def get_ccd_data(self, ccd, data, **kwargs): """Get the bias values and update the data dictionary Parameters ---------- ccd : `MaskedCCD` The ccd we are getting data from data : `dict` The data we are updating Keywords -------- slot : `str` The slot name ifile : `int` The file index nfiles_used : `int` Total number of files """ slot = self.config.slot bias_type = self.get_bias_algo() ifile = kwargs['ifile'] nfiles = kwargs['nfiles'] amps = get_amp_list(ccd) for i, amp in enumerate(amps): regions = get_geom_regions(ccd, amp) serial_oscan = regions['serial_overscan'] img = get_raw_image(ccd, amp) bimg = imutil.bias_image(img, serial_oscan, bias_method=bias_type) bimg_row_mean = bimg[serial_oscan].getArray().mean(1) key_str = "biasval_%s_a%02i" % (slot, i) if key_str not in data: data[key_str] = np.ndarray((len(bimg_row_mean), nfiles)) data[key_str][:, ifile] = bimg_row_mean
def get_ccd_data(self, ccd, ref_frames, **kwargs): """Get the bias values and update the data dictionary Parameters ---------- ccd : `MaskedCCD` The ccd we are getting data from data : `dict` The data we are updating Keywords -------- ifile : `int` The file index s_correl : `array` Serial overscan correlations p_correl : `array` Parallel overscan correlations """ ifile = kwargs['ifile'] s_correl = kwargs['s_correl'] p_correl = kwargs['p_correl'] nrow_i = kwargs['nrow_i'] ncol_i = kwargs['ncol_i'] amps = get_amp_list(ccd) for i, amp in enumerate(amps): regions = get_geom_regions(ccd, amp) image = get_raw_image(ccd, amp) frames = get_image_frames_2d(image, regions) del_i_array = frames['imaging'] - ref_frames[i]['imaging'] del_s_array = frames['serial_overscan'] - ref_frames[i][ 'serial_overscan'] del_p_array = frames['parallel_overscan'] - ref_frames[i][ 'parallel_overscan'] dd_s = del_s_array.mean(1)[0:nrow_i] - del_i_array.mean(1) dd_p = del_p_array.mean(0)[0:ncol_i] - del_i_array.mean(0) mask_s = np.fabs(dd_s) < self.clip_value mask_p = np.fabs(dd_p) < self.clip_value s_correl[i, ifile - 1] = np.corrcoef( del_s_array.mean(1)[0:nrow_i][mask_s], dd_s[mask_s])[0, 1] p_correl[i, ifile - 1] = np.corrcoef( del_p_array.mean(0)[0:ncol_i][mask_p], dd_p[mask_p])[0, 1]
def get_ccd_data(self, butler, ccd, **kwargs): """Get the serial overscan data Parameters ---------- butler : `Butler` The data butler ccd : `MaskedCCD` The ccd we are getting data from data : `dict` The data we are updating Keywords -------- superbias_frame : `MaskedCCD` The superbias frame to subtract away boundry : `int` Size of buffer around edge of overscan region Returns ------- overscans : `list` The overscan data """ amps = get_amp_list(ccd) superbias_frame = kwargs.get('superbias_frame', None) overscans = [] for amp in amps: superbias_im = self.get_superbias_amp_image(butler, superbias_frame, amp) regions = get_geom_regions(ccd, amp) serial_oscan = regions['serial_overscan'] img = get_raw_image(ccd, amp) image = unbias_amp(img, serial_oscan, bias_type=None, superbias_im=superbias_im).image oscan_copy = copy.deepcopy(serial_oscan) oscan_copy.grow(-self.boundry) oscan_data = image[oscan_copy] step_x = regions['step_x'] step_y = regions['step_y'] overscans.append(oscan_data.getArray()[::step_x, ::step_y]) return overscans
def unbias(input_file, output_file, bias_method, bias_method_col=None, superbias_file=None): # build output file by copying input shutil.copyfile(input_file, output_file) ccd = get_ccd_from_id(None, input_file, []) hdulist = fits.open(input_file) if superbias_file is not None: superbias_ccd = get_ccd_from_id(None, superbias_file, []) else: superbias_ccd = None amps = get_amp_list(ccd) offset = get_amp_offset(ccd, superbias_ccd) for i, amp in enumerate(amps): regions = get_geom_regions(ccd, amp) serial_oscan = regions['serial_overscan'] parallel_oscan = regions['parallel_overscan'] img = get_raw_image(ccd, amp) if superbias_ccd is not None: superbias_im = get_raw_image(superbias_frame, amp + offset) else: superbias_im = None image = unbias_amp(img, serial_oscan, bias_type=bias_method, superbias_im=superbias_im, bias_type_col=bias_method_col, parallel_oscan=parallel_oscan) fits.update(output_file, image.image.array, amp, header=hdulist[amp].header)
