def test_simple_corr(self): print("Testing simple corr") nn=12 x1=np.random.uniform(size=nn)-0.5 y1=np.random.uniform(size=nn)-0.5 # arb. angle a=10./180.*np.pi ca=np.cos(a) sa=np.sin(a) # arb. dilatation xscale = 12. yscale = 13. x3 = xscale*ca*x1 + yscale*sa*y1 y3 = -xscale*sa*x1 + yscale*ca*y1 # arb. translation x3 += 33. y3 += 11. corr31=SimpleCorr() corr31.fit(x3,y3,x1,y1) x3b,y3b=corr31.apply(x3,y3) dist=np.sqrt((x3b-x1)**2+(y3b-y1)**2) assert(np.all(dist<1e-6)) print("Testing inverse") x1b,y1b=corr31.apply_inverse(x1,y1) dist=np.sqrt((x1b-x3)**2+(y1b-y3)**2) assert(np.all(dist<1e-6))
def fit_gfa2fp(metrology): """ Fit GFA pix -> FP mm scale, rotation, xyoffsets for each GFA Returns dict keyed by PETAL_LOC, with dictionaries of transform coeffs. """ #- HARDCODE: GFA pixel dimensions nx, ny = 2048, 1032 #- Trim to just GFA entries without altering input table gfarows = (metrology['DEVICE_TYPE'] == 'GFA') metrology = metrology[gfarows] metrology.sort(['PETAL_LOC', 'PINHOLE_ID']) #- Metrology corners start at (0,0) for middle of pixel #- Thankfully this is consistent with gfa_reduce, desimeter fvc spots, #- and the Unified Metrology Table in DESI-5421 xgfa = np.array([0, nx-1, nx-1, 0]) ygfa = np.array([0, 0, ny-1, ny-1]) gfa_transforms = dict() for p in range(10): ii = (metrology['PETAL_LOC'] == p) if np.count_nonzero(ii) > 0: xfp = np.asarray(metrology['X_FP'][ii]) yfp = np.asarray(metrology['Y_FP'][ii]) zfp = np.asarray(metrology['Z_FP'][ii]) #- fit transform corr = SimpleCorr() corr.fit(xgfa, ygfa, xfp, yfp) #- measure norm of plane x01 = np.array( [ xfp[1]-xfp[0], yfp[1]-yfp[0], zfp[1]-zfp[0] ] ) x01 /= np.sqrt(np.sum(x01**2)) x12 = np.array( [ xfp[2]-xfp[1], yfp[2]-yfp[1], zfp[2]-zfp[1] ] ) x12 /= np.sqrt(np.sum(x12**2)) norm_vector= np.cross(x01,x12) # I checked the sign of all components # The guide CCDs are about 2.23 mm below the focal surface # because of the filter of thickness 5.03+-0.01 mm # and refractive index 1.805 to 1.791 from 578nm to 706nm # see DESI-5336, https://desi.lbl.gov/DocDB/cgi-bin/private/ShowDocument?docid=5336 # there is a correction to apply because the focal surface is curved #- compute correction to apply delta_z = 2.23 # mm delta_x = delta_z*norm_vector[0]/norm_vector[2] delta_y = delta_z*norm_vector[1]/norm_vector[2] #- apply correction to offsets corr.dx += delta_x corr.dy += delta_y gfa_transforms[p] = corr return gfa_transforms
def fit_gfa2fp(metrology): """ Fit GFA pix -> FP mm scale, rotation, xyoffsets for each GFA Returns dict keyed by PETAL_LOC, with dictionaries of transform coeffs. """ #- HARDCODE: GFA pixel dimensions nx, ny = 2048, 1032 #- Trim to just GFA entries without altering input table gfarows = (metrology['DEVICE_TYPE'] == 'GFA') metrology = metrology[gfarows] metrology.sort(['PETAL_LOC', 'PINHOLE_ID']) #- Metrology corners start at (0,0) for middle of pixel #- Thankfully this is consistent with gfa_reduce, desimeter fvc spots, #- and the Unified Metrology Table in DESI-5421 xgfa = np.array([0, nx-1, nx-1, 0]) ygfa = np.array([0, 0, ny-1, ny-1]) gfa_transforms = dict() for p in range(10): ii = (metrology['PETAL_LOC'] == p) if np.count_nonzero(ii) > 0: xfp = np.asarray(metrology['X_FP'][ii]) yfp = np.asarray(metrology['Y_FP'][ii]) zfp = np.asarray(metrology['Z_FP'][ii]) #- fit transform corr = SimpleCorr() corr.fit(xgfa, ygfa, xfp, yfp) #- measure norm of plane x01 = np.array( [ xfp[1]-xfp[0], yfp[1]-yfp[0], zfp[1]-zfp[0] ] ) x01 /= np.sqrt(np.sum(x01**2)) x12 = np.array( [ xfp[2]-xfp[1], yfp[2]-yfp[1], zfp[2]-zfp[1] ] ) x12 /= np.sqrt(np.sum(x12**2)) norm_vector= np.cross(x01,x12) # I checked the sign of all components #- compute correction to apply delta_z = 2.23 # mm delta_x = delta_z*norm_vector[0]/norm_vector[2] delta_y = delta_z*norm_vector[1]/norm_vector[2] #- apply correction to offsets corr.dx += delta_x corr.dy += delta_y gfa_transforms[p] = corr return gfa_transforms
