def main(): from simtbx.nanoBragg.sim_data import SimData import sys if "--cuda" in sys.argv: import os os.environ["DIFFBRAGG_USE_CUDA"] = "1" S = SimData(use_default_crystal=True) S.instantiate_diffBragg() S.D.nopolar = True S.D.oversample = 3 S.D.add_diffBragg_spots() S._add_background() diff_img = S.D.raw_pixels.as_numpy_array() S.D.raw_pixels *= 0 S.D.add_nanoBragg_spots() S._add_background() nano_img = S.D.raw_pixels.as_numpy_array() import numpy as np assert np.allclose(diff_img, nano_img, atol=1e-9)
def sim_spots(F): a_real = (79, 0, 0) b_real = (0, 79, 0) c_real = (0, 0, 38) C = Crystal(a_real, b_real, c_real, 'P43212') nbcryst = NBcrystal(init_defaults=True) nbcryst.dxtbx_crystal = C # simulate ground truth nbcryst.thick_mm = 0.1 nbcryst.Ncells_abc = 10, 10, 10 nbcryst.miller_array = F print("Ground truth ncells = %f" % (nbcryst.Ncells_abc[0])) # ground truth detector from simtbx.nanoBragg.sim_data import SimData DET_gt = SimData.simple_detector(150, 0.177, (600, 600)) # initialize the simulator SIM = SimData(use_default_crystal=True) SIM.detector = DET_gt SIM.crystal = nbcryst SIM.instantiate_diffBragg(oversample=0) SIM.D.default_F = 0 SIM.D.progress_meter = False SIM.D.add_diffBragg_spots() SIM.D.F000 = 0 SPOTS = SIM.D.raw_pixels.as_numpy_array() SIM.D.free_all() SIM.D.free_Fhkl2() return SPOTS
def flexBeam_sim_colors(CRYSTAL, DETECTOR, BEAM, Famp, energies, fluxes, pids=None, cuda=False, oversample=0, Ncells_abc=(50, 50, 50), mos_dom=1, mos_spread=0, beamsize_mm=0.001, device_Id=0, omp=False, show_params=False, crystal_size_mm=0.01, printout_pix=None, time_panels=True, verbose=0, default_F=0, interpolate=0, recenter=True, profile="gauss", spot_scale_override=None, background_raw_pixels=None, include_noise=False, add_water=False, add_air=False, water_path_mm=0.005, air_path_mm=0, rois_perpanel=None, adc_offset=0, readout_noise=3, psf_fwhm=0, gain=1, mosaicity_random_seeds=None): """ :param CRYSTAL: dxtbx Crystal model :param DETECTOR: dxtbx detector model :param BEAM: dxtbx beam model :param Famp: cctbx miller array (amplitudes) :param energies: list of energies to simulate the scattering :param fluxes: list of pulse fluences per energy (same length as energies) :param pids: panel ids to simulate on (None means all panels) :param cuda: whether to use GPU (only works for nvidia builds) :param oversample: pixel oversample factor (0 means nanoBragg will decide) :param Ncells_abc: number of unit cells along each crystal direction in the mosaic block :param mos_dom: number of mosaic domains in used to sample mosaic spread (texture) :param mos_spread: mosaicity in degrees (spherical cap width) :param beamsize_mm: focal size of the beam :param device_Id: cuda device id (ignore if cuda=False) :param omp: whether to use open mp (required open MP build configuration) :param show_params: show the nanoBragg parameters :param crystal_size_mm: size of the crystal (increases the intensity of the spots) :param printout_pix: debug pixel position : tuple of (pixel_fast_coord, pixel_slow_coord) :param time_panels: show timing info :param verbose: verbosity level for nanoBragg (0-10), 0 is quiet :param default_F: default amplitude value for nanoBragg :param interpolate: whether to interpolate for small mosaic domains :param recenter: recenter for tilted cameras, deprecated :param profile: profile shape, can be : gauss, round, square, or tophat :param spot_scale_override: scale the simulated scattering bythis amounth (overrides value based on crystal thickness) :param background_raw_pixels: dictionary of {panel_id: raw_pixels}, add these background pixels to the simulated Bragg :param