def extract(self, butler, data, **kwargs): """Extract data Parameters ---------- butler : `Butler` The data butler data : `dict` Dictionary (or other structure) contain the input data kwargs Used to override default configuration Returns ------- dtables : `TableDict` Output data tables """ self.safe_update(**kwargs) slot = self.config.slot qe_files = data['LAMBDA'] lams = [] for file in qe_files: lam = file.split('flat_')[1].split('_')[0] lams.append(lam) mask_files = self.get_mask_files() superbias_frame = self.get_superbias_frame(mask_files) bias_type = self.get_bias_algo() self.log_info_slot_msg(self.config, "%i files" % len(qe_files)) sflat_table_file = self.get_filename_from_format(RAFT_SFLAT_TABLE_FORMATTER, "sflat.fits") sflat_tables = TableDict(sflat_table_file) bbox_dict = construct_bbox_dict(sflat_tables['defects']) slot_bbox_dict = bbox_dict[slot] # This is a dictionary of dictionaries to store all the # data you extract from the qe_files data_dict = dict(SLOT=[], AMP=[], XCORNER=[], YCORNER=[], XSIZE=[], YSIZE=[]) for lam in lams: data_dict['FLUX_' + lam] = [] data_dict['MED_' + lam] = [] temp_list = [] # Analysis goes here, you should fill data_dict with data extracted # by the analysis # # For this slot, loop over qe files, loop over amplifiers, loop over dust spots in that amplifier, # record the flux and median for each dust spot # Then loop over dust spots CCDs, amplifiers, and QE files to accumulate the output dictionary ccd = self.get_ccd(butler, qe_files[0], mask_files) amps = get_amp_list(ccd) spot = 0 for ifile, qe_file in enumerate(qe_files): lam = qe_file.split('flat_')[1].split('_')[0] for i, amp in enumerate(amps): bbox_list = slot_bbox_dict[amp] if len(bbox_list) > 100: if i == 0: self.log.warn("Skipping slot:amp %s:%i with %i defects" % (slot, amp, len(bbox_list))) continue ccd = self.get_ccd(butler, qe_file, mask_files) regions = get_geom_regions(ccd, amp) serial_oscan = regions['serial_overscan'] imaging = regions['imaging'] img = get_raw_image(ccd, amp) if superbias_frame is not None: if butler is not None: superbias_im = get_raw_image(superbias_frame, amp) else: superbias_im = get_raw_image(superbias_frame, amp) else: superbias_im = None image = unbias_amp(img, serial_oscan, bias_type=bias_type, superbias_im=superbias_im, region=imaging) for bbox in bbox_list: if ifile == 0: data_dict['SLOT'].append(slot) #data_dict['LAM'].append(lam) data_dict['AMP'].append(amp) data_dict['XCORNER'].append(bbox.getBeginX()) data_dict['YCORNER'].append(bbox.getBeginY()) data_dict['XSIZE'].append(bbox.getWidth()) data_dict['YSIZE'].append(bbox.getHeight()) try: cutout = image[bbox] except Exception: pass # Here evaluate the 'flux' of the feature, relative to the median # value of the amplifier image. May also want to assemble bounding # box corners into a ds9 region file, CCD by CCD med = np.median(image.array) flux = np.sum(cutout.array) - bbox.getWidth()*bbox.getHeight()*med spot += 1 #temp_dict[spot].append((lam, flux, med)) temp_list.append((lam, flux, med)) for i, tmp_data in enumerate(temp_list): #data_dict['SLOT'].append(temp_dict['SLOT'][i]) #data_dict['AMP'].append(temp_dict['AMP'][i]) #lam = temp_dict['LAM'][i] lam, flux, med = tmp_data data_dict['FLUX_' + lam].append(flux) #temp_dict['FLUX'][i]) data_dict['MED_' + lam].append(med) #np.median(image.array)) sys.stdout.write("!\n") sys.stdout.flush() dtables = TableDict() dtables.make_datatable('files', make_file_dict(butler, qe_files)) #dtables.make_datatable('dust_color', data_dict) dtables.make_datatable('dust_color_hack', data_dict) return dtables
def extract(self, butler, data, **kwargs): """Extract data Parameters ---------- butler : `Butler` The data butler data : `dict` Dictionary (or other structure) contain the input data kwargs Used to override default configuration Returns ------- dtables : `TableDict` output data tables """ self.safe_update(**kwargs) slots = self.config.slots if slots is None: slots = ALL_SLOTS if butler is not None: self.log.warn("Ignoring butler") dark_current_data = dict(median=[], stdev=[], mean=[], fit_mean=[], fit_width=[], fit_dof=[], fit_chi2=[], exptime=[], current=[], slot=[], amp=[]) self.log_info_raft_msg(self.config, "") for islot, slot in enumerate(slots): self.log_progress(" %s" % slot) mask_files = self.get_mask_files(slot=slot) superdark_file = data[slot] if not os.path.exists(superdark_file): self.log.warn(" %s does not exist, skipping" % superdark_file) continue superdark_frame = self.get_ccd(None, superdark_file, mask_files) exptime = get_exposure_time(superdark_frame) amps = get_amp_list(superdark_frame) for