def findfiducials(spots, input_transform=None, pinhole_max_separation_mm=1.5): global metrology_pinholes_table global metrology_fiducials_table log = get_logger() log.debug( "load input tranformation we will use to go from FP to FVC pixels") if input_transform is None: input_transform = fvc2fp_filename() log.info("loading input tranform from {}".format(input_transform)) input_tx = FVC2FP.read_jsonfile(input_transform) xpix = np.array([ 2000., ]) ypix = np.array([ 0., ]) xfp1, yfp1 = input_tx.fvc2fp(xpix, ypix) xfp2, yfp2 = input_tx.fvc2fp(xpix + 1, ypix) pixel2fp = np.hypot(xfp2 - xfp1, yfp2 - yfp1)[0] # mm pinhole_max_separation_pixels = pinhole_max_separation_mm / pixel2fp log.info( "with pixel2fp = {:4.3f} mm, pinhole max separation = {:4.3f} pixels ". format(pixel2fp, pinhole_max_separation_pixels)) if metrology_pinholes_table is None: metrology_table = load_metrology() log.debug("keep only the pinholes") metrology_pinholes_table = metrology_table[:][ (metrology_table["DEVICE_TYPE"] == "FIF") | (metrology_table["DEVICE_TYPE"] == "GIF")] # use input transform to convert X_FP,Y_FP to XPIX,YPIX xpix, ypix = input_tx.fp2fvc(metrology_pinholes_table["X_FP"], metrology_pinholes_table["Y_FP"]) metrology_pinholes_table["XPIX"] = xpix metrology_pinholes_table["YPIX"] = ypix log.debug("define fiducial location as the most central dot") central_pinholes = [] for loc in np.unique(metrology_pinholes_table["LOCATION"]): ii = np.where(metrology_pinholes_table["LOCATION"] == loc)[0] mx = np.mean(metrology_pinholes_table["XPIX"][ii]) my = np.mean(metrology_pinholes_table["YPIX"][ii]) k = np.argmin((metrology_pinholes_table["XPIX"][ii] - mx)**2 + (metrology_pinholes_table["YPIX"][ii] - my)**2) central_pinholes.append(ii[k]) metrology_fiducials_table = metrology_pinholes_table[:][ central_pinholes] # find fiducials candidates log.info("select spots with at least two close neighbors (in pixel units)") nspots = spots["XPIX"].size xy = np.array([spots["XPIX"], spots["YPIX"]]).T tree = KDTree(xy) measured_spots_distances, measured_spots_indices = tree.query( xy, k=4, distance_upper_bound=pinhole_max_separation_pixels) number_of_neighbors = np.sum( measured_spots_distances < pinhole_max_separation_pixels, axis=1) fiducials_candidates_indices = np.where( number_of_neighbors >= 4)[0] # including self, so at least 3 pinholes log.debug("number of fiducials=", fiducials_candidates_indices.size) # match candidates to fiducials from metrology log.info( "first match {} fiducials candidates to metrology ({}) with iterative fit" .format(fiducials_candidates_indices.size, len(metrology_fiducials_table))) x1 = spots["XPIX"][fiducials_candidates_indices] y1 = spots["YPIX"][fiducials_candidates_indices] x2 = metrology_fiducials_table["XPIX"] y2 = metrology_fiducials_table["YPIX"] nloop = 20 saved_median_distance = 0 for loop in range(nloop): indices_2, distances = match_same_system(x1, y1, x2, y2) mdist = np.median(distances[indices_2 >= 0]) if loop < nloop - 1: maxdistance = max(10, 3. * 1.4 * mdist) else: # final iteration maxdistance = 10 # pixel selection = np.where((indices_2 >= 