text_trap = StringIO()
    t0 = time.time()

    # trapping warp std output
    text_trap = {True: StringIO(), False: sys.stdout}[enable_trap]
    original = sys.stdout

    for n_step in range(tstep_start, tot_nsteps):
        # if a passage is starting...
        if n_step / ntsteps_p_bunch >= b_pass + b_pass_prev:
            b_pass += 1
            perc = 10
            if secelec.wspecies.getn() > N_mp_max:
                dict_out_temp = {}
                print('Number of macroparticles: %d' %
                      (secelec.wspecies.getn() + elecb.wspecies.getn()))
                print('MAXIMUM LIMIT OF MPS HAS BEEN RACHED')
                print('Please restart the simulation')
                dict_out_temp['x_mp'] = np.concatenate(
                    (secelec.wspecies.getx(), elecb.wspecies.getx()))
                dict_out_temp['y_mp'] = np.concatenate(
                    (secelec.wspecies.gety(), elecb.wspecies.gety()))
                dict_out_temp['z_mp'] = np.concatenate(
                    (secelec.wspecies.getz(), elecb.wspecies.gety()))
                dict_out_temp['ux_mp'] = np.concatenate(
                    (secelec.wspecies.getux(), elecb.wspecies.getux()))
                dict_out_temp['uy_mp'] = np.concatenate(
                    (secelec.wspecies.getuy(), elecb.wspecies.getuy()))
                dict_out_temp['uz_mp'] = np.concatenate(
                    (secelec.wspecies.getuz(), elecb.wspecies.getuz()))
                dict_out_temp['w_mp'] = np.concatenate(
                    (secelec_w, elecb.wspecies.getw()))

                dict_out_temp['numelecs'] = numelecs
                dict_out_temp['elecs_density'] = elecs_density
                dict_out_temp['N_mp'] = N_mp

                dict_out_temp['b_pass'] = b_pass + b_pass_prev

                filename = 'temp_mps_info.h5'

                mfm.dict_to_h5(dict_out_temp, filename)

                return

            print('===========================')
            print('Bunch passage: %d' % (b_pass + b_pass_prev))
            print('Number of electrons in the dipole: %d' %
                  (np.sum(secelec.wspecies.getw()) +
                   np.sum(elecb.wspecies.getw())))
            print('Number of macroparticles: %d' %
                  (secelec.wspecies.getn() + elecb.wspecies.getn()))

        if n_step % ntsteps_p_bunch / ntsteps_p_bunch * 100 > perc:
            print('%d%% of bunch passage' % perc)
            perc = perc + 10

        sys.stdout = text_trap
        step(1)
        sys.stdout = original
        #print(elecb.wspecies.getvy()[0])
        # store outputs
        secelec_w = secelec.wspecies.getw()
        elecb_w = elecb.wspecies.getw()
        numelecs[n_step] = np.sum(secelec_w) + np.sum(elecb_w)
        elecs_density[n_step, :, :, :] = secelec.wspecies.get_density(
        )[:, :, (nz + 1) / 2 - 1:(nz + 1) / 2 +
          2] + elecb.wspecies.get_density()[:, :,
                                            (nz + 1) / 2 - 1:(nz + 1) / 2 + 2]
        N_mp[n_step] = len(secelec_w) + len(elecb_w)

    t1 = time.time()
    totalt = t1 - t0
    dict_out['numelecs'] = numelecs
    dict_out['elecs_density'] = elecs_density
    dict_out['N_mp'] = N_mp

    mfm.dict_to_h5(dict_out, 'output.h5')

    if os.path.exists('temp_mps_info.h5'):
        os.remove('temp_mps_info.h5')

    print('Run terminated in %ds' % totalt)
コード例 #5
0
    def __init__(self,
                 z_length=None,
                 nx=None,
                 ny=None,
                 nz=None,
                 dh_t=None,
                 n_bunches=None,
                 b_spac=None,
                 beam_gamma=None,
                 sigmax=None,
                 sigmay=None,
                 sigmat=None,
                 bunch_intensity=None,
                 init_num_elecs=None,
                 init_num_elecs_mp=None,
                 By=None,
                 pyecloud_nel_mp_ref=None,
                 dt=None,
                 pyecloud_fact_clean=None,
                 pyecloud_fact_split=None,
                 chamber_type=None,
                 flag_save_video=None,
                 enable_trap=True,
                 Emax=None,
                 del_max=None,
                 R0=None,
                 E_th=None,
                 sigmafit=None,
                 mufit=None,
                 secondary_angle_distribution=None,
                 N_mp_max=None,
                 N_mp_target=None,
                 flag_checkpointing=False,
                 checkpoints=None,
                 flag_output=False,
                 bunch_macro_particles=None,
                 t_offs=None,
                 width=None,
                 height=None,
                 output_name='output.mat',
                 flag_relativ_tracking=False,
                 nbins=100,
                 radius=None,
                 lattice_elem=None,
                 ghost=None,
                 ghost_z=None,
                 stride_imgs=10,
                 stride_output=1000):

        # Construct PyECLOUD secondary emission object
        sey_mod = seec.SEY_model_ECLOUD(
            Emax=Emax,
            del_max=del_max,
            R0=R0,
            E_th=E_th,
            sigmafit=sigmafit,
            mufit=mufit,
            secondary_angle_distribution='cosine_3D')

        ##########################
        # physics parameters
        ##########################

        mysolver = 'ES'  # solver type ('ES'=electrostatic; 'EM'=electromagnetic)

        ##########################
        # numerics parameters
        ##########################
        self.nbins = nbins
        self.N_mp_target = N_mp_target
        self.N_mp_max = N_mp_max
        self.nx = nx
        self.ny = ny
        self.nz = nz
        self.flag_checkpointing = flag_checkpointing
        self.flag_output = flag_output
        self.output_name = output_name
        self.stride_imgs = stride_imgs
        self.stride_output = stride_output
        # --- grid
        if lattice_elem == 'dipole':
            zs_dipo = -0.5 * z_length
            ze_dipo = 0.5 * z_length

        # Consistency check
        if chamber_type == 'rect':
            assert (height is not None) and (
                width is not None
            ), 'When using rectangular chamber, height and width must be specified'
        if chamber_type == 'circle':
            assert radius is not None, 'When using circular chamber r must be specified'
        if chamber_type == 'LHC':
            radius = 23.e-3
            height = 2 * 18.e-3
            width = 2 * radius

        z_length

        unit = 1e-3
        if ghost is None:
            ghost = 1e-3

        if ghost_z is None:
            ghost_z = ghost

        if chamber_type == 'rect' or chamber_type == 'LHC':
            self.xmin = -width / 2. - ghost
            self.xmax = -self.xmin
            self.ymin = -height / 2 - ghost
            self.ymax = -self.ymin
            self.zmin = zs_dipo - 50 * unit
            self.zmax = ze_dipo + 50 * unit

            lower_bound = [-width / 2, -height / 2, zs_dipo]
            upper_bound = [width / 2, height / 2, ze_dipo]
        elif chamber_type == 'circle':
            self.xmin = -radius - ghost
            self.xmax = radius + ghost
            self.ymin = -radius - ghost
            self.ymax = radius + ghost
            self.zmin = zs_dipo - 50 * unit
            self.zmax = ze_dipo + 50 * unit

            lower_bound = [-radius, -radius, zs_dipo]
            upper_bound = [radius, radius, ze_dipo]
        elif chamber_type == 'crab':
            max_z = 500 * unit
            l_main_y = 242 * unit
            l_main_x = 300 * unit
            l_main_z = 350 * unit
            l_beam_pipe = 84 * unit
            l_int = 62 * unit
            l_main_int_y = l_main_y - 0.5 * l_beam_pipe
            l_main_int_z = 0.5 * l_main_z - l_int
            l_main_int_x = 0.5 * l_main_x - l_int

            self.xmin = -0.5 * l_main_x - ghost
            self.xmax = 0.5 * l_main_x + ghost
            self.ymin = -0.5 * l_main_y - ghost
            self.ymax = 0.5 * l_main_y + ghost
            self.zmin = -0.5 * max_z - 50 * unit
            self.zmax = 0.5 * max_z + 50 * unit

            lower_bound = [-0.5 * l_main_x, -0.5 * l_main_y, -0.5 * l_main_z]
            upper_bound = [0.5 * l_main_x, 0.5 * l_main_y, 0.5 * l_main_z]

    ##########################
    # Beam parameters
    ##########################
        sigmaz = sigmat * picmi.clight
        if bunch_macro_particles > 0:
            bunch_w = bunch_intensity / bunch_macro_particles
        else:
            bunch_w = 0

        #######################################################
        # compute beam size from normalized emittance and beta
        # Uncomment if data available
        #######################################################
        bunch_rms_size = [sigmax, sigmay, sigmaz]
        bunch_rms_velocity = [0., 0., 0.]
        if chamber_type == 'crab':
            bunch_centroid_position = [0, 0, self.zmin + 10 * unit]
        else:
            bunch_centroid_position = [0, 0, zs_dipo - 10 * unit]

        bunch_centroid_velocity = [0., 0., beam_gamma * picmi.constants.c]

        self.beam = picmi.Species(particle_type='proton',
                                  particle_shape='linear',
                                  name='beam')
        temp_file_name = 'temp_mps_info.mat'