include_noise: add noise to simulated pattern :param add_water: add water to similated pattern :param add_air: add ait to simulated pattern :param water_path_mm: length of water the beam travels through :param air_path_mm: length of air the beam travels through :param rois_perpanel: regions of intererest on each panel :param adc_offset: add this value to each pixel in simulated pattern :param readout_noise: readout noise level (usually 3-5 ADU) :param psf_fwhm: point spread kernel FWHM :param gain: photon gain :param mosaicity_random_seeds: random seeds to simulating mosaic texture :return: list of [(panel_id0,simulated pattern0), (panel_id1, simulated_pattern1), ...] """ if pids is None: pids = range(len(DETECTOR)) if background_raw_pixels is None: background_raw_pixels = {pid: None for pid in pids} if rois_perpanel is None: rois_perpanel = {pid: None for pid in pids} nbBeam = NBbeam() nbBeam.size_mm = beamsize_mm nbBeam.unit_s0 = BEAM.get_unit_s0() wavelengths = ENERGY_CONV / np.array(energies) nbBeam.spectrum = list(zip(wavelengths, fluxes)) nbCrystal = NBcrystal() nbCrystal.dxtbx_crystal = CRYSTAL nbCrystal.miller_array = Famp nbCrystal.Ncells_abc = Ncells_abc nbCrystal.symbol = CRYSTAL.get_space_group().info().type().lookup_symbol() nbCrystal.thick_mm = crystal_size_mm nbCrystal.xtal_shape = profile nbCrystal.n_mos_domains = mos_dom nbCrystal.mos_spread_deg = mos_spread panel_images = [] tinit = time.time() S = SimData() S.detector = DETECTOR S.beam = nbBeam S.crystal = nbCrystal S.using_cuda = cuda S.using_omp = omp S.add_air = add_air S.air_path_mm = air_path_mm S.add_water = add_water S.water_path_mm = water_path_mm S.readout_noise = readout_noise S.gain = gain S.psf_fwhm = psf_fwhm S.include_noise = include_noise if mosaicity_random_seeds is not None: S.mosaic_seeds = mosaicity_random_seeds S.instantiate_nanoBragg(verbose=verbose, oversample=oversample, interpolate=interpolate, device_Id=device_Id, default_F=default_F, adc_offset=adc_offset) if printout_pix is not None: S.update_nanoBragg_instance("printout_pixel_fastslow", printout_pix) if spot_scale_override is not None: S.update_nanoBragg_instance("spot_scale", spot_scale_override) for pid in pids: t_panel = time.time() S.background_raw_pixels = background_raw_pixels[pid] S.panel_id = pid S.rois = rois_perpanel[pid] S.generate_simulated_image() if show_params: S.D.show_params() print('spot scale: %2.7g' % S.D.spot_scale) panel_image = S.D.raw_pixels.as_numpy_array() panel_images.append([pid, panel_image]) S.D.raw_pixels *= 0 if time_panels: tdone = time.time() - tinit t_panel = time.time() - t_panel print( 'Panel %d took %.4f seconds (Total sim time = %.4f seconds)' % (pid, t_panel, tdone)) S.D.free_all() return panel_images
def multipanel_sim( CRYSTAL, DETECTOR, BEAM, Famp, energies, fluxes, background_wavelengths=None, background_wavelength_weights=None, background_total_flux=None, background_sample_thick_mm=None, density_gcm3=1, molecular_weight=18, cuda=False, oversample=0, Ncells_abc=(50, 50, 50), mos_dom=1, mos_spread=0, mosaic_method="double_uniform", mos_aniso=None, beamsize_mm=0.001, crystal_size_mm=0.01, verbose=0, default_F=0, interpolate=0, profile="gauss", spot_scale_override=None, show_params=False, time_panels=False, add_water = False, add_air=False, water_path_mm=0.005, air_path_mm=0, adc_offset=0, readout_noise=3, psf_fwhm=0, gain=1, mosaicity_random_seeds=None, include_background=True, mask_file="",skip_numpy=False,relevant_whitelist_order=None): from simtbx.nanoBragg.nanoBragg_beam import NBbeam from simtbx.nanoBragg.nanoBragg_crystal import NBcrystal from simtbx.nanoBragg.sim_data import SimData from