def create_spec_model(npoints=10, flux=1e-9, wave_range=(11, 13)): """Create a SpecModel""" flux = np.full(npoints, flux) wavelength = np.arange(*wave_range, step=(wave_range[1] - wave_range[0]) / npoints) error = np.zeros(npoints) surf_bright = np.zeros(npoints) sb_error = np.zeros(npoints) var_dummy = error.copy() dq = np.zeros(npoints) background = np.zeros(npoints) berror = np.zeros(npoints) npixels = np.zeros(npoints) spec_dtype = datamodels.SpecModel( ).spec_table.dtype # This data type is used for creating an output table. otab = np.array(list( zip(wavelength, flux, error, var_dummy, var_dummy, var_dummy, surf_bright, sb_error, var_dummy, var_dummy, var_dummy, dq, background, berror, var_dummy, var_dummy, var_dummy, npixels), ), dtype=spec_dtype) spec_model = datamodels.SpecModel(spec_table=otab) return spec_model
def user_bkg_spec_b(): """Create "user-background" data for testing. `expand_to_2d` uses `np.interp` for interpolation, and the wavelength array that is passed to `np.interp` must be increasing. `expand_to_2d` is supposed to handle the case that the wavelengths are decreasing. Create data for checking that the results are the same even if the wavelength array in `m_bkg_spec` is reversed so that the values are decreasing, and the corresponding flux array is also reversed to retain the original (wavelength, flux) relation. Returns ------- m_bkg_spec : `~jwst.datamodels.MultiSpecModel` """ # This data type is used for creating a MultiSpecModel. spec_dtype = datamodels.SpecModel().spec_table.dtype m_bkg_spec = datamodels.MultiSpecModel() wavelength = np.geomspace(1.5, 4.5, num=25, endpoint=True, dtype=np.float64)[::-1] flux = np.zeros_like(wavelength) error = np.ones_like(wavelength) var_dummy = error.copy() surf_bright = np.linspace(13., 25., num=25, endpoint=True, retstep=False, dtype=np.float64)[::-1] sb_error = np.ones_like(wavelength) dq = np.zeros(wavelength.shape, dtype=np.uint32) background = np.ones_like(wavelength) berror = np.ones_like(wavelength) npixels = np.ones_like(wavelength) otab = np.array(list( zip(wavelength, flux, error, var_dummy, var_dummy, var_dummy, surf_bright, sb_error, var_dummy, var_dummy, var_dummy, dq, background, berror, var_dummy, var_dummy, var_dummy, npixels)), dtype=spec_dtype) spec = datamodels.SpecModel(spec_table=otab) m_bkg_spec.spec.append(spec) return m_bkg_spec
def create_spec_model(npoints=10, flux=1e-9, wave_range=(11, 13)): """Create a SpecModel""" flux = np.full(npoints, flux) wavelength = np.arange(*wave_range, step=(wave_range[1] - wave_range[0]) / npoints) error = np.zeros(npoints) surf_bright = np.zeros(npoints) sb_error = np.zeros(npoints) dq = np.zeros(npoints) background = np.zeros(npoints) berror = np.zeros(npoints) npixels = np.zeros(npoints) data = [(i, j, k, l, m, n, o, p, q) for i, j, k, l, m, n, o, p, q in zip( wavelength, flux, error, surf_bright, sb_error, dq, background, berror, npixels)] spec_table = np.array(data, dtype=[('WAVELENGTH', 'f8'), ('FLUX', 'f8'), ('ERROR', 'f8'), ('SURF_BRIGHT', 'f8'), ('SB_ERROR', 'f8'), ('DQ', 'u4'), ('BACKGROUND', 'f8'), ('BERROR', 'f8'), ('NPIXELS', 'f8')]) spec_model = datamodels.SpecModel() spec_model.spec_table = spec_table return spec_model
def user_bkg_spec_a(): """Create "user-background" data for testing. Returns ------- m_bkg_spec : `~jwst.datamodels.MultiSpecModel` """ # This data type is used for creating a MultiSpecModel. spec_dtype = datamodels.SpecModel().spec_table.dtype # m_bkg_spec doesn't have to be a MultiSpecModel, but that's an option. m_bkg_spec = datamodels.MultiSpecModel() wavelength = np.geomspace(1.5, 4.5, num=25, endpoint=True, dtype=np.float64) flux = np.zeros_like(wavelength) error = np.ones_like(wavelength) var_dummy = error.copy() surf_bright = np.linspace(13., 25., num=25, endpoint=True, retstep=False, dtype=np.float64) sb_error = np.ones_like(wavelength) dq = np.zeros(wavelength.shape, dtype=np.uint32) background = np.ones_like(wavelength) berror = np.ones_like(wavelength) # The npixels column should no longer be used. Set it to a large value # to make it more obvious in case it actually is still used. npixels = np.zeros_like(wavelength) + 2000. otab = np.array(list( zip(wavelength, flux, error, var_dummy, var_dummy, var_dummy, surf_bright, sb_error, var_dummy, var_dummy, var_dummy, dq, background, berror, var_dummy, var_dummy, var_dummy, npixels)), dtype=spec_dtype) spec = datamodels.SpecModel(spec_table=otab) m_bkg_spec.spec.append(spec) return m_bkg_spec