        ########################################################
        # if checkopoint is found reload it,
        # otherwise start from scratch
        ########################################################
        if flag_checkpointing and os.path.exists(temp_file_name):
            print(
                '############################################################')
            print('Temp distribution found. Regenarating and restarting')
            print(
                '############################################################')
            dict_init_dist = sio.loadmat(temp_file_name)
            # Load particles status
            x0 = dict_init_dist['x_mp'][0]
            y0 = dict_init_dist['y_mp'][0]
            z0 = dict_init_dist['z_mp'][0]
            vx0 = dict_init_dist['vx_mp'][0]
            vy0 = dict_init_dist['vy_mp'][0]
            vz0 = dict_init_dist['vz_mp'][0]
            w0 = dict_init_dist['nel_mp'][0]
            # compute the velocities
            #invgamma = np.sqrt(1-picmi.clight**2/(np.square(ux0)+np.square(uy0)+np.square(uz0)))
            #vx0 = np.multiply(invgamma,ux0)
            #vy0 = np.multiply(invgamma,uy0)
            #vz0 = np.multiply(invgamma,uy0)
            # Reload the outputs and other auxiliary stuff
            if flag_output:
                self.numelecs = dict_init_dist['numelecs'][0]
                self.N_mp = dict_init_dist['N_mp'][0]
                self.numelecs_tot = dict_init_dist['numelecs_tot'][0]
                self.xhist = dict_init_dist['xhist']
                self.bins = dict_init_dist['bins']
                self.b_pass_prev = dict_init_dist['b_pass'] - 1
        else:
            if chamber_type == 'circle':
                x0 = random.uniform(lower_bound[0], upper_bound[0],
                                    init_num_elecs_mp)
                y0 = random.uniform(lower_bound[1], upper_bound[1],
                                    init_num_elecs_mp)
                z0 = random.uniform(lower_bound[2], upper_bound[2],
                                    init_num_elecs_mp)
                vx0 = np.zeros(init_num_elecs_mp)
                vy0 = np.zeros(init_num_elecs_mp)
                vz0 = np.zeros(init_num_elecs_mp)

                r0_sq = np.square(x0) + np.square(y0)
                flag_out = np.where(r0_sq > radius * radius)[0]
                Nout = len(flag_out)
                while Nout > 0:
                    x0[flag_out] = random.uniform(lower_bound[0],
                                                  upper_bound[0], Nout)
                    y0[flag_out] = random.uniform(lower_bound[1],
                                                  upper_bound[1], Nout)

                    r0_sq = np.square(x0) + np.square(y0)
                    flag_out = np.where(r0_sq > radius * radius)[0]
                    Nout = len(flag_out)

                w0 = float(init_num_elecs) / float(init_num_elecs_mp)
            elif chamber_type == 'crab':
                x0 = random.uniform(lower_bound[0], upper_bound[0],
                                    init_num_elecs_mp)
                y0 = random.uniform(lower_bound[1], upper_bound[1],
                                    init_num_elecs_mp)
                z0 = random.uniform(lower_bound[2], upper_bound[2],
                                    init_num_elecs_mp)
                vx0 = np.zeros(init_num_elecs_mp)
                vy0 = np.zeros(init_num_elecs_mp)
                vz0 = np.zeros(init_num_elecs_mp)

                flag_out = np.where(
                    np.logical_and(
                        np.logical_and(
                            np.logical_and(x0 < l_main_int_x,
                                           x0 > -l_main_int_x),
                            np.logical_and(z0 < l_main_int_z,
                                           z0 > -l_main_int_z)),
                        np.logical_or(y0 > 0.5 * l_beam_pipe,
                                      y0 < -0.5 * l_beam_pipe)))[0]
                Nout = len(flag_out)
                while Nout > 0:
                    x0[flag_out] = random.uniform(lower_bound[0],
                                                  upper_bound[0], Nout)
                    y0[flag_out] = random.uniform(lower_bound[1],
                                                  upper_bound[1], Nout)
                    z0[flag_out] = random.uniform(lower_bound[2],
                                                  upper_bound[2], Nout)

                    flag_out = np.where(
                        np.logical_and(
                            np.logical_and(
                                np.logical_and(x0 < l_main_int_x,
                                               x0 > -l_main_int_x),
                                np.logical_and(z0 < l_main_int_z,
                                               z0 > -l_main_int_z)),
                            np.logical_or(y0 > 0.5 * l_beam_pipe,
                                          y0 < -0.5 * l_beam_pipe)))[0]

                    Nout = len(flag_out)

                w0 = float(init_num_elecs) / float(init_num_elecs_mp)

            else:
                x0 = random.uniform(lower_bound[0], upper_bound[0],
                                    init_num_elecs_mp)
                y0 = random.uniform(lower_bound[1], upper_bound[1],
                                    init_num_elecs_mp)
                z0 = random.uniform(lower_bound[2], upper_bound[2],
                                    init_num_elecs_mp)
                vx0 = np.zeros(init_num_elecs_mp)
                vy0 = np.zeros(init_num_elecs_mp)
                vz0 = np.zeros(init_num_elecs_mp)
                w0 = float(init_num_elecs) / float(init_num_elecs_mp)

            self.b_pass_prev = 0

        electron_background_dist = picmi.ParticleListDistribution(x=x0,
                                                                  y=y0,
                                                                  z=z0,
                                                                  vx=vx0,
                                                                  vy=vy0,
                                                                  vz=vz0,
                                                                  weight=w0)

        self.elecb = picmi.Species(
            particle_type='electron',
            particle_shape='linear',
            name='Electron background',
            initial_distribution=electron_background_dist)

        self.secelec = picmi.Species(particle_type='electron',
                                     particle_shape='linear',
                                     name='Secondary electrons')

        ##########################
        # Numeric components
        ##########################

        if mysolver == 'ES':
            lower_boundary_conditions = ['dirichlet', 'dirichlet', 'dirichlet']
            upper_boundary_conditions = ['dirichlet', 'dirichlet', 'dirichlet']
        if mysolver == 'EM':
            lower_boundary_conditions = ['open', 'open', 'open']
            upper_boundary_conditions = ['open', 'open', 'open']

        grid = picmi.Cartesian3DGrid(
            number_of_cells=[self.nx, self.ny, self.nz],
            lower_bound=[self.xmin, self.ymin, self.zmin],
            upper_bound=[self.xmax, self.ymax, self.zmax],
            lower_boundary_conditions=lower_boundary_conditions,
            upper_boundary_conditions=upper_boundary_conditions)

        if mysolver == 'ES':
            solver = picmi.ElectrostaticSolver(grid=grid)
        if mysolver == 'EM':
            smoother = picmi.BinomialSmoother(n_pass=[[1], [1], [1]],
                                              compensation=[[False], [False],
                                                            [False]],
                                              stride=[[1], [1], [1]],
                                              alpha=[[0.5], [0.5], [0.5]])
            solver = picmi.ElectromagneticSolver(
                grid=grid,
                method='CKC',
                cfl=1.,
                source_smoother=smoother,
                warp_l_correct_num_Cherenkov=False,
                warp_type_rz_depose=0,
                warp_l_setcowancoefs=True,
                warp_l_getrho=False)

        ##########################
        # Simulation setup
        ##########################

        if chamber_type == 'rect':
            print('Using rectangular chamber with xaper: %1.2e, yaper: %1.2e' %
                  (width / 2., height / 2.))
            upper_box = picmi.warp.YPlane(y0=height / 2., ysign=1, condid=1)
            lower_box = picmi.warp.YPlane(y0=-height / 2., ysign=-1, condid=1)
            left_box = picmi.warp.XPlane(x0=width / 2., xsign=1, condid=1)
            right_box = picmi.warp.XPlane(x0=-width / 2., xsign=-1, condid=1)

            sim = picmi.Simulation(solver=solver,
                                   verbose=1,
                                   cfl=1.0,
                                   warp_initialize_solver_after_generate=1)

            sim.conductors = upper_box + lower_box + left_box + right_box

        elif chamber_type == 'LHC':
            print('Using the LHC chamber')
            #pipe_annulus = picmi.warp.ZAnnulus(rmin = radius, rmax    = radius+ghost/2, length  = l, condid =1)
            upper_box = picmi.warp.YPlane(y0=height / 2, ysign=1, condid=1)
            lower_box = picmi.warp.YPlane(y0=-height / 2, ysign=-1, condid=1)
            pipe = picmi.warp.ZCylinderOut(radius=radius,
                                           length=z_length,
                                           condid=1)

            sim = picmi.Simulation(solver=solver,
                                   verbose=1,
                                   cfl=1.0,
                                   warp_initialize_solver_after_generate=1)

            sim.conductors = pipe + upper_box + lower_box

        elif chamber_type == 'circle':
            print('Using a circular chamber with radius %1.2e' % radius)
            pipe_annulus = picmi.warp.ZAnnulus(rmin=radius,
                                               rmax=radius + ghost,
                                               length=l,
                                               voltage=0.,
                                               xcent=0.,
                                               ycent=0.,
                                               zcent=0.,
                                               condid=1)
            pipe = picmi.warp.ZCylinderOut(radius=radius, length=l, condid=1)

            sim = picmi.Simulation(solver=solver,
                                   verbose=1,
                                   cfl=1.0,
                                   warp_initialize_solver_after_generate=1)

            sim.conductors = pipe_annulus

        elif chamber_type == 'crab':
            print('Simulating ECLOUD in a crab cavity')
            box1 = picmi.warp.Box(zsize=self.zmax - self.zmin,
                                  xsize=self.xmax - self.xmin,
                                  ysize=self.ymax - self.ymin)
            box2 = picmi.warp.Box(zsize=self.zmax - self.zmin,
                                  xsize=l_beam_pipe,
                                  ysize=l_beam_pipe)
            box3 = picmi.warp.Box(zsize=l_main_z,
                                  xsize=l_main_x,
                                  ysize=l_main_y)
            # Shape the cavity
            ycen1 = 0.5 * l_beam_pipe + l_main_int_y
            ycen2 = -ycen1
            box4 = picmi.warp.Box(zsize=2 * l_main_int_z,
                                  xsize=2 * l_main_int_x,
                                  ysize=2 * l_main_int_y,
                                  ycent=ycen1)
            box5 = picmi.warp.Box(zsize=2 * l_main_int_z,
                                  xsize=2 * l_main_int_x,
                                  ysize=2 * l_main_int_y,
                                  ycent=ycen2)

            sim = picmi.Simulation(solver=solver,
                                   verbose=1,
                                   cfl=1.0,
                                   warp_initialize_solver_after_generate=1)

            sim.conductors = box1 - box2 - box3 + box4 + box5

        sim.add_species(self.beam,
                        layout=None,
                        initialize_self_field=solver == 'EM')

        self.elecb_layout = picmi.PseudoRandomLayout(
            n_macroparticles=init_num_elecs_mp, seed=3)

        sim.add_species(self.elecb,
                        layout=self.elecb_layout,
                        initialize_self_field=solver == 'EM')

        sim.add_species(self.secelec, layout=None, initialize_self_field=False)