iamp, amp in enumerate(amps): regions = get_geom_regions(superdark_frame, amp) imaging = regions['imaging'] superdark_im = get_raw_image(superdark_frame, amp).image image_data = superdark_im[imaging].array median = np.median(image_data) stdev = np.std(image_data) hist_bins = np.linspace(median - 5 * stdev, median + 5 * stdev, 101) hist = np.histogram(image_data, bins=hist_bins) fit_result = gauss_fit(hist) fit_pars = fit_result[0] dark_current_data['median'].append(median) dark_current_data['stdev'].append(stdev) dark_current_data['mean'].append(np.mean(image_data)) dark_current_data['fit_mean'].append(fit_pars[1]) dark_current_data['fit_width'].append(fit_pars[2]) dark_current_data['fit_dof'].append(0.) dark_current_data['fit_chi2'].append(0.) dark_current_data['exptime'].append(exptime) dark_current_data['current'].append(median/exptime) dark_current_data['slot'].append(islot) dark_current_data['amp'].append(iamp) self.log_progress("Done!") dtables = TableDict() dtables.make_datatable('dark_current', dark_current_data) return dtables
def extract(self, butler, data, **kwargs): """Extract the correlations between the imaging section and the overscan regions in a series of bias frames Parameters ---------- butler : `Butler` The data butler data : `dict` Dictionary (or other structure) contain the input data kwargs Used to override default configuration Returns ------- dtables : `TableDict` The resulting data """ self.safe_update(**kwargs) bias_files = data['BIAS'] mask_files = self.get_mask_files() self.log_info_slot_msg(self.config, "%i files" % len(bias_files)) ref_frames = {} nfiles = len(bias_files) s_correl = np.ndarray((16, nfiles - 1)) p_correl = np.ndarray((16, nfiles - 1)) for ifile, bias_file in enumerate(bias_files): if ifile % 10 == 0: self.log_progress(" %i" % ifile) ccd = self.get_ccd(butler, bias_file, mask_files) if ifile == 0: dims = get_dims_from_ccd(ccd) nrow_i = dims['nrow_i'] ncol_i = dims['ncol_i'] amps = get_amp_list(ccd) for i, amp in enumerate(amps): regions = get_geom_regions(ccd, amp) image = get_raw_image(ccd, amp) ref_frames[i] = get_image_frames_2d(image, regions) continue self.get_ccd_data(ccd, ref_frames, ifile=ifile, s_correl=s_correl, p_correl=p_correl, nrow_i=nrow_i, ncol_i=ncol_i) self.log_progress("Done!") data = {} for i in range(16): data['s_correl_a%02i' % i] = s_correl[i] data['p_correl_a%02i' % i] = p_correl[i] dtables = TableDict() dtables.make_datatable('files', make_file_dict(butler, bias_files)) dtables.make_datatable("correl", data) return dtables
def get_ccd_data(self, ccd, data, **kwargs): """Get the bias values and update the data dictionary Parameters ---------- ccd : `MaskedCCD` The ccd we are getting data from data : `dict` The data we are updating Keywords -------- slot : `str` The slot name ifile : `int` The file index nfiles_used : `int` Total number of files bias_type : `str` Method to use to construct bias std : `bool` Used standard deviation instead of mean superbias_frame : `MaskedCCD` The superbias frame to subtract away """ nfiles_used = kwargs.get('nfiles_used', 1) ifile = kwargs.get('ifile', 0) slot = kwargs.get('slot') superbias_frame = kwargs.get('superbias_frame', None) offset = get_amp_offset(ccd, superbias_frame) bias_type = self.get_bias_algo() bias_type_col = self.get_bias_col_algo() amps = get_amp_list(ccd) for i, amp in enumerate(amps): regions = get_geom_regions(ccd, amp) serial_oscan = regions['serial_overscan'] parallel_oscan = regions['parallel_overscan'] img = get_raw_image(ccd, amp) if superbias_frame is not None: superbias_im = get_raw_image(superbias_frame, amp + offset) else: superbias_im = None image = unbias_amp(img, serial_oscan, bias_type=bias_type, bias_type_col=bias_type_col, superbias_im=superbias_im, parallel_oscan=parallel_oscan) frames = get_image_frames_2d(image, regions) for key, region in zip(REGION_KEYS, REGION_NAMES): framekey_row = "row_%s" % key framekey_col = "col_%s" % key struct = array_struct(frames[region], do_std=self.config.std) key_str = "biasst_%s_a%02i" % (slot, i) if key_str not in data[framekey_row]: data[framekey_row][key_str] = np.ndarray( (len(struct['rows']), nfiles_used)) if key_str not in data[framekey_col]: data[framekey_col][key_str] = np.ndarray( (len(struct['cols']), nfiles_used)) data[framekey_row][key_str][:, ifile] = struct['rows'] data[framekey_col][key_str][:, ifile] = struct['cols']