simtbx.nanoBragg.utils import get_xray_beams from scitbx.array_family import flex from scipy import constants import numpy as np ENERGY_CONV = 10000000000.0 * constants.c * constants.h / constants.electron_volt assert cuda # disallow the default nbBeam = NBbeam() nbBeam.size_mm = beamsize_mm nbBeam.unit_s0 = BEAM.get_unit_s0() wavelengths = ENERGY_CONV / np.array(energies) nbBeam.spectrum = list(zip(wavelengths, fluxes)) nbCrystal = NBcrystal(False) nbCrystal.dxtbx_crystal = CRYSTAL #nbCrystal.miller_array = None # use the gpu_channels_singleton mechanism instead nbCrystal.Ncells_abc = Ncells_abc nbCrystal.symbol = CRYSTAL.get_space_group().info().type().lookup_symbol() nbCrystal.thick_mm = crystal_size_mm nbCrystal.xtal_shape = profile nbCrystal.n_mos_domains = mos_dom nbCrystal.mos_spread_deg = mos_spread nbCrystal.anisotropic_mos_spread_deg = mos_aniso pid = 0 # remove the loop, use C++ iteration over detector panels use_exascale_api = True if use_exascale_api: S = SimData(use_default_crystal = False) S.detector = DETECTOR S.beam = nbBeam S.crystal = nbCrystal S.panel_id = pid S.add_air = add_air S.air_path_mm = air_path_mm S.add_water = add_water S.water_path_mm = water_path_mm S.readout_noise = readout_noise S.gain = gain S.psf_fwhm = psf_fwhm S.include_noise = False S.Umats_method = dict(double_random=0, double_uniform=5)[mosaic_method] if mosaicity_random_seeds is not None: S.mosaic_seeds = mosaicity_random_seeds S.instantiate_nanoBragg(verbose=verbose, oversample=oversample, interpolate=interpolate, device_Id=Famp.get_deviceID(),default_F=default_F, adc_offset=adc_offset) SIM = S.D # the nanoBragg instance assert Famp.get_deviceID()==SIM.device_Id if spot_scale_override is not None: SIM.spot_scale = spot_scale_override assert Famp.get_nchannels() == 1 # non-anomalous scenario from simtbx.gpu import exascale_api gpu_simulation = exascale_api(nanoBragg = SIM) gpu_simulation.allocate() # presumably done once for each image from simtbx.gpu import gpu_detector as gpud gpu_detector = gpud(deviceId=SIM.device_Id, detector=DETECTOR, beam=BEAM) gpu_detector.each_image_allocate() # revisit the allocate cuda for overlap with detector, sync up please x = 0 # only one energy channel if mask_file is "": # all-pixel kernel P = Profiler("%40s"%"from gpu amplitudes cuda") gpu_simulation.add_energy_channel_from_gpu_amplitudes( x, Famp, gpu_detector) elif type(mask_file) is flex.bool: # 1D bool array, flattened from ipanel, islow, ifast P = Profiler("%40s"%"from gpu amplitudes cuda with bool mask") gpu_simulation.add_energy_channel_mask_allpanel( channel_number = x, gpu_amplitudes = Famp, gpu_detector = gpu_detector, pixel_active_mask_bools = mask_file ) elif type(mask_file) is flex.int: # precalculated active_pixel_list P = Profiler("%40s"%"from gpu amplitudes cuda w/int whitelist") gpu_simulation.add_energy_channel_mask_allpanel( channel_number = x, gpu_amplitudes = Famp, gpu_detector = gpu_detector, pixel_active_list_ints = mask_file ) else: assert type(mask_file) is str from LS49.adse13_187.adse13_221.mask_utils import mask_from_file boolean_mask = mask_from_file(mask_file) P = Profiler("%40s"%"from gpu amplitudes cuda with file mask") gpu_simulation.add_energy_channel_mask_allpanel( x, Famp, gpu_detector, boolean_mask ) TIME_BRAGG = time()-P.start_el per_image_scale_factor = 1. gpu_detector.scale_in_place(per_image_scale_factor) # apply scale directly on GPU if include_background: t_bkgrd_start = time() SIM.beamsize_mm = beamsize_mm wavelength_weights = np.array(background_wavelength_weights) weights = wavelength_weights / wavelength_weights.sum() * background_total_flux spectrum = list(zip(background_wavelengths, weights)) xray_beams = get_xray_beams(spectrum, BEAM) SIM.xray_beams = xray_beams SIM.Fbg_vs_stol = water SIM.flux=sum(weights) SIM.amorphous_sample_thick_mm = background_sample_thick_mm SIM.amorphous_density_gcm3 = density_gcm3 SIM.amorphous_molecular_weight_Da = molecular_weight gpu_simulation.add_background(gpu_detector) TIME_BG = time()-t_bkgrd_start else: TIME_BG=0. if skip_numpy: P = Profiler("%40s"%"get short whitelist values") whitelist_only = gpu_detector.get_whitelist_raw_pixels(relevant_whitelist_order) # whitelist_only, flex_double pixel values # relevant_whitelist_order, flex.size_t detector addresses assert len(whitelist_only) == len(relevant_whitelist_order) # guard against shoebox overlap bug # when shoeboxes overlap, the overlapped pixels should be simulated once for each parent shoebox P = Profiler("%40s"%"each image free cuda") gpu_detector.each_image_free() return whitelist_only, TIME_BG, TIME_BRAGG, S.exascale_mos_blocks or None packed_numpy = gpu_detector.get_raw_pixels() gpu_detector.each_image_free() return packed_numpy.as_numpy_array(), TIME_BG, TIME_BRAGG, S.exascale_mos_blocks or None
# with background and noise # <><><><><><><><><><><><><><><><><><><><><><><><><> nbcryst = NBcrystal() nbcryst.dxtbx_crystal = C # simulate ground truth nbcryst.thick_mm = 0.1 nbcryst.isotropic_ncells = False if "eta" in args.perturb: nbcryst.n_mos_domains = 1000 ETA_ABC_GT = args.eta nbcryst.anisotropic_mos_spread_deg = ETA_ABC_GT NCELLS_GT = 12, 12, 11 else: NCELLS_GT = 12, 12, 11 nbcryst.Ncells_abc = NCELLS_GT SIM = SimData(use_default_crystal=True) #SIM.detector = SimData.simple_detector(150, 0.1, (513, 512)) if "eta" in args.perturb: shape = 513 * 3, 512 * 3 #detdist = 70 else: shape = 513, 512 detdist = 150 SIM.detector = SimData.simple_detector(detdist, 0.1, shape) SIM.crystal = nbcryst SIM.instantiate_diffBragg(oversample=0, auto_set_spotscale=True) SIM.D.default_F = 0 SIM.D.F000 = 0 SIM.D.progress_meter = False SIM.water_path_mm = 0.005 SIM.air_path_mm = 0.1
ucell = (70, 60, 50, 90.0, 110, 90.0) symbol = "C121" a_real, b_real, c_real = sqr( uctbx.unit_cell( ucell).orthogonalization_matrix()).transpose().as_list_of_lists() C = Crystal(a_real, b_real, c_real, symbol) # make a nanoBragg crystal to pass to diffBragg nbcryst = NBcrystal() nbcryst.dxtbx_crystal = C nbcryst.n_mos_domains = 1 nbcryst.thick_mm = 0.01 nbcryst.Ncells_abc = (7, 7, 7) # make an instance of diffBRagg, use the simData wrapper SIM = SimData(use_default_crystal=True) # overwrite the default detector with a smaller pixels one SIM.detector = SimData.simple_detector(220, 0.1, (1000, 1000)) SIM.crystal = nbcryst SIM.instantiate_diffBragg(oversample=0, verbose=0, interpolate=0, default_F=1e3, auto_set_spotscale=True) # D is an instance of diffBragg with reasonable parameters # and our dxtbx crystal created above D = SIM.D if args.curvatures: D.compute_curvatures = True
def diffBragg_forward(CRYSTAL, DETECTOR, BEAM, Famp, energies, fluxes, oversample=0, Ncells_abc=(50, 50, 50), mos_dom=1, mos_spread=0, beamsize_mm=0.001, device_Id=0, show_params=True, crystal_size_mm=None, printout_pix=None, verbose=0, default_F=0, interpolate=0, profile="gauss", spot_scale_override=None, mosaicity_random_seeds=None, nopolar=False, diffuse_params=None, cuda=False, show_timings=False): if cuda: os.environ["DIFFBRAGG_USE_CUDA"] = "1" CRYSTAL, Famp = nanoBragg_utils.ensure_p1(CRYSTAL, Famp) nbBeam = NBbeam() nbBeam.size_mm = beamsize_mm nbBeam.unit_s0 = BEAM.get_unit_s0() wavelengths = utils.ENERGY_CONV / np.array(energies) nbBeam.spectrum = list(zip(wavelengths, fluxes)) nbCrystal = NBcrystal(init_defaults=False) nbCrystal.isotropic_ncells = False nbCrystal.dxtbx_crystal = CRYSTAL nbCrystal.miller_array = Famp nbCrystal.Ncells_abc = Ncells_abc nbCrystal.symbol = CRYSTAL.get_space_group().info().type().lookup_symbol() nbCrystal.thick_mm = crystal_size_mm nbCrystal.xtal_shape = profile nbCrystal.n_mos_domains = mos_dom nbCrystal.mos_spread_deg = mos_spread S = SimData() S.detector = DETECTOR npan = len(DETECTOR) nfast, nslow = DETECTOR[0].get_image_size() img_shape = npan, nslow, nfast S.beam = nbBeam S.crystal = nbCrystal if mosaicity_random_seeds is not None: S.mosaic_seeds = mosaicity_random_seeds S.instantiate_diffBragg(verbose=verbose, oversample=oversample, interpolate=interpolate, device_Id=device_Id, default_F=default_F, auto_set_spotscale=crystal_size_mm is not None and spot_scale_override is None) if spot_scale_override is not None: S.update_nanoBragg_instance("spot_scale", spot_scale_override) S.update_nanoBragg_instance("nopolar", nopolar) if show_params: S.D.show_params() print("Spot scale=%f" % S.D.spot_scale) if show_timings and verbose < 2: S.D.verbose = 2 S.D.record_time = True if diffuse_params is not None: S.D.use_diffuse = True S.D.gamma_miller_units = diffuse_params["gamma_miller_units"] S.D.diffuse_gamma = diffuse_params["gamma"] S.D.diffuse_sigma = diffuse_params["sigma"] S.D.add_diffBragg_spots_full() if show_timings: S.D.show_timings() t = time.time() data = S.D.raw_pixels_roi.as_numpy_array().reshape(img_shape) t = time.time() - t if show_timings: print("Took %f sec to recast and reshape" % t) if printout_pix is not None: S.D.raw_pixels_roi *= 0 p, f, s = printout_pix S.D.printout_pixel_fastslow = f, s S.D.show_params() S.D.add_diffBragg_spots(printout_pix) # free up memory S.D.free_all() S.D.free_Fhkl2() if S.D.gpu_free is not None: S.D.gpu_free() return data
nbcryst.dxtbx_crystal = C # simulate ground truth nbcryst.thick_mm = 0.1 nbcryst.Ncells_abc = Ncells_gt # ground truth Ncells nbcryst.mos_spread_deg = MOS_SPREAD if args.aniso is not None: nbcryst.anisotropic_mos_spread_deg = ANISO_MOS_SPREAD assert nbcryst.has_anisotropic_mosaicity else: assert not nbcryst.has_anisotropic_mosaicity nbcryst.n_mos_domains = N_MOS_DOMAINS nbcryst.miller_array = miller_array_GT print("Ground truth ncells = %f" % (nbcryst.Ncells_abc[0])) # ground truth detector DET_gt = SimData.simple_detector(150, 0.177, (600, 600)) # initialize the simulator SIM = SimData() if args.aniso is None: SIM.Umats_method = 2 else: SIM.Umats_method = 3 SIM.detector = DET_gt SIM.crystal = nbcryst SIM.instantiate_diffBragg(oversample=1, verbose=0) SIM.D.refine(eta_diffBragg_id) SIM.D.initialize_managers() SIM.D.spot_scale = 100000 SIM.D.default_F = 0 SIM.D.progress_meter = False
# STEP3: # create the unit cell parameter manager UcellMan = utils.manager_from_params(ucell) n_ucell_params = len(UcellMan.variables) assert np.allclose(UcellMan.B_recipspace, C.get_B()) # STEP4: # make a nanoBragg crystal to pass to diffBragg nbcryst = NBcrystal(init_defaults=True) nbcryst.dxtbx_crystal = C nbcryst.n_mos_domains = 1 nbcryst.thick_mm = 0.01 nbcryst.Ncells_abc = (7, 7, 7) # STEP5: make an instance of diffBRagg, use the simData wrapper SIM = SimData() # overwrite the default detector to use smaller pixels img_sh = 700, 700 SIM.detector = SimData.simple_detector(300, 0.1, img_sh) SIM.crystal = nbcryst SIM.instantiate_diffBragg(oversample=0, verbose=0, auto_set_spotscale=True) # D is an instance of diffBragg with sensible parameters # and our dxtbx crystal created above D = SIM.D D.progress_meter = True # STEP6: # initialize the derivative managers for the unit cell parameters for i_param in