        #########################
        # Add Dipole
        #########################
        if lattice_elem == 'dipole':
            picmi.warp.addnewdipo(zs=zs_dipo, ze=ze_dipo, by=By)
        elif lattice_elem == 'crab':
            [self.x, self.y, self.z, self.Ex, self.Ey,
             self.Ez] = picmi.getdatafromtextfile("efield.txt",
                                                  nskip=1,
                                                  dims=[6, None])
            [_, _, _, Hx, Hy, Hz] = picmi.getdatafromtextfile("hfield.txt",
                                                              nskip=1,
                                                              dims=[6, None])

            self.Bx = Hx * picmi.mu0
            self.By = Hy * picmi.mu0
            self.Bz = Hz * picmi.mu0

            ### Interpolate them at cell centers (as prescribed by Warp doc)
            self.d = abs(self.x[1] - self.x[0])
            ### Number of mesh cells
            self.NNx = int(round(2 * np.max(self.x) / self.d))
            self.NNy = int(round(2 * np.max(self.y) / self.d))
            self.NNz = int(round(2 * np.max(self.z) / self.d))
            ### Number of mesh vertices
            self.nnx = self.NNx + 1
            self.nny = self.NNy + 1
            self.nnz = self.NNz + 1

            self.Ex3d = self.Ex.reshape(self.nnz, self.nny,
                                        self.nnx).transpose(2, 1, 0)
            self.Ey3d = self.Ey.reshape(self.nnz, self.nny,
                                        self.nnx).transpose(2, 1, 0)
            self.Ez3d = self.Ez.reshape(self.nnz, self.nny,
                                        self.nnx).transpose(2, 1, 0)
            self.Bx3d = self.Bx.reshape(self.nnz, self.nny,
                                        self.nnx).transpose(2, 1, 0)
            self.By3d = self.By.reshape(self.nnz, self.nny,
                                        self.nnx).transpose(2, 1, 0)
            self.Bz3d = self.Bz.reshape(self.nnz, self.nny,
                                        self.nnx).transpose(2, 1, 0)
            self.x3d = self.x.reshape(self.nnz, self.nny,
                                      self.nnx).transpose(2, 1, 0)
            self.y3d = self.y.reshape(self.nnz, self.nny,
                                      self.nnx).transpose(2, 1, 0)
            self.z3d = self.z.reshape(self.nnz, self.nny,
                                      self.nnx).transpose(2, 1, 0)

            ### Rescale the fields at convenience
            maxE = 57 * 1e6
            kk = maxE / np.max(abs(self.Ey3d))

            self.Ex3d *= kk
            self.Ey3d *= kk
            self.Ez3d *= kk
            self.Bx3d *= kk
            self.By3d *= kk
            self.Bz3d *= kk

            self.Exx = 0.125 * (
                self.Ex3d[0:-1, 0:-1, 0:-1] + self.Ex3d[0:-1:, 0:-1, 1:] +
                self.Ex3d[0:-1, 1:, 0:-1] + self.Ex3d[0:-1, 1:, 1:] +
                self.Ex3d[1:, 1:, 0:-1] + self.Ex3d[1:, 1:, 1:] +
                self.Ex3d[1:, 0:-1, 1:] + self.Ex3d[1:, 0:-1, 0:-1])

            self.Eyy = 0.125 * (
                self.Ey3d[0:-1, 0:-1, 0:-1] + self.Ey3d[0:-1:, 0:-1, 1:] +
                self.Ey3d[0:-1, 1:, 0:-1] + self.Ey3d[0:-1, 1:, 1:] +
                self.Ey3d[1:, 1:, 0:-1] + self.Ey3d[1:, 1:, 1:] +
                self.Ey3d[1:, 0:-1, 1:] + self.Ey3d[1:, 0:-1, 0:-1])

            self.Ezz = 0.125 * (
                self.Ez3d[0:-1, 0:-1, 0:-1] + self.Ez3d[0:-1:, 0:-1, 1:] +
                self.Ez3d[0:-1, 1:, 0:-1] + self.Ez3d[0:-1, 1:, 1:] +
                self.Ez3d[1:, 1:, 0:-1] + self.Ez3d[1:, 1:, 1:] +
                self.Ez3d[1:, 0:-1, 1:] + self.Ez3d[1:, 0:-1, 0:-1])

            self.Bxx = 0.125 * (
                self.Bx3d[0:-1, 0:-1, 0:-1] + self.Bx3d[0:-1:, 0:-1, 1:] +
                self.Bx3d[0:-1, 1:, 0:-1] + self.Bx3d[0:-1, 1:, 1:] +
                self.Bx3d[1:, 1:, 0:-1] + self.Bx3d[1:, 1:, 1:] +
                self.Bx3d[1:, 0:-1, 1:] + self.Bx3d[1:, 0:-1, 0:-1])

            self.Byy = 0.125 * (
                self.By3d[0:-1, 0:-1, 0:-1] + self.By3d[0:-1:, 0:-1, 1:] +
                self.By3d[0:-1, 1:, 0:-1] + self.By3d[0:-1, 1:, 1:] +
                self.By3d[1:, 1:, 0:-1] + self.By3d[1:, 1:, 1:] +
                self.By3d[1:, 0:-1, 1:] + self.By3d[1:, 0:-1, 0:-1])

            self.Bzz = 0.125 * (
                self.Bz3d[0:-1, 0:-1, 0:-1] + self.Bz3d[0:-1:, 0:-1, 1:] +
                self.Bz3d[0:-1, 1:, 0:-1] + self.Bz3d[0:-1, 1:, 1:] +
                self.Bz3d[1:, 1:, 0:-1] + self.Bz3d[1:, 1:, 1:] +
                self.Bz3d[1:, 0:-1, 1:] + self.Bz3d[1:, 0:-1, 0:-1])

            self.xx = 0.125 * (
                self.x3d[0:-1, 0:-1, 0:-1] + self.x3d[0:-1:, 0:-1, 1:] +
                self.x3d[0:-1, 1:, 0:-1] + self.x3d[0:-1, 1:, 1:] +
                self.x3d[1:, 1:, 0:-1] + self.x3d[1:, 1:, 1:] +
                self.x3d[1:, 0:-1, 1:] + self.x3d[1:, 0:-1, 0:-1])

            self.yy = 0.125 * (
                self.y3d[0:-1, 0:-1, 0:-1] + self.y3d[0:-1:, 0:-1, 1:] +
                self.y3d[0:-1, 1:, 0:-1] + self.y3d[0:-1, 1:, 1:] +
                self.y3d[1:, 1:, 0:-1] + self.y3d[1:, 1:, 1:] +
                self.y3d[1:, 0:-1, 1:] + self.y3d[1:, 0:-1, 0:-1])

            self.zz = 0.125 * (
                self.z3d[0:-1, 0:-1, 0:-1] + self.z3d[0:-1:, 0:-1, 1:] +
                self.z3d[0:-1, 1:, 0:-1] + self.z3d[0:-1, 1:, 1:] +
                self.z3d[1:, 1:, 0:-1] + self.z3d[1:, 1:, 1:] +
                self.z3d[1:, 0:-1, 1:] + self.z3d[1:, 0:-1, 0:-1])

            ### Lattice spatial parameters
            self.zs = np.min(self.z3d) - self.d / 2.
            self.ze = np.max(self.z3d) + self.d / 2.
            self.xs = np.min(self.x3d) - self.d / 2.
            self.ys = np.min(self.y3d) - self.d / 2.
            ### Lattice temporal parameters
            self.Tf = 25e-9
            self.freq = 400 * 1e6
            self.Nt = 1000
            self.phase_disp = 0
            self.time_array = np.linspace(0., self.Tf, self.Nt)
            self.data_arrayE = np.sin(self.time_array * self.freq * 2 * np.pi +
                                      self.phase_disp)
            self.data_arrayB = np.sin(self.time_array * self.freq * 2 * np.pi -
                                      np.pi / 2 + self.phase_disp)

            ### Create overlapped lattice elements to have E and B in the same region
            self.ie, self.egrid = picmi.warp.addnewegrd(self.zs,
                                                        self.ze,
                                                        dx=self.d,
                                                        dy=self.d,
                                                        xs=self.xs,
                                                        ys=self.ys,
                                                        time=self.time_array,
                                                        data=self.data_arrayE,
                                                        ex=self.Ex3d,
                                                        ey=self.Ey3d,
                                                        ez=self.Ez3d)

            picmi.warp.addnewbgrd(self.zs,
                                  self.ze,
                                  dx=self.d,
                                  dy=self.d,
                                  xs=self.xs,
                                  ys=self.ys,
                                  time=self.time_array,
                                  data=self.data_arrayB,
                                  bx=self.Bx3d,
                                  by=self.By3d,
                                  bz=self.Bz3d)

        def time_prof(t):
            val = 0
            for i in range(0, n_bunches):
                val += bunch_macro_particles * 1. / np.sqrt(
                    2 * np.pi * sigmat * sigmat) * np.exp(
                        -(t - i * b_spac - t_offs) *
                        (t - i * b_spac - t_offs) /
                        (2 * sigmat * sigmat)) * picmi.warp.top.dt
            return val

        def nonlinearsource():
            NP = int(round(time_prof(top.time)))
            x = random.normal(bunch_centroid_position[0], bunch_rms_size[0],
                              NP)
            y = random.normal(bunch_centroid_position[1], bunch_rms_size[1],
                              NP)
            z = bunch_centroid_position[2]
            vx = random.normal(bunch_centroid_velocity[0],
                               bunch_rms_velocity[0], NP)
            vy = random.normal(bunch_centroid_velocity[1],
                               bunch_rms_velocity[1], NP)
            vz = picmi.warp.clight * np.sqrt(1 - 1. / (beam_gamma**2))
            self.beam.wspecies.addparticles(x=x,
                                            y=y,
                                            z=z,
                                            vx=vx,
                                            vy=vy,
                                            vz=vz,
                                            gi=1. / beam_gamma,
                                            w=bunch_w)

        picmi.warp.installuserinjection(nonlinearsource)

