def build_miri_output_wcs(self, refwcs=None): """ Create a simple output wcs covering footprint of the input datamodels """ # TODO: generalize this for more than one input datamodel # TODO: generalize this for imaging modes with distorted wcs input_model = self.input_models[0] if refwcs == None: refwcs = input_model.meta.wcs x, y = wcstools.grid_from_bounding_box(refwcs.bounding_box, step=(1, 1), center=True) ra, dec, lam = refwcs(x.flatten(), y.flatten()) # TODO: once astropy.modeling._Tabular is fixed, take out the # flatten() and reshape() code above and below ra = ra.reshape(x.shape) dec = dec.reshape(x.shape) lam = lam.reshape(x.shape) # Find rotation of the slit from y axis from the wcs forward transform # TODO: figure out if angle is necessary for MIRI. See for discussion # https://github.com/STScI-JWST/jwst/pull/347 rotation = [m for m in refwcs.forward_transform if \ isinstance(m, Rotation2D)] if rotation: rot_slit = functools.reduce(lambda x, y: x | y, rotation) rot_angle = rot_slit.inverse.angle.value unrotate = rot_slit.inverse refwcs_minus_rot = refwcs.forward_transform | \ unrotate & Identity(1) # Correct for this rotation in the wcs ra, dec, lam = refwcs_minus_rot(x.flatten(), y.flatten()) ra = ra.reshape(x.shape) dec = dec.reshape(x.shape) lam = lam.reshape(x.shape) # Get the slit size at the center of the dispersion sky_coords = SkyCoord(ra=ra, dec=dec, unit=u.deg) slit_coords = sky_coords[int(sky_coords.shape[0] / 2)] slit_angular_size = slit_coords[0].separation(slit_coords[-1]) log.debug('Slit angular size: {0}'.format(slit_angular_size.arcsec)) # Compute slit center from bounding_box dx0 = refwcs.bounding_box[0][0] dx1 = refwcs.bounding_box[0][1] dy0 = refwcs.bounding_box[1][0] dy1 = refwcs.bounding_box[1][1] slit_center_pix = (dx1 - dx0) / 2 dispersion_center_pix = (dy1 - dy0) / 2 slit_center = refwcs_minus_rot(dx0 + slit_center_pix, dy0 + dispersion_center_pix) slit_center_sky = SkyCoord(ra=slit_center[0], dec=slit_center[1], unit=u.deg) log.debug('slit center: {0}'.format(slit_center)) # Compute spatial and spectral scales spatial_scale = slit_angular_size / slit_coords.shape[0] log.debug('Spatial scale: {0}'.format(spatial_scale.arcsec)) tcenter = int((dx1 - dx0) / 2) trace = lam[:, tcenter] trace = trace[~np.isnan(trace)] spectral_scale = np.abs((trace[-1] - trace[0]) / trace.shape[0]) log.debug('spectral scale: {0}'.format(spectral_scale)) # Compute transform for output frame log.debug('Slit center %s' % slit_center_pix) offset = Shift(-slit_center_pix) & Shift(-slit_center_pix) # TODO: double-check the signs on the following rotation angles roll_ref = input_model.meta.wcsinfo.roll_ref * u.deg rot = Rotation2D(roll_ref) tan = Pix2Sky_TAN() lon_pole = _compute_lon_pole(slit_center_sky, tan) skyrot = RotateNative2Celestial(slit_center_sky.ra, slit_center_sky.dec, lon_pole) min_lam = np.nanmin(lam) mapping = Mapping((0, 0, 1)) transform = Shift(-slit_center_pix) & Identity(1) | \ Scale(spatial_scale) & Scale(spectral_scale) | \ Identity(1) & Shift(min_lam) | mapping | \ (rot | tan | skyrot) & Identity(1) transform.inputs = (x, y) transform.outputs = ('ra', 'dec', 'lamda') # Build the output wcs input_frame = refwcs.input_frame