def make_datamodel(): """Make data for white light tests""" model = datamodels.MultiSpecModel() model.meta.exposure.group_time = 0.15904 model.meta.exposure.ngroups = 60 model.meta.exposure.start_time = 58627.0 model.meta.exposure.integration_start = 1 model.meta.exposure.integration_end = 2 # Make data arrays flux = np.random.rand(200) * 1e-9 wavelength = np.arange(11, 13, step=0.01) error = np.random.rand(200) surf_bright = np.zeros(200) sb_error = np.zeros(200) dq = np.ones(200) background = np.zeros(200) berror = np.zeros(200) npixels = np.zeros(200) data = [(i, j, k, l, m, n, o, p, q) for i, j, k, l, m, n, o, p, q in zip( wavelength, flux, error, surf_bright, sb_error, dq, background, berror, npixels)] spec_table = np.array(data, dtype=[('WAVELENGTH', 'f8'), ('FLUX', 'f8'), ('ERROR', 'f8'), ('SURF_BRIGHT', 'f8'), ('SB_ERROR', 'f8'), ('DQ', 'u4'), ('BACKGROUND', 'f8'), ('BERROR', 'f8'), ('NPIXELS', 'f8')]) spectrum = datamodels.SpecModel() spectrum.spec_table = spec_table model.spec.append(spectrum) integrations = [ (1, 58627.53891071, 58627.53896565, 58627.5390206, 0., 0., 0.), (2, 58627.5390206, 58627.53907555, 58627.5391305, 0., 0., 0.), (3, 58627.5391305, 58627.53918544, 58627.53924039, 0., 0., 0.) ] integration_table = np.array(integrations, dtype=[('integration_number', 'i4'), ('int_start_MJD_UTC', 'f8'), ('int_mid_MJD_UTC', 'f8'), ('int_end_MJD_UTC', 'f8'), ('int_start_BJD_TDB', 'f8'), ('int_mid_BJD_TDB', 'f8'), ('int_end_BJD_TDB', 'f8')]) model.int_times = (integration_table) return model
def user_bkg_spec_a(): """Create "user-background" data for testing. Returns ------- m_bkg_spec : `~jwst.datamodels.MultiSpecModel` """ # This data type is used for creating a MultiSpecModel. spec_dtype = datamodels.SpecModel().spec_table.dtype # m_bkg_spec doesn't have to be a MultiSpecModel, but that's an option. m_bkg_spec = datamodels.MultiSpecModel() wavelength = np.geomspace(1.5, 4.5, num=25, endpoint=True, dtype=np.float64) flux = np.linspace(13., 25., num=25, endpoint=True, retstep=False, dtype=np.float64) fl_error = np.ones_like(wavelength) dq = np.zeros(wavelength.shape, dtype=np.uint32) net = np.zeros_like(wavelength) nerror = np.ones_like(wavelength) background = np.ones_like(wavelength) berror = np.ones_like(wavelength) npixels = np.ones_like(wavelength) otab = np.array(list( zip(wavelength, flux, fl_error, dq, net, nerror, background, berror, npixels)), dtype=spec_dtype) spec = datamodels.SpecModel(spec_table=otab) m_bkg_spec.spec.append(spec) return m_bkg_spec
def make_datamodel(): """Make data for white light tests""" model = datamodels.MultiSpecModel() model.meta.exposure.group_time = 0.15904 model.meta.exposure.ngroups = 60 model.meta.exposure.start_time = 58627.0 model.meta.exposure.integration_start = 1 model.meta.exposure.integration_end = 2 # Make data arrays flux = np.random.rand(200) * 1e-9 wavelength = np.arange(11, 13, step=0.01) f_var_poisson = np.random.rand(200) f_var_rnoise = np.random.rand(200) f_var_flat = np.random.rand(200) error = np.sqrt(f_var_poisson + f_var_rnoise + f_var_flat) surf_bright = np.zeros(200) sb_error = np.zeros(200) sb_var_poisson = sb_error.copy() sb_var_rnoise = sb_error.copy() sb_var_flat = sb_error.copy() dq = np.ones(200) background = np.zeros(200) berror = np.zeros(200) b_var_poisson = sb_error.copy() b_var_rnoise = sb_error.copy() b_var_flat = sb_error.copy() npixels = np.zeros(200) spec_dtype = datamodels.SpecModel( ).spec_table.dtype # This data type is used for creating an output table. otab = np.array(list( zip(wavelength, flux, error, f_var_poisson, f_var_rnoise, f_var_flat, surf_bright, sb_error, sb_var_poisson, sb_var_rnoise, sb_var_flat, dq, background, berror, b_var_poisson, b_var_rnoise, b_var_flat, npixels), ), dtype=spec_dtype) spec_model = datamodels.SpecModel(spec_table=otab) model.spec.append(spec_model) integrations = [ (1, 58627.53891071, 58627.53896565, 58627.5390206, 0., 0., 0.), (2, 58627.5390206, 58627.53907555, 58627.5391305, 0., 0., 0.), (3, 58627.5391305, 58627.53918544, 58627.53924039, 0., 0., 0.) ] integration_table = np.array(integrations, dtype=[('integration_number', 'i4'), ('int_start_MJD_UTC', 'f8'), ('int_mid_MJD_UTC', 'f8'), ('int_end_MJD_UTC', 'f8'), ('int_start_BJD_TDB', 'f8'), ('int_mid_BJD_TDB', 'f8'), ('int_end_BJD_TDB', 'f8')]) model.int_times = integration_table return model