        ##########################
        # simulation run
        ##########################
        sim.step(1)
        solver.solver.installconductor(sim.conductors,
                                       dfill=picmi.warp.largepos)
        sim.step(1)

        pp = warp.ParticleScraper(sim.conductors,
                                  lsavecondid=1,
                                  lsaveintercept=1,
                                  lcollectlpdata=1)

        sec = Secondaries(conductors=sim.conductors,
                          l_usenew=1,
                          pyecloud_secemi_object=sey_mod,
                          pyecloud_nel_mp_ref=pyecloud_nel_mp_ref,
                          pyecloud_fact_clean=pyecloud_fact_clean,
                          pyecloud_fact_split=pyecloud_fact_split)

        sec.add(incident_species=self.elecb.wspecies,
                emitted_species=self.secelec.wspecies,
                conductor=sim.conductors)

        sec.add(incident_species=self.secelec.wspecies,
                emitted_species=self.secelec.wspecies,
                conductor=sim.conductors)

        #Subcycle(10)

        # just some shortcuts
        pw = picmi.warp
        step = pw.step

        if mysolver == 'ES':
            pw.top.dt = dt
            if flag_relativ_tracking:
                pw.top.lrelativ = pw.true
            else:
                pw.top.lrelativ = pw.false

        def myplots(l_force=0):
            if l_force or self.n_step % self.stride_imgs == 0:
                plt.close()
                (Nx, Ny, Nz) = np.shape(self.secelec.wspecies.get_density())
                fig, axs = plt.subplots(1, 2, figsize=(12, 4.5))
                fig.subplots_adjust(left=0.05,
                                    bottom=0.1,
                                    right=0.97,
                                    top=0.94,
                                    wspace=0.15)
                d = self.secelec.wspecies.get_density(
                ) + self.elecb.wspecies.get_density(
                ) + self.beam.wspecies.get_density()
                d2 = self.secelec.wspecies.get_density(
                ) + self.elecb.wspecies.get_density()
                im1 = axs[0].imshow(
                    d[:, :, int(Nz / 2)].T,
                    cmap='jet',
                    origin='lower',
                    vmin=0.2 * np.min(d2[:, :, int(Nz / 2)]),
                    vmax=0.8 * np.max(d2[:, :, int(Nz / 2)]),
                    extent=[self.xmin, self.xmax, self.ymin, self.ymax])
                axs[0].set_xlabel('x [m]')
                axs[0].set_ylabel('y [m]')
                axs[0].set_title('e- density')
                fig.colorbar(
                    im1,
                    ax=axs[0],
                )
                im2 = axs[1].imshow(
                    d[int(Nx / 2), :, :],
                    cmap='jet',
                    origin='lower',
                    vmin=0.2 * np.min(d2[int(Nx / 2), :, :]),
                    vmax=0.8 * np.max(d2[int(Nx / 2), :, :]),
                    extent=[self.zmin, self.zmax, self.ymin, self.ymax],
                    aspect='auto')
                axs[1].set_xlabel('z [m]')
                axs[1].set_ylabel('y [m]')
                axs[1].set_title('e- density')
                fig.colorbar(im2, ax=axs[1])
                n_step = top.time / top.dt
                figname = 'images/%d.png' % n_step
                plt.savefig(figname)

        if flag_save_video:
            pw.installafterstep(myplots)
            myplots(1)

        self.ntsteps_p_bunch = b_spac / top.dt
        self.tot_nsteps = int(np.ceil(b_spac * (n_bunches) / top.dt))
        t_start = self.b_pass_prev * b_spac
        tstep_start = int(round(t_start / top.dt))

        # pre-allocate outputs
        if self.flag_output and not (self.flag_checkpointing
                                     and os.path.exists('temp_mps_info.mat')):
            self.numelecs = np.zeros(self.tot_nsteps)
            self.numelecs_tot = np.zeros(self.tot_nsteps)
            self.N_mp = np.zeros(self.tot_nsteps)
            self.xhist = np.zeros((n_bunches, nbins))

        dict_out = {}

        # aux variables
        self.b_pass = 0
        self.perc = 10
        self.t0 = time.time()

        # trapping warp std output
        self.text_trap = {True: StringIO(), False: sys.stdout}[enable_trap]
        self.original = sys.stdout
        self.n_step = 0
コード例 #6
0
ファイル: LHC_bug.py プロジェクト: lgiacome/warp_crab
    lower_boundary_conditions = ['dirichlet', 'dirichlet', 'dirichlet']
    upper_boundary_conditions = ['dirichlet', 'dirichlet', 'dirichlet']
if mysolver == 'EM':
    lower_boundary_conditions = ['open', 'open', 'open']
    upper_boundary_conditions = ['open', 'open', 'open']

grid = picmi.Cartesian3DGrid(
    number_of_cells=[nx, ny, nz],
    lower_bound=[xmin, ymin, zmin],
    upper_bound=[xmax, ymax, zmax],
    lower_boundary_conditions=lower_boundary_conditions,
    upper_boundary_conditions=upper_boundary_conditions)  #,
#warpx_max_grid_size=32)

if mysolver == 'ES':
    solver = picmi.ElectrostaticSolver(grid=grid)

if mysolver == 'EM':
    smoother = picmi.BinomialSmoother(n_pass=[[1], [1], [1]],
                                      compensation=[[False], [False], [False]],
                                      stride=[[1], [1], [1]],
                                      alpha=[[0.5], [0.5], [0.5]])

    solver = picmi.ElectromagneticSolver(
        grid=grid,
        method='CKC',
        cfl=1.,
        source_smoother=smoother,
        #                                     field_smoother = smoother,
        warp_l_correct_num_Cherenkov=False,
        warp_type_rz_depose=0,
コード例 #7
0
def warp_pyecloud_dipole(z_length=None,
                         nx=None,
                         ny=None,
                         nz=None,
                         dh_t=None,
                         n_bunches=None,
                         b_spac=None,
                         beam_gamma=None,
                         sigmax=None,
                         sigmay=None,
                         sigmat=None,
                         bunch_intensity=None,
                         init_num_elecs=None,
                         init_num_elecs_mp=None,
                         By=None,
                         pyecloud_nel_mp_ref=None,
                         dt=None,
                         pyecloud_fact_clean=None,
                         pyecloud_fact_split=None,
                         chamber_type=None,
                         flag_save_video=None,
                         enable_trap=True,
                         Emax=None,
                         del_max=None,
                         R0=None,
                         E_th=None,
                         sigmafit=None,
                         mufit=None,
                         secondary_angle_distribution=None,
                         N_mp_max=None,
                         N_mp_target=None,
                         flag_checkpointing=False,
                         checkpoints=None,
                         flag_output=False,
                         bunch_macro_particles=None,
                         t_offs=None,
                         width=None,
                         height=None,
                         output_name='output.mat',
                         flag_relativ_tracking=False,
                         nbins=100,
                         r=None):

    import numpy as np
    import numpy.random as random
    from warp import picmi
    from scipy.stats import gaussian_kde
    from warp.particles.Secondaries import Secondaries, top, warp, time
    import matplotlib.pyplot as plt
    import scipy.io as sio
    from io import BytesIO as StringIO
    from scipy.constants import c as clight
    import sys
    import PyECLOUD.myfilemanager as mfm
    import os
    # Construct PyECLOUD secondary emission object
    import PyECLOUD.sec_emission_model_ECLOUD as seec
    sey_mod = seec.SEY_model_ECLOUD(Emax=Emax,
                                    del_max=del_max,
                                    R0=R0,
                                    E_th=E_th,
                                    sigmafit=sigmafit,
                                    mufit=mufit,
                                    secondary_angle_distribution='cosine_3D')

    ##########################
    # physics parameters
    ##########################

    mysolver = 'ES'  # solver type ('ES'=electrostatic; 'EM'=electromagnetic)

    ##########################
    # numerics parameters
    ##########################

    # --- grid

    zs_dipo = -0.5 * z_length
    ze_dipo = 0.5 * z_length

    # Consistency check
    if chamber_type == 'rect':
        assert (height is not None) and (
            width is not None
        ), 'When using rectangular chamber, height and width must be specified'
    if chamber_type == 'circle':
        assert r is not None, 'When using circular chamber r must be specified'
    if chamber_type == 'LHC':
        h = 18.e-3

    l = z_length

    unit = 1e-3
    ghost = 1e-3

    if chamber_type == 'rect':
        xmin = -width / 2. - ghost
        xmax = -xmin
        ymin = -height / 2 - ghost
        ymax = -ymin

        lower_bound = [-width / 2, -height / 2, zs_dipo]
        upper_bound = [width / 2, height / 2, ze_dipo]
    else:
        xmin = -r - ghost
        xmax = r + ghost
        ymin = -r - ghost
        ymax = r + ghost

        lower_bound = [-r, -r, zs_dipo]
        upper_bound = [r, r, ze_dipo]

    zmin = zs_dipo - 50 * unit
    zmax = ze_dipo + 50 * unit

    if chamber_type == 'LHC':
        chamber_area = 0.0014664200235342726
    elif chamber_type == 'rect':
        chamber_area = width * height
    elif chamber_type == 'circle':
        chamber_area = np.pi * r * r

    init_dist_area = (upper_bound[0] - lower_bound[0]) * (upper_bound[1] -
                                                          lower_bound[1])
    ##########################
    # Beam parameters
    ##########################
    sigmaz = sigmat * picmi.clight
    bunch_w = bunch_intensity / bunch_macro_particles
    print('DEBUG: bunch_w: %d' % bunch_w)
    print('DEBUG: bunch_intensity: %d' % bunch_intensity)
    print('DEBUG: bunch_macro_particles: %d' % bunch_macro_particles)