output_frame = refwcs.output_frame wnew = WCS(output_frame=output_frame, forward_transform=transform) # Build the bounding_box in the output frame wcs object bounding_box_grid = wnew.backward_transform(ra, dec, lam) bounding_box = [] for axis in input_frame.axes_order: axis_min = np.nanmin(bounding_box_grid[axis]) axis_max = np.nanmax(bounding_box_grid[axis]) bounding_box.append((axis_min, axis_max)) wnew.bounding_box = tuple(bounding_box) # Update class properties self.output_spatial_scale = spatial_scale self.output_spectral_scale = spectral_scale self.output_wcs = wnew
def build_miri_output_wcs(self, refwcs=None): """ Create a simple output wcs covering footprint of the input datamodels """ # TODO: generalize this for more than one input datamodel # TODO: generalize this for imaging modes with distorted wcs input_model = self.input_models[0] if refwcs == None: refwcs = input_model.meta.wcs # Generate grid of sky coordinates for area within domain x, y = wcstools.grid_from_domain(refwcs.domain) ra, dec, lam = refwcs(x.flatten(), y.flatten()) # TODO: once astropy.modeling._Tabular is fixed, take out the # flatten() and reshape() code above and below ra = ra.reshape(x.shape) dec = dec.reshape(x.shape) lam = lam.reshape(x.shape) # Find rotation of the slit from y axis from the wcs forward transform # TODO: figure out if angle is necessary for MIRI. See for discussion # https://github.com/STScI-JWST/jwst/pull/347 rotation = [m for m in refwcs.forward_transform if \ isinstance(m, Rotation2D)] if rotation: rot_slit = functools.reduce(lambda x, y: x | y, rotation) rot_angle = rot_slit.inverse.angle.value unrotate = rot_slit.inverse refwcs_minus_rot = refwcs.forward_transform | \ unrotate & Identity(1) # Correct for this rotation in the wcs ra, dec, lam = refwcs_minus_rot(x.flatten(), y.flatten()) ra = ra.reshape(x.shape) dec = dec.reshape(x.shape) lam = lam.reshape(x.shape) # Get the slit size at the center of the dispersion sky_coords = SkyCoord(ra=ra, dec=dec, unit=u.deg) slit_coords = sky_coords[int(sky_coords.shape[0] / 2)] slit_angular_size = slit_coords[0].separation(slit_coords[-1]) log.debug('Slit angular size: {0}'.format(slit_angular_size.arcsec)) # Compute slit center from domain dx0 = refwcs.domain[0]['lower'] dx1 = refwcs.domain[0]['upper'] dy0 = refwcs.domain[1]['lower'] dy1 = refwcs.domain[1]['upper'] slit_center_pix = (dx1 - dx0) / 2 dispersion_center_pix = (dy1 - dy0) / 2 slit_center = refwcs_minus_rot(dx0 + slit_center_pix, dy0 + dispersion_center_pix) slit_center_sky = SkyCoord(ra=slit_center[0], dec=slit_center[1], unit=u.deg) log.debug('slit center: {0}'.format(slit_center)) # Compute spatial and spectral scales spatial_scale = slit_angular_size / slit_coords.shape[0] log.debug('Spatial scale: {0}'.format(spatial_scale.arcsec)) tcenter = int((dx1 - dx0) / 2) trace = lam[:, tcenter] trace = trace[~np.isnan(trace)] spectral_scale = np.abs((trace[-1] - trace[0]) / trace.shape[0]) log.debug('spectral scale: {0}'.format(spectral_scale)) # Compute transform for output frame log.debug('Slit center %s' % slit_center_pix) offset = Shift(-slit_center_pix) & Shift(-slit_center_pix) # TODO: double-check the signs on the following