range(n_ucell_params): D.refine(UCELL_ID_OFFSET + i_param) for i in range(n_ucell_params):
def flexBeam_sim_colors(CRYSTAL, DETECTOR, BEAM, Famp, energies, fluxes, pids=None, cuda=False, oversample=0, Ncells_abc=(50, 50, 50), mos_dom=1, mos_spread=0, beamsize_mm=0.001, device_Id=0, omp=False, show_params=False, crystal_size_mm=0.01, printout_pix=None, time_panels=True, verbose=0, default_F=0, interpolate=0, recenter=True, profile="gauss", spot_scale_override=None, background_raw_pixels=None, include_noise=False, add_water=False, add_air=False, water_path_mm=0.005, air_path_mm=0, rois_perpanel=None, adc_offset=0, readout_noise=3, psf_fwhm=0, gain=1, mosaicity_random_seeds=None): if pids is None: pids = range(len(DETECTOR)) if background_raw_pixels is None: background_raw_pixels = {pid: None for pid in pids} if rois_perpanel is None: rois_perpanel = {pid: None for pid in pids} nbBeam = NBbeam() nbBeam.size_mm = beamsize_mm nbBeam.unit_s0 = BEAM.get_unit_s0() wavelengths = ENERGY_CONV / np.array(energies) nbBeam.spectrum = list(zip(wavelengths, fluxes)) nbCrystal = NBcrystal() nbCrystal.dxtbx_crystal = CRYSTAL nbCrystal.miller_array = Famp nbCrystal.Ncells_abc = Ncells_abc nbCrystal.symbol = CRYSTAL.get_space_group().info().type().lookup_symbol() nbCrystal.thick_mm = crystal_size_mm nbCrystal.xtal_shape = profile nbCrystal.n_mos_domains = mos_dom nbCrystal.mos_spread_deg = mos_spread panel_images = [] for pid in pids: tinit = time.time() S = SimData() S.detector = DETECTOR S.beam = nbBeam S.crystal = nbCrystal S.panel_id = pid S.using_cuda = cuda S.using_omp = omp S.add_air = add_air S.air_path_mm = air_path_mm S.add_water = add_water S.water_path_mm = water_path_mm S.background_raw_pixels = background_raw_pixels[pid] S.rois = rois_perpanel[pid] S.readout_noise = readout_noise S.gain = gain S.psf_fwhm = psf_fwhm S.include_noise = include_noise if mosaicity_random_seeds is not None: S.mosaic_seeds = mosaicity_random_seeds S.instantiate_nanoBragg(verbose=verbose, oversample=oversample, interpolate=interpolate, device_Id=device_Id, default_F=default_F, adc_offset=adc_offset) if recenter: S.update_nanoBragg_instance( "beam_center_mm", DETECTOR[int(pid)].get_beam_centre(BEAM.get_s0())) if printout_pix is not None: S.update_nanoBragg_instance("printout_pixel_fastslow", printout_pix) if spot_scale_override is not None: S.update_nanoBragg_instance("spot_scale", spot_scale_override) S.generate_simulated_image() if show_params: S.D.show_params() print('spot scale: %2.7g' % S.D.spot_scale) panel_image = S.D.raw_pixels.as_numpy_array() panel_images.append([pid, panel_image]) S.D.free_all() if time_panels: tdone = time.time() - tinit print('Panel %d took %.4f seconds' % (pid, tdone)) del S.D return panel_images
# random raotation rotation = Rotation.random(num=1, random_state=101)[0] Q = rec(rotation.as_quat(), n=(4, 1)) rot_ang, rot_axis = Q.unit_quaternion_as_axis_and_angle() C.rotate_around_origin(rot_axis, rot_ang) # make a nanoBragg crystal to pass to diffBragg nbcryst = NBcrystal(init_defaults=True) nbcryst.dxtbx_crystal = C nbcryst.n_mos_domains = 1 nbcryst.thick_mm = 0.01 nbcryst.Ncells_abc = (7, 7, 7) # make an instance of diffBRagg, use the simData wrapper SIM = SimData(use_default_crystal=True) # overwrite the default detector with a smaller pixels one SIM.detector = SimData.simple_detector(300, 0.1, (700, 700)) SIM.crystal = nbcryst Fcell = 1e6 SIM.instantiate_diffBragg(oversample=0, verbose=0, interpolate=0, default_F=Fcell) # D is an instance of diffBragg with reasonable parameters # and our dxtbx crystal created above D = SIM.D D.progress_meter = True # initialize the derivative manager for Fcell