    #######################################################
    # compute beam size from normalized emittance and beta
    # Uncomment if data available
    #######################################################
    bunch_rms_size = [sigmax, sigmay, sigmaz]
    bunch_rms_velocity = [0., 0., 0.]
    bunch_centroid_position = [0, 0, zs_dipo - 10 * unit]
    bunch_centroid_velocity = [0., 0., beam_gamma * picmi.constants.c]

    beam = picmi.Species(particle_type='proton',
                         particle_shape='linear',
                         name='beam')
    temp_file_name = 'temp_mps_info.mat'

    ########################################################
    # if checkopoint is found reload it,
    # otherwise start from scratch
    ########################################################
    if flag_checkpointing and os.path.exists(temp_file_name):
        print('############################################################')
        print('Temp distribution found. Regenarating and restarting')
        print('############################################################')
        dict_init_dist = sio.loadmat(temp_file_name)
        # Load particles status
        x0 = dict_init_dist['x_mp'][0]
        y0 = dict_init_dist['y_mp'][0]
        z0 = dict_init_dist['z_mp'][0]
        ux0 = dict_init_dist['ux_mp'][0]
        uy0 = dict_init_dist['uy_mp'][0]
        uz0 = dict_init_dist['uz_mp'][0]
        w0 = dict_init_dist['w_mp'][0]
        # compute the velocities
        invgamma = np.sqrt(1 - picmi.clight**2 /
                           (np.square(ux0) + np.square(uy0) + np.square(uz0)))
        vx0 = np.multiply(invgamma, ux0)
        vy0 = np.multiply(invgamma, uy0)
        vz0 = np.multiply(invgamma, uy0)
        # Reload the outputs and other auxiliary stuff
        if flag_output:
            numelecs = dict_init_dist['numelecs'][0]
            N_mp = dict_init_dist['N_mp'][0]
            numelecs_tot = dict_init_dist['numelecs_tot'][0]
            xhist = dict_init_dist['xhist'][0]
            bins = dict_init_dist['bins'][0]
            b_pass_prev = dict_init_dist['b_pass'] - 1
    else:
        x0 = random.uniform(lower_bound[0], upper_bound[0], init_num_elecs_mp)
        y0 = random.uniform(lower_bound[1], upper_bound[1], init_num_elecs_mp)
        z0 = random.uniform(lower_bound[2], upper_bound[2], init_num_elecs_mp)
        vx0 = np.zeros(init_num_elecs_mp)
        vy0 = np.zeros(init_num_elecs_mp)
        vz0 = np.zeros(init_num_elecs_mp)
        w0 = float(init_num_elecs) / float(init_num_elecs_mp)
        #Correct the weight to the chambers size
        w0 = w0 * init_dist_area / chamber_area
        b_pass_prev = 0

    electron_background_dist = picmi.ParticleListDistribution(x=x0,
                                                              y=y0,
                                                              z=z0,
                                                              vx=vx0,
                                                              vy=vy0,
                                                              vz=vz0,
                                                              weight=w0)

    elecb = picmi.Species(particle_type='electron',
                          particle_shape='linear',
                          name='Electron background',
                          initial_distribution=electron_background_dist)

    secelec = picmi.Species(particle_type='electron',
                            particle_shape='linear',
                            name='Secondary electrons')

    ##########################
    # Numeric components
    ##########################

    if mysolver == 'ES':
        lower_boundary_conditions = ['dirichlet', 'dirichlet', 'dirichlet']
        upper_boundary_conditions = ['dirichlet', 'dirichlet', 'dirichlet']
    if mysolver == 'EM':
        lower_boundary_conditions = ['open', 'open', 'open']
        upper_boundary_conditions = ['open', 'open', 'open']

    grid = picmi.Cartesian3DGrid(
        number_of_cells=[nx, ny, nz],
        lower_bound=[xmin, ymin, zmin],
        upper_bound=[xmax, ymax, zmax],
        lower_boundary_conditions=lower_boundary_conditions,
        upper_boundary_conditions=upper_boundary_conditions)

    if mysolver == 'ES':
        solver = picmi.ElectrostaticSolver(grid=grid)

    if mysolver == 'EM':
        smoother = picmi.BinomialSmoother(n_pass=[[1], [1], [1]],
                                          compensation=[[False], [False],
                                                        [False]],
                                          stride=[[1], [1], [1]],
                                          alpha=[[0.5], [0.5], [0.5]])
        solver = picmi.ElectromagneticSolver(
            grid=grid,
            method='CKC',
            cfl=1.,
            source_smoother=smoother,
            warp_l_correct_num_Cherenkov=False,
            warp_type_rz_depose=0,
            warp_l_setcowancoefs=True,
            warp_l_getrho=False)

    ##########################
    # Simulation setup
    ##########################

    if chamber_type == 'rect':
        print 'Using rectangular chamber with xaper: %1.2e, yaper: %1.2e' % (
            width / 2., height / 2.)
        upper_box = picmi.warp.YPlane(y0=height / 2., ysign=1, condid=1)
        lower_box = picmi.warp.YPlane(y0=-height / 2., ysign=-1, condid=1)
        left_box = picmi.warp.XPlane(x0=width / 2., xsign=1, condid=1)
        right_box = picmi.warp.XPlane(x0=-width / 2., xsign=-1, condid=1)

        sim = picmi.Simulation(solver=solver,
                               verbose=1,
                               cfl=1.0,
                               warp_initialize_solver_after_generate=1)

        sim.conductors = upper_box + lower_box + left_box + right_box

    elif chamber_type == 'LHC':
        print 'Using the LHC chamber'
        pipe_annulus = picmi.warp.ZAnnulus(rmin=r,
                                           rmax=r + ghost / 2,
                                           length=l,
                                           condid=1)
        upper_box = picmi.warp.YPlane(y0=h, ysign=1, condid=1)
        lower_box = picmi.warp.YPlane(y0=-h, ysign=-1, condid=1)
        pipe = picmi.warp.ZCylinderOut(radius=r, length=l, condid=1)

        sim = picmi.Simulation(solver=solver,
                               verbose=1,
                               cfl=1.0,
                               warp_initialize_solver_after_generate=1)

        sim.conductors = pipe + upper_box + lower_box

    elif chamber_type == 'circle':
        print 'Using a circular chamber with radius %d' % r
        pipe_annulus = picmi.warp.ZAnnulus(rmin=r,
                                           rmax=r + ghost,
                                           length=l,
                                           voltage=0.,
                                           xcent=0.,
                                           ycent=0.,
                                           zcent=0.,
                                           condid=1)
        pipe = picmi.warp.ZCylinderOut(radius=r, length=l, condid=1)

        sim = picmi.Simulation(solver=solver,
                               verbose=1,
                               cfl=1.0,
                               warp_initialize_solver_after_generate=1)

        sim.conductors = pipe

    beam_layout = picmi.PseudoRandomLayout(n_macroparticles=10**5, seed=3)

    sim.add_species(beam, layout=None, initialize_self_field=solver == 'EM')

    elecb_layout = picmi.PseudoRandomLayout(n_macroparticles=init_num_elecs_mp,
                                            seed=3)

    sim.add_species(elecb,
                    layout=elecb_layout,
                    initialize_self_field=solver == 'EM')
    sim.add_species(secelec, layout=None, initialize_self_field=False)
    #########################
    # Add Dipole
    #########################
    picmi.warp.addnewdipo(zs=zs_dipo, ze=ze_dipo, by=By)

    def time_prof(t):
        val = 0
        for i in range(0, n_bunches):
            val += bunch_macro_particles * 1. / np.sqrt(
                2 * np.pi * sigmat * sigmat) * np.exp(
                    -(t - i * b_spac - t_offs) * (t - i * b_spac - t_offs) /
                    (2 * sigmat * sigmat)) * picmi.warp.top.dt
        return val

    def nonlinearsource():
        NP = int(round(time_prof(top.time)))
        x = random.normal(bunch_centroid_position[0], bunch_rms_size[0], NP)
        y = random.normal(bunch_centroid_position[1], bunch_rms_size[1], NP)
        z = bunch_centroid_position[2]
        vx = random.normal(bunch_centroid_velocity[0], bunch_rms_velocity[0],
                           NP)
        vy = random.normal(bunch_centroid_velocity[1], bunch_rms_velocity[1],
                           NP)
        vz = picmi.warp.clight * np.sqrt(1 - 1. / (beam_gamma**2))
        beam.wspecies.addparticles(x=x,
                                   y=y,
                                   z=z,
                                   vx=vx,
                                   vy=vy,
                                   vz=vz,
                                   gi=1. / beam_gamma,
                                   w=bunch_w)

    picmi.warp.installuserinjection(nonlinearsource)