rotation angles roll_ref = input_model.meta.wcsinfo.roll_ref * u.deg rot = Rotation2D(roll_ref) tan = Pix2Sky_TAN() lon_pole = _compute_lon_pole(slit_center_sky, tan) skyrot = RotateNative2Celestial(slit_center_sky.ra, slit_center_sky.dec, lon_pole) min_lam = np.nanmin(lam) mapping = Mapping((0, 0, 1)) transform = Shift(-slit_center_pix) & Identity(1) | \ Scale(spatial_scale) & Scale(spectral_scale) | \ Identity(1) & Shift(min_lam) | mapping | \ (rot | tan | skyrot) & Identity(1) transform.inputs = (x, y) transform.outputs = ('ra', 'dec', 'lamda') # Build the output wcs input_frame = refwcs.input_frame output_frame = refwcs.output_frame wnew = WCS(output_frame=output_frame, forward_transform=transform) # Build the domain in the output frame wcs object domain_grid = wnew.backward_transform(ra, dec, lam) domain = [] for axis in input_frame.axes_order: axis_min = np.nanmin(domain_grid[axis]) axis_max = np.nanmax(domain_grid[axis]) + 1 domain.append({'lower': axis_min, 'upper': axis_max, 'includes_lower': True, 'includes_upper': False}) log.debug('Domain: {0} {1}'.format(domain[0]['lower'], domain[0]['upper'])) log.debug('Domain: {0} {1}'.format(domain[1]['lower'], domain[1]['upper'])) wnew.domain = domain # Update class properties self.output_spatial_scale = spatial_scale self.output_spectral_scale = spectral_scale self.output_wcs = wnew
def build_nirspec_output_wcs(self, refwcs=None): """ Create a simple output wcs covering footprint of the input datamodels """ # TODO: generalize this for more than one input datamodel # TODO: generalize this for imaging modes with distorted wcs input_model = self.input_models[0] if refwcs == None: refwcs = input_model.meta.wcs # Generate grid of sky coordinates for area within bounding box bb = refwcs.bounding_box det = x, y = wcstools.grid_from_bounding_box(bb, step=(1, 1), center=True) sky = ra, dec, lam = refwcs(*det) x_center = int((bb[0][1] - bb[0][0]) / 2) y_center = int((bb[1][1] - bb[1][0]) / 2) log.debug("Center of bounding box: {} {}".format(x_center, y_center)) # Compute slit angular size, slit center sky coords xpos = [] sz = 3 for row in lam: if np.isnan(row[x_center]): xpos.append(np.nan) else: f = interpolate.interp1d(row[x_center - sz + 1:x_center + sz], x[y_center, x_center - sz + 1:x_center + sz], bounds_error=False, fill_value='extrapolate') xpos.append(f(lam[y_center, x_center])) x_arg = np.array(xpos)[~np.isnan(lam[:, x_center])] y_arg = y[~np.isnan(lam[:, x_center]), x_center] # slit_coords, spect0 = refwcs(x_arg, y_arg, output='numericals_plus') slit_ra, slit_dec, slit_spec_ref = refwcs(x_arg, y_arg) slit_coords = SkyCoord(ra=slit_ra, dec=slit_dec, unit=u.deg) pix_num = np.flipud(np.arange(len(slit_ra))) # pix_num = np.arange(len(slit_ra)) interpol_ra = interpolate.interp1d(pix_num, slit_ra) interpol_dec = interpolate.interp1d(pix_num, slit_dec) slit_center_pix = len(slit_spec_ref) / 2. - 1 log.debug('Slit center pix: {0}'.format(slit_center_pix)) slit_center_sky = SkyCoord(ra=interpol_ra(slit_center_pix), dec=interpol_dec(slit_center_pix), unit=u.deg) log.debug('Slit center: {0}'.format(slit_center_sky)) log.debug('Fiducial: {0}'.format( resample_utils.compute_spec_fiducial([refwcs]))) angular_slit_size = np.abs(slit_coords[0].separation(slit_coords[-1])) log.debug('Slit angular size: {0}'.format(angular_slit_size.arcsec)) dra, ddec = slit_coords[0].spherical_offsets_to(slit_coords[-1]) offset_up_slit = (dra.to(u.arcsec), ddec.to(u.arcsec)) log.debug('Offset up the slit: {0}'.format(offset_up_slit)) # Compute spatial and spectral scales xposn = np.array(xpos)[~np.isnan(xpos)] dx = xposn[-1] - xposn[0] slit_npix = np.sqrt(dx**2 + np.array(len(xposn) - 1)**2) spatial_scale = angular_slit_size / slit_npix log.debug('Spatial scale: {0}'.format(spatial_scale.arcsec)) spectral_scale = lam[y_center, x_center] - lam[y_center, x_center - 1] # Compute slit angle relative (clockwise) to y axis slit_rot_angle = (np.arcsin(dx / slit_npix) * u.radian).to(u.degree) slit_rot_angle = slit_rot_angle.value log.debug('Slit rotation angle: {0}'.format(slit_rot_angle)) # Compute transform for output frame roll_ref = input_model.meta.wcsinfo.roll_ref min_lam = np.nanmin(lam) offset = Shift(-slit_center_pix) & Shift(-slit_center_pix) # TODO: double-check the signs on the following rotation angles rot = Rotation2D(roll_ref + slit_rot_angle) scale = Scale(spatial_scale.value) & Scale(spatial_scale.value) tan = Pix2Sky_TAN() lon_pole = _compute_lon_pole(slit_center_sky, tan) skyrot = RotateNative2Celestial(slit_center_sky.ra.value, slit_center_sky.dec.value, lon_pole.value) spatial_trans = offset | rot | scale | tan | skyrot spectral_trans = Scale(spectral_scale) | Shift(min_lam) mapping = Mapping((1, 1, 0)) mapping.inverse = Mapping((2, 1)) transform = mapping | spatial_trans & spectral_trans transform.outputs = ('ra', 'dec', 'lamda') # Build the output wcs input_frame = refwcs.input_frame output_frame = refwcs.output_frame wnew = WCS(output_frame=output_frame, forward_transform=transform) # Build the bounding_box in the output frame wcs object bounding_box_grid = wnew.backward_transform(ra, dec, lam) bounding_box = [] for axis in input_frame.axes_order: axis_min = np.nanmin(bounding_box_grid[axis]) axis_max = np.nanmax(bounding_box_grid[axis]) bounding_box.append((axis_min, axis_max)) wnew.bounding_box = tuple(bounding_box) # Update class properties self.output_spatial_scale = spatial_scale self.output_spectral_scale = spectral_scale self.output_wcs = wnew
def build_nirspec_output_wcs(self, refwcs=None): """ Create a simple output wcs covering footprint of the input datamodels """ # TODO: generalize this for more than one input datamodel # TODO: generalize this for imaging modes with distorted wcs input_model = self.input_models[0] if refwcs == None: refwcs = input_model.meta.wcs # Generate grid of sky coordinates for area within domain det = x, y = wcstools.grid_from_domain(refwcs.domain) sky = ra, dec, lam = refwcs(*det) domain_xsize = refwcs.domain[0]['upper'] - refwcs.domain[0]['lower'] domain_ysize = refwcs.domain[1]['upper'] - refwcs.domain[1]['lower'] x_center, y_center = int(domain_xsize / 2), int(domain_ysize / 2) # Compute slit angular size, slit center sky coords xpos = [] sz = 3 for row in lam: if np.isnan(row[x_center]): xpos.append(np.nan) else: f = interpolate.interp1d(row[x_center - sz + 1:x_center + sz], x[y_center, x_center - sz + 1:x_center + sz]) xpos.append(f(lam[y_center, x_center])) x_arg = np.array(xpos)[~np.isnan(lam[:, x_center])] y_arg = y[~np.isnan(lam[:,x_center]), x_center] # slit_coords, spect0 = refwcs(x_arg, y_arg, output='numericals_plus') slit_ra, slit_dec, slit_spec_ref = refwcs(x_arg, y_arg) slit_coords = SkyCoord(ra=slit_ra, dec=slit_dec, unit=u.deg) pix_num = np.flipud(np.arange(len(slit_ra))) # pix_num = np.arange(len(slit_ra)) interpol_ra = interpolate.interp1d(pix_num, slit_ra) interpol_dec = interpolate.interp1d(pix_num, slit_dec) slit_center_pix = len(slit_spec_ref) / 2. - 1 log.debug('Slit center pix: {0}'.format(slit_center_pix)) slit_center_sky = SkyCoord(ra=interpol_ra(slit_center_pix), dec=interpol_dec(slit_center_pix), unit=u.deg) log.debug('Slit center: {0}'.format(slit_center_sky)) log.debug('Fiducial: {0}'.format(resample_utils.compute_spec_fiducial([refwcs]))) angular_slit_size = np.abs(slit_coords[0].separation(slit_coords[-1])) log.debug('Slit angular size: {0}'.format(angular_slit_size.arcsec)) dra, ddec = slit_coords[0].spherical_offsets_to(slit_coords[-1]) offset_up_slit = (dra.to(u.arcsec), ddec.to(u.arcsec)) log.debug('Offset up the slit: {0}'.format(offset_up_slit)) # Compute spatial and spectral scales xposn = np.array(xpos)[~np.isnan(xpos)] dx = xposn[-1] - xposn[0] slit_npix = np.sqrt(dx**2 + np.array(len(xposn) - 1)**2) spatial_scale = angular_slit_size / slit_npix log.debug('Spatial scale: {0}'.format(spatial_scale.arcsec)) spectral_scale = lam[y_center, x_center] - lam[y_center, x_center - 1] # Compute slit angle relative (clockwise) to y axis slit_rot_angle = (np.arcsin(dx / slit_npix) * u.radian).to(u.degree) log.debug('Slit rotation angle: {0}'.format(slit_rot_angle)) # Compute transform for output frame roll_ref = input_model.meta.wcsinfo.roll_ref * u.deg min_lam = np.nanmin(lam) offset = Shift(-slit_center_pix) & Shift(-slit_center_pix) # TODO: double-check the signs on the following rotation angles rot = Rotation2D(roll_ref + slit_rot_angle) scale = Scale(spatial_scale) & Scale(spatial_scale) tan = Pix2Sky_TAN() lon_pole = _compute_lon_pole(slit_center_sky, tan) skyrot = RotateNative2Celestial(slit_center_sky.ra, slit_center_sky.dec, lon_pole) spatial_trans = offset | rot | scale | tan | skyrot spectral_trans = Scale(spectral_scale) | Shift(min_lam) mapping = Mapping((1, 1, 0)) mapping.inverse = Mapping((2, 1)) transform = mapping | spatial_trans & spectral_trans transform.outputs = ('ra', 'dec', 'lamda') # Build the output wcs input_frame = refwcs.input_frame output_frame = refwcs.output_frame wnew = WCS(output_frame=output_frame, forward_transform=transform) # Build the domain in the output frame wcs object domain_grid = wnew.backward_transform(*sky) domain = [] for axis in input_frame.axes_order: axis_min = np.nanmin(domain_grid[axis]) axis_max = np.nanmax(domain_grid[axis]) + 1 domain.append({'lower': axis_min, 'upper': axis_max, 'includes_lower': True, 'includes_upper': False}) log.debug('Domain: {0} {1}'.format(domain[1]['lower'], domain[1]['upper'])) wnew.domain = domain # Update class properties self.output_spatial_scale = spatial_scale self.output_spectral_scale = spectral_scale self.output_wcs = wnew