    ##########################
    # simulation run
    ##########################
    sim.step(1)
    solver.solver.installconductor(sim.conductors, dfill=picmi.warp.largepos)
    sim.step(1)

    pp = warp.ParticleScraper(sim.conductors,
                              lsavecondid=1,
                              lsaveintercept=1,
                              lcollectlpdata=1)

    sec = Secondaries(conductors=sim.conductors,
                      l_usenew=1,
                      pyecloud_secemi_object=sey_mod,
                      pyecloud_nel_mp_ref=pyecloud_nel_mp_ref,
                      pyecloud_fact_clean=pyecloud_fact_clean,
                      pyecloud_fact_split=pyecloud_fact_split)

    sec.add(incident_species=elecb.wspecies,
            emitted_species=secelec.wspecies,
            conductor=sim.conductors)

    sec.add(incident_species=secelec.wspecies,
            emitted_species=secelec.wspecies,
            conductor=sim.conductors)

    #Subcycle(10)

    # just some shortcuts
    pw = picmi.warp
    step = pw.step

    if mysolver == 'ES':
        pw.top.dt = dt
        if flag_relativ_tracking:
            pw.top.lrelativ = pw.true
        else:
            pw.top.lrelativ = pw.false

    def myplots(l_force=0):
        if l_force or pw.top.it % 10 == 0:
            plt.close()
            (Nx, Ny, Nz) = np.shape(secelec.wspecies.get_density())
            fig, axs = plt.subplots(1, 2, figsize=(12, 4.5))
            fig.subplots_adjust(left=0.05,
                                bottom=0.1,
                                right=0.97,
                                top=0.94,
                                wspace=0.15)
            d = secelec.wspecies.get_density() + elecb.wspecies.get_density(
            ) + beam.wspecies.get_density()
            d2 = secelec.wspecies.get_density() + elecb.wspecies.get_density()
            im1 = axs[0].imshow(d2[:, :, Nz / 2].T,
                                cmap='jet',
                                origin='lower',
                                vmin=0.2 * np.min(d2[:, :, Nz / 2]),
                                vmax=0.8 * np.max(d2[:, :, Nz / 2]),
                                extent=[xmin, xmax, ymin, ymax])
            axs[0].set_xlabel('x [m]')
            axs[0].set_ylabel('y [m]')
            axs[0].set_title('e- density')
            fig.colorbar(
                im1,
                ax=axs[0],
            )
            im2 = axs[1].imshow(d2[Nx / 2, :, :],
                                cmap='jet',
                                origin='lower',
                                vmin=0.2 * np.min(d2[Nx / 2, :, :]),
                                vmax=0.8 * np.max(d2[Nx / 2, :, :]),
                                extent=[zmin, zmax, ymin, ymax],
                                aspect='auto')
            axs[1].set_xlabel('z [m]')
            axs[1].set_ylabel('y [m]')
            axs[1].set_title('e- density')
            fig.colorbar(im2, ax=axs[1])
            n_step = top.time / top.dt
            figname = 'images/%d.png' % n_step
            plt.savefig(figname)

    if flag_save_video:
        pw.installafterstep(myplots)
        myplots(1)

    ntsteps_p_bunch = b_spac / top.dt
    tot_nsteps = int(np.ceil(b_spac * (n_bunches) / top.dt))
    t_start = b_pass_prev * b_spac
    tstep_start = int(round(t_start / top.dt))

    # pre-allocate outputs
    if flag_output and not (flag_checkpointing
                            and os.path.exists('temp_mps_info.mat')):
        numelecs = np.zeros(tot_nsteps)
        numelecs_tot = np.zeros(tot_nsteps)
        N_mp = np.zeros(tot_nsteps)
        xhist = np.zeros((n_bunches, nbins))

    dict_out = {}

    # aux variables
    b_pass = 0
    perc = 10
    original = sys.stdout
    text_trap = StringIO()
    t0 = time.time()

    # trapping warp std output
    text_trap = {True: StringIO(), False: sys.stdout}[enable_trap]
    original = sys.stdout

    for n_step in range(tstep_start, tot_nsteps):
        # if a passage is starting...
        if n_step / ntsteps_p_bunch >= b_pass + b_pass_prev:
            b_pass += 1
            perc = 10
            # Measure the duration of the previous passage
            if b_pass > 1:
                t_pass_1 = time.time()
                t_pass = t_pass_1 - t_pass_0
            t_pass_0 = time.time()
            # Dump outputs
            if flag_output:
                dict_out['numelecs'] = numelecs
                dict_out['numelecs_tot'] = numelecs_tot
                dict_out['N_mp'] = N_mp
                # Compute the x-position histogram
                (xhist[b_pass - 1],
                 bins) = np.histogram(secelec.wspecies.getx(),
                                      range=(xmin, xmax),
                                      bins=nbins,
                                      weights=secelec.wspecies.getw(),
                                      density=False)
                dict_out['bins'] = bins
                dict_out['xhist'] = xhist
                sio.savemat(output_name, dict_out)
            # Perform regeneration if needed
            if secelec.wspecies.getn() > N_mp_max:
                dict_out_temp = {}
                print('Number of macroparticles: %d' %
                      (secelec.wspecies.getn()))
                print('MAXIMUM LIMIT OF MPS HAS BEEN RACHED')

                perform_regeneration(N_mp_target, secelec.wspecies, sec)

                # Save stuff if checkpoint
                if flag_checkpointing and np.any(checkpoints == b_pass +
                                                 b_pass_prev) and b_pass > 1:
                    dict_out_temp = {}
                    print('Saving a checkpoint!')
                    secelec_w = secelec.wspecies.getw()
                    dict_out_temp['x_mp'] = np.concatenate(
                        (secelec.wspecies.getx(), elecb.wspecies.getx()))
                    dict_out_temp['y_mp'] = np.concatenate(
                        (secelec.wspecies.gety(), elecb.wspecies.gety()))
                    dict_out_temp['z_mp'] = np.concatenate(
                        (secelec.wspecies.getz(), elecb.wspecies.gety()))
                    dict_out_temp['ux_mp'] = np.concatenate(
                        (secelec.wspecies.getux(), elecb.wspecies.getux()))
                    dict_out_temp['uy_mp'] = np.concatenate(
                        (secelec.wspecies.getuy(), elecb.wspecies.getuy()))
                    dict_out_temp['uz_mp'] = np.concatenate(
                        (secelec.wspecies.getuz(), elecb.wspecies.getuz()))
                    dict_out_temp['w_mp'] = np.concatenate(
                        (secelec_w, elecb.wspecies.getw()))
                    if flag_output:
                        dict_out_temp['numelecs'] = numelecs
                        dict_out_temp['numelecs_tot'] = numelecs_tot
                        dict_out_temp['N_mp'] = N_mp
                        dict_out_temp['xhist'] = xhist
                        dict_out_temp['bins'] = bins

                    dict_out_temp['b_pass'] = b_pass + b_pass_prev

                    filename = 'temp_mps_info.mat'

                    sio.savemat(filename, dict_out_temp)

            print('===========================')
            print('Bunch passage: %d' % (b_pass + b_pass_prev))
            print('Number of electrons in the dipole: %d' %
                  (np.sum(secelec.wspecies.getw()) +
                   np.sum(elecb.wspecies.getw())))
            print('Number of macroparticles: %d' %
                  (secelec.wspecies.getn() + elecb.wspecies.getn()))
            if b_pass > 1:
                print('Previous passage took %ds' % t_pass)
        if n_step % ntsteps_p_bunch / ntsteps_p_bunch * 100 > perc:
            print('%d%% of bunch passage' % perc)
            perc = perc + 10

        # Perform a step
        sys.stdout = text_trap
        step(1)
        sys.stdout = original
        #if secelec.wspecies.getn()>0 and elecb.wspecies.getn()>0:
        #    print(max(max(np.sqrt(np.square(elecb.wspecies.getvx())+np.square(elecb.wspecies.getvy())+np.square(elecb.wspecies.getvz()))), max(np.sqrt(np.square(secelec.wspecies.getvx())+np.square(secelec.wspecies.getvy())+np.square(secelec.wspecies.getvz())))))
        # Store stuff to be saved
        if flag_output:
            secelec_w = secelec.wspecies.getw()
            elecb_w = elecb.wspecies.getw()
            elecs_density = secelec.wspecies.get_density(
                l_dividebyvolume=0)[:, :,
                                    int(nz / 2.)] + elecb.wspecies.get_density(
                                        l_dividebyvolume=0)[:, :,
                                                            int(nz / 2.)]
            numelecs[n_step] = np.sum(elecs_density)
            elecs_density_tot = secelec.wspecies.get_density(
                l_dividebyvolume=0)[:, :, :] + elecb.wspecies.get_density(
                    l_dividebyvolume=0)[:, :, :]
            numelecs_tot[n_step] = np.sum(elecs_density_tot)
            N_mp[n_step] = len(secelec_w) + len(elecb_w)

    # Timer
    t1 = time.time()
    totalt = t1 - t0
    # Dump outputs
    if flag_output:
        dict_out['numelecs'] = numelecs
        dict_out['N_mp'] = N_mp
        dict_out['numelecs_tot'] = numelecs_tot
        dict_out['xhist'] = xhist
        dict_out['bins'] = bins
        sio.savemat(output_name, dict_out)

    # Delete checkpoint if found
    if flag_checkpointing and os.path.exists('temp_mps_info.mat'):
        os.remove('temp_mps_info.mat')

    print('Run terminated in %ds' % totalt)
コード例 #8
0
    def __init__(self,
                 z_length=None,
                 nx=None,
                 ny=None,
                 nz=None,
                 solver_type='ES',
                 n_bunches=None,
                 b_spac=None,
                 beam_gamma=None,
                 sigmax=None,
                 sigmay=None,
                 sigmat=None,
                 bunch_intensity=None,
                 init_num_elecs=None,
                 init_num_elecs_mp=None,
                 By=None,
                 N_subcycle=None,
                 pyecloud_nel_mp_ref=None,
                 dt=None,
                 pyecloud_fact_clean=None,
                 pyecloud_fact_split=None,
                 chamber_type=None,
                 flag_save_video=None,
                 enable_trap=True,
                 Emax=None,
                 del_max=None,
                 R0=None,
                 E_th=None,
                 sigmafit=None,
                 mufit=None,
                 secondary_angle_distribution=None,
                 N_mp_max=None,
                 N_mp_target=None,
                 flag_checkpointing=False,
                 checkpoints=None,
                 flag_output=False,
                 bunch_macro_particles=None,
                 t_offs=None,
                 width=None,
                 height=None,
                 output_filename='output.mat',
                 flag_relativ_tracking=False,
                 nbins=100,
                 radius=None,
                 ghost=None,
                 ghost_z=None,
                 stride_imgs=10,
                 stride_output=1000,
                 chamber=False,
                 lattice_elem=None,
                 temps_filename='temp_mps_info.mat',
                 custom_plot=None):

        # Construct PyECLOUD secondary emission object
        sey_mod = seec.SEY_model_ECLOUD(
            Emax=Emax,
            del_max=del_max,
            R0=R0,
            E_th=E_th,
            sigmafit=sigmafit,
            mufit=mufit,
            secondary_angle_distribution='cosine_3D')

        self.nbins = nbins
        self.N_mp_target = N_mp_target
        self.N_mp_max = N_mp_max
        self.nx = nx
        self.ny = ny
        self.nz = nz
        self.flag_checkpointing = flag_checkpointing
        self.checkpoints = checkpoints
        self.flag_output = flag_output
        self.output_filename = output_filename
        self.stride_imgs = stride_imgs
        self.stride_output = stride_output
        self.beam_gamma = beam_gamma
        self.chamber = chamber
        self.init_num_elecs_mp = init_num_elecs_mp
        self.init_num_elecs = init_num_elecs
        self.n_bunches = n_bunches
        self.bunch_macro_particles = bunch_macro_particles
        self.sigmat = sigmat
        self.b_spac = b_spac
        self.t_offs = t_offs
        self.temps_filename = temps_filename
        # Just some shortcuts
        pw = picmi.warp
        step = pw.step

        if solver_type == 'ES':
            pw.top.dt = dt
            if flag_relativ_tracking:
                pw.top.lrelativ = pw.true
            else:
                pw.top.lrelativ = pw.false

        self.tot_nsteps = int(np.ceil(b_spac * (n_bunches) / top.dt))

        self.saver = Saver(flag_output,
                           flag_checkpointing,
                           self.tot_nsteps,
                           n_bunches,
                           nbins,
                           temps_filename=temps_filename,
                           output_filename=output_filename)

        # Beam parameters
        sigmaz = sigmat * picmi.clight
        if bunch_macro_particles > 0:
            self.bunch_w = bunch_intensity / bunch_macro_particles
        else:
            self.bunch_w = 0

        self.bunch_rms_size = [sigmax, sigmay, sigmaz]
        self.bunch_rms_velocity = [0., 0., 0.]
        self.bunch_centroid_position = [0, 0, chamber.zmin + 10e-3]
        self.bunch_centroid_velocity = [0., 0., beam_gamma * picmi.constants.c]

        # Instantiate beam
        self.beam = picmi.Species(particle_type='proton',
                                  particle_shape='linear',
                                  name='beam')

        # If checkopoint is found reload it,
        # otherwise start with uniform distribution
        self.temp_file_name = 'temp_mps_info.mat'
        if self.flag_checkpointing and os.path.exists(self.temp_file_name):
            electron_background_dist = self.load_elec_density()
        else:
            electron_background_dist = self.init_uniform_density()

        self.elecb = picmi.Species(
            particle_type='electron',
            particle_shape='linear',
            name='Electron background',
            initial_distribution=electron_background_dist)

        self.secelec = picmi.Species(particle_type='electron',
                                     particle_shape='linear',
                                     name='Secondary electrons')

        # Setup grid and boundary conditions
        if solver_type == 'ES':
            lower_bc = ['dirichlet', 'dirichlet', 'dirichlet']
            upper_bc = ['dirichlet', 'dirichlet', 'dirichlet']
        if solver_type == 'EM':
            lower_boundary_conditions = ['open', 'open', 'open']
            upper_boundary_conditions = ['open', 'open', 'open']

        grid = picmi.Cartesian3DGrid(
            number_of_cells=[self.nx, self.ny, self.nz],
            lower_bound=[chamber.xmin, chamber.ymin, chamber.zmin],
            upper_bound=[chamber.xmax, chamber.ymax, chamber.zmax],
            lower_boundary_conditions=lower_bc,
            upper_boundary_conditions=upper_bc)

        if solver_type == 'ES':
            solver = picmi.ElectrostaticSolver(grid=grid)
        elif solver_type == 'EM':
            smoother = picmi.BinomialSmoother(n_pass=[[1], [1], [1]],
                                              compensation=[[False], [False],
                                                            [False]],
                                              stride=[[1], [1], [1]],
                                              alpha=[[0.5], [0.5], [0.5]])
            solver = picmi.ElectromagneticSolver(
                grid=grid,
                method='CKC',
                cfl=1.,
                source_smoother=smoother,
                warp_l_correct_num_Cherenkov=False,
                warp_type_rz_depose=0,
                warp_l_setcowancoefs=True,
                warp_l_getrho=False)

        # Setup simulation
        sim = picmi.Simulation(solver=solver,
                               verbose=1,
                               cfl=1.0,
                               warp_initialize_solver_after_generate=1)

        sim.conductors = chamber.conductors

        sim.add_species(self.beam,
                        layout=None,
                        initialize_self_field=solver == 'EM')

        self.elecb_layout = picmi.PseudoRandomLayout(
            n_macroparticles=init_num_elecs_mp, seed=3)

        sim.add_species(self.elecb,
                        layout=self.elecb_layout,
                        initialize_self_field=solver == 'EM')

        sim.add_species(self.secelec, layout=None, initialize_self_field=False)

        picmi.warp.installuserinjection(self.bunched_beam)

        sim.step(1)
        solver.solver.installconductor(sim.conductors,
                                       dfill=picmi.warp.largepos)
        sim.step(1)

        # Setup secondary emission stuff
        pp = warp.ParticleScraper(sim.conductors,
                                  lsavecondid=1,
                                  lsaveintercept=1,
                                  lcollectlpdata=1)

        sec = Secondaries(conductors=sim.conductors,
                          l_usenew=1,
                          pyecloud_secemi_object=sey_mod,
                          pyecloud_nel_mp_ref=pyecloud_nel_mp_ref,
                          pyecloud_fact_clean=pyecloud_fact_clean,
                          pyecloud_fact_split=pyecloud_fact_split)

        sec.add(incident_species=self.elecb.wspecies,
                emitted_species=self.secelec.wspecies,
                conductor=sim.conductors)

        sec.add(incident_species=self.secelec.wspecies,
                emitted_species=self.secelec.wspecies,
                conductor=sim.conductors)

        if N_subcycle is not None:
            Subcycle(N_subcycle)

        if custom_plot is not None:
            plot_func = custom_plot
        else:
            plot_func = self.myplots

        pw.installafterstep(plot_func)
        plot_func(1)

        self.ntsteps_p_bunch = b_spac / top.dt
        t_start = self.b_pass_prev * b_spac
        tstep_start = int(np.round(t_start / top.dt))

        # aux variables
        self.b_pass = 0
        self.perc = 10
        self.t0 = time.time()

        # trapping warp std output
        self.text_trap = {True: StringIO(), False: sys.stdout}[enable_trap]
        self.original = sys.stdout

        self.n_step = int(np.round(self.b_pass_prev * b_spac / dt))
コード例 #9
0
    def __init__(self, fieldsolver_inputs=None,
                 beam_inputs=None, ecloud_inputs=None,
                 antenna_inputs=None,
                 saving_inputs=None,
                 simulation_inputs=None):

        self.defaultsfromdict(self.__fieldsolver_inputs__, fieldsolver_inputs)
        self.defaultsfromdict(self.__beam_inputs__, beam_inputs)
        self.defaultsfromdict(self.__ecloud_inputs__, ecloud_inputs)
        self.defaultsfromdict(self.__antenna_inputs__, antenna_inputs)
        self.defaultsfromdict(self.__saving_inputs__, saving_inputs)
        self.defaultsfromdict(self.__simulation_inputs__, simulation_inputs)

        # Construct PyECLOUD secondary emission object
        self.sey_mod = seec.SEY_model_ECLOUD(Emax=self.Emax,
                                             del_max=self.del_max,
                                             R0=self.R0, E_th=self.E_th,
                                             sigmafit=self.sigmafit,
                                             mufit=self.mufit,
                                             secondary_angle_distribution='cosine_3D')

        self.beam_beta = np.sqrt(1 - 1 / (self.beam_gamma ** 2))

        if self.n_bunches is not None and self.tot_nsteps is not None:
            print("""WARNING: if both n_bunches and tot_nsteps are specified 
                   tot_nsteps is going to be ignored and the number of steps is 
                   going to be determined basing on n_bunches and dt""")

        if self.n_bunches is not None and self.t_end is not None:
            print("""WARNING: if both n_bunches and t_end are specified
                   tot_nsteps is going to be ignored and the number of steps is
                   going to be determined basing on n_bunches and dt""")

        if not os.path.exists(self.images_dir) and picmi.warp.me == 0:
            os.makedirs(self.images_dir)

        # Just some shortcuts
        pw = picmi.warp

        if self.custom_time_prof is None:
            self.time_prof = self.gaussian_time_prof
        else:
            self.time_prof = self.self_wrapped_custom_time_prof

        if self.solver_type == 'EM':
            if self.dt is not None:
                print('WARNING: dt is going to be ignored for the EM solver')
        else:
            pw.top.dt = self.dt

        if self.flag_relativ_tracking:
            pw.top.lrelativ = pw.true
        else:
            pw.top.lrelativ = pw.false

        # Beam parameters
        self.sigmaz = self.sigmat * picmi.clight
        if self.bunch_macro_particles > 0:
            self.bunch_w = self.bunch_intensity / self.bunch_macro_particles
        else:
            self.bunch_w = 0

        self.bunch_rms_size = [self.sigmax, self.sigmay, self.sigmaz]
        self.bunch_rms_velocity = [0., 0., 0.]
        self.bunch_centroid_position = [0, 0, self.chamber.z_inj_beam]
        self.bunch_centroid_velocity = [0., 0., self.beam_beta * picmi.constants.c]

        self.species_names = ['beam', 'ecloud']

        # Instantiate beam
        self.elecs_injected = False
        if self.flag_checkpointing and os.path.exists(self.temps_filename):
            self.ecloud = picmi.Species(particle_type='electron',
                                        particle_shape='linear',
                                        name=self.species_names[1],
                                        initial_distribution=self.load_elec_density())
            self.elecs_injected = True 
        else:
            self.ecloud = picmi.Species(particle_type='electron',
                                        particle_shape='linear',
                                        name=self.species_names[1])

        self.beam = picmi.Species(particle_type='proton',
                                  particle_shape='linear',
                                  name=self.species_names[0],
                                  warp_fselfb = self.bunch_centroid_velocity[2])


        self.b_pass = 0
        # Setup grid and boundary conditions
        self.dir_bc = ['dirichlet', 'dirichlet', 'dirichlet']
        self.pml_bc = ['open', 'open', 'open']
        #self.pml_bc = ['dirichlet', 'dirichlet', 'dirichlet']

        self.number_of_cells = [self.nx, self.ny, self.nz]
        self.lower_bound = [self.chamber.xmin, self.chamber.ymin, self.chamber.zmin]
        self.upper_bound = [self.chamber.xmax, self.chamber.ymax, self.chamber.zmax]
        
        self.grid_EM = picmi.Cartesian3DGrid(number_of_cells=self.number_of_cells,
                                        lower_bound=self.lower_bound,
                                        upper_bound=self.upper_bound,
                                        lower_boundary_conditions=self.pml_bc,
                                        upper_boundary_conditions=self.pml_bc)


        grid_ES = picmi.Cartesian3DGrid(number_of_cells=self.number_of_cells,
                                        lower_bound=self.lower_bound,
                                        upper_bound=self.upper_bound,
                                        lower_boundary_conditions=self.dir_bc,
                                        upper_boundary_conditions=self.dir_bc)

        if self.solver_type == 'ES':
            self.solver = picmi.ElectrostaticSolver(grid=grid_ES,
                                                    warp_conductors = self.chamber.conductors,
                                                    warp_conductor_dfill = picmi.warp.largepos)

        elif self.solver_type == 'EM':
            if self.source_smoothing:
                n_pass = [[1], [1], [1]]
                stride = [[1], [1], [1]]
                compensation = [[False], [False], [False]]
                alpha = [[0.5], [0.5], [0.5]]
                smoother = picmi.BinomialSmoother(n_pass=n_pass,
                                                  compensation=compensation,
                                                  stride=stride,
                                                  alpha=alpha)
            else:
                smoother = None

            if hasattr(self, 'laser_func'):
                self.solver = picmi.ElectromagneticSolver(grid=self.grid_EM,
                                                      method=self.EM_method, cfl=self.cfl,
                                                      source_smoother=smoother,
                                                      warp_l_correct_num_Cherenkov=False,
                                                      warp_type_rz_depose=0,
                                                      warp_l_setcowancoefs=True,
                                                      warp_l_getrho=False,
                                                      warp_laser_func=self.laser_func,
                                                      warp_laser_source_z=self.laser_source_z,
                                                      warp_laser_polangle=self.laser_polangle,
                                                      warp_laser_emax=self.laser_emax,
                                                      warp_laser_xmin=self.laser_xmin,
                                                      warp_laser_xmax=self.laser_xmax,
                                                      warp_laser_ymin=self.laser_ymin,
                                                      warp_laser_ymax=self.laser_ymax,
                                                      warp_conductors = self.chamber.conductors,
                                                      warp_conductor_dfill = picmi.warp.largepos,
                                                      warp_deposition_species =[self.ecloud.wspecies],
                                                      warp_iselfb_list = [0]) 
            else:
                self.solver = picmi.ElectromagneticSolver(grid=self.grid_EM,
                                                      method=self.EM_method, cfl=self.cfl,
                                                      source_smoother=smoother,
                                                      warp_l_correct_num_Cherenkov=False,
                                                      warp_type_rz_depose=0,
                                                      warp_l_setcowancoefs=True,
                                                      warp_l_getrho=False,
                                                      warp_conductors = self.chamber.conductors,
                                                      warp_conductor_dfill = picmi.warp.largepos,
                                                      warp_deposition_species =[self.ecloud.wspecies],
                                                      warp_iselfb_list = [0])     


        # Setup simulation
        self.sim = picmi.Simulation(solver=self.solver, verbose=1,
                               warp_initialize_solver_after_generate=1)

        self.sim.add_species(self.beam, layout=None,
                        initialize_self_field=False)

        self.ecloud_layout = picmi.PseudoRandomLayout(
            n_macroparticles=self.init_num_elecs_mp,
            seed=3)

        #tot_cells = 2 #self.nx*self.ny*self.nz
        #self.ecloud_layout = picmi.GriddedLayout(grid=self.grid_EM,
        #    n_macroparticle_per_cell= np.array([2, 2, 2])) #np.array([int(self.init_num_elecs_mp/tot_cells), 
                                               #int(self.init_num_elecs_mp/tot_cells), 
                                               #int(self.init_num_elecs_mp/tot_cells)]))

        self.sim.add_species(self.ecloud, layout=self.ecloud_layout)
#                        initialize_self_field= self.init_ecloud_fields) 

        
        #init_field = self.solver_type=='EM'
       
        self.sim.step(1)

        if self.init_num_elecs_mp > 0 and (not self.elecs_injected):
            if self.t_inject_elec == 0:
                self.init_uniform_density()
            else:
                picmi.warp.installuserinjection(self.init_uniform_density)


        if self.tot_nsteps is None and self.n_bunches is not None:
            self.tot_nsteps = int(np.round(self.b_spac*(self.n_bunches)/top.dt))
        if self.tot_nsteps is None and self.t_end is not None:
            self.tot_nsteps = int(np.round(self.t_end / top.dt))
        # to be fixed
        if self.t_end is not None:
            self.tot_nsteps = int(np.round(self.t_end / top.dt))
        elif self.tot_nsteps is None and self.n_bunches is None:
            raise Exception('One between n_bunches, tot_nsteps, t_end has to be specified')
        
        # needed to be consistent with the conductors
        self.solver.solver.current_cor = False 

        self.flag_first_pass = True

        if self.bunch_macro_particles > 0:
            picmi.warp.installuserinjection(self.bunched_beam)     
        # Initialize the EM fields
        # if self.init_em_fields:
        #    em = self.solver.solver
        #    me = pw.me
        #  
        #    fields = dict_of_arrays_and_scalar_from_h5_serial(self.folder_em_fields+'/'+str(picmi.warp.me)+'/'+self.file_em_fields) 

        #    em.fields.Ex = fields['ex']*self.em_scale_fac
        #    em.fields.Ey = fields['ey']*self.em_scale_fac
        #    em.fields.Ez = fields['ez']*self.em_scale_fac
        #    em.fields.Bx = fields['bx']*self.em_scale_fac
        #    em.fields.By = fields['by']*self.em_scale_fac
        #    em.fields.Bz = fields['bz']*self.em_scale_fac      
        #    em.setebp()
       
        # Setup secondary emission stuff       
        self.part_scraper = ParticleScraper(self.chamber.conductors, lsavecondid=1, lsaveintercept=1, lcollectlpdata=1)

        self.sec = Secondaries(conductors=self.chamber.conductors, l_usenew=1,
                               pyecloud_secemi_object=self.sey_mod,
                               pyecloud_nel_mp_ref=self.pyecloud_nel_mp_ref,
                               pyecloud_fact_clean=self.pyecloud_fact_clean,
                               pyecloud_fact_split=self.pyecloud_fact_split)
 
        self.sec.add(incident_species=self.ecloud.wspecies,
                     emitted_species=self.ecloud.wspecies,
                     conductor=self.chamber.conductors)
        
        self.saver = Saver(self.flag_output, self.flag_checkpointing,
                           self.nbins,
                           self.solver, self.sec, temps_filename=self.temps_filename,
                           output_filename=self.output_filename,
                           probe_filename = self.probe_filename,
                           tot_nsteps = self.tot_nsteps, n_bunches = self.n_bunches,
                           flag_save_ek_impacts = self.flag_save_ek_impacts)


        self.ntsteps_p_bunch = int(np.round(self.b_spac / top.dt))
        self.n_step = int(np.round(self.b_pass * self.ntsteps_p_bunch))
        if self.N_subcycle is not None:
            Subcycle(self.N_subcycle)

        if self.custom_plot is not None:
            pw.installafterstep(self.self_wrapped_custom_plot)

        # Install field probes
        if len(self.field_probes) > 0:
            self.saver.init_field_probes(np.shape(self.field_probes)[0],
                                         self.tot_nsteps,
                                         self.field_probes_dump_stride)

            pw.installafterstep(self.self_wrapped_probe_fun)

        # Install other user-specified functions
        for fun in self.after_step_fun_list:
            pw.installafterstep(fun)

        # aux variables
        self.perc = 10
        self.t0 = time.time()

        # trapping warp std output
        self.text_trap = {True: StringIO(), False: sys.stdout}[self.enable_trap]
        self.original = sys.stdout
        self.print_solvers_info()