0) & (distances < maxdistance))[0] log.info("iter #{} median_dist={} max_dist={} matches={}".format( loop, mdist, maxdistance, selection.size)) corr21 = SimpleCorr() corr21.fit(x2[indices_2[selection]], y2[indices_2[selection]], x1[selection], y1[selection]) x2, y2 = corr21.apply(x2, y2) if np.abs(saved_median_distance - mdist) < 0.0001: break # no more improvement saved_median_distance = mdist # use same coord system match (note we now match the otherway around) indices_1, distances = match_same_system(x2, y2, x1, y1) maxdistance = 10. # FVC pixels selection = np.where((indices_1 >= 0) & (distances < maxdistance))[0] fiducials_candidates_indices = fiducials_candidates_indices[ indices_1[selection]] matching_known_fiducials_indices = selection log.debug( "mean distance = {:4.2f} pixels for {} matched and {} known fiducials". format(np.mean(distances[distances < maxdistance]), fiducials_candidates_indices.size, metrology_fiducials_table["XPIX"].size)) log.debug("now matching pinholes ...") nspots = spots["XPIX"].size for k in ['LOCATION', 'PETAL_LOC', 'DEVICE_LOC', 'PINHOLE_ID']: if k not in spots.dtype.names: spots.add_column(Column(np.zeros(nspots, dtype=int)), name=k) spots["LOCATION"][:] = -1 spots["PETAL_LOC"][:] = -1 spots["DEVICE_LOC"][:] = -1 spots["PINHOLE_ID"][:] = 0 for index1, index2 in zip(fiducials_candidates_indices, matching_known_fiducials_indices): location = metrology_fiducials_table["LOCATION"][index2] # get indices of all pinholes for this matched fiducial # note we now use the full pinholes metrology table pi1 = measured_spots_indices[index1][ measured_spots_distances[index1] < pinhole_max_separation_pixels] pi2 = np.where(metrology_pinholes_table["LOCATION"] == location)[0] x1 = spots["XPIX"][pi1] y1 = spots["YPIX"][pi1] x2 = metrology_pinholes_table["XPIX"][pi2] y2 = metrology_pinholes_table["YPIX"][pi2] indices_2, distances = match_arbitrary_translation_dilatation( x1, y1, x2, y2) metrology_pinhole_ids = metrology_pinholes_table["PINHOLE_ID"][pi2] pinhole_ids = np.zeros(x1.size, dtype=int) matched = (indices_2 >= 0) pinhole_ids[matched] = metrology_pinhole_ids[indices_2[matched]] spots["LOCATION"][pi1[matched]] = location spots["PINHOLE_ID"][pi1[matched]] = pinhole_ids[matched] if np.sum(pinhole_ids == 0) > 0: log.warning( "only matched pinholes {} for {} detected at LOCATION {} xpix~{} ypix~{}" .format(pinhole_ids[pinhole_ids > 0], x1.size, location, int(np.mean(x1)), int(np.mean(y1)))) # check duplicates if np.unique( pinhole_ids[pinhole_ids > 0]).size != np.sum(pinhole_ids > 0): xfp = np.mean(metrology_pinholes_table[pi2]["X_FP"]) yfp = np.mean(metrology_pinholes_table[pi2]["Y_FP"]) log.warning( "duplicate(s) pinhole ids in {} at LOCATION={} xpix~{} ypix~{} xfp~{} yfp~{}" .format(pinhole_ids, location, int(np.mean(x1)), int(np.mean(y1)), int(xfp), int(yfp))) bc = np.bincount(pinhole_ids[pinhole_ids > 0]) duplicates = np.where(bc > 1)[0] for duplicate in duplicates: log.warning( "Unmatch ambiguous pinhole id = {}".format(duplicate)) selection = (spots["LOCATION"] == location) & (spots["PINHOLE_ID"] == duplicate) spots["PINHOLE_ID"][selection] = 0 ii = (spots["LOCATION"] >= 0) spots["PETAL_LOC"][ii] = spots["LOCATION"][ii] // 1000 spots["DEVICE_LOC"][ii] = spots["LOCATION"][ii] % 1000 n_matched_pinholes = np.sum(spots["PINHOLE_ID"] > 0) n_matched_fiducials = np.sum(spots["PINHOLE_ID"] == 4) log.info("matched {} pinholes from {} fiducials".format( n_matched_pinholes, n_matched_fiducials)) return spots
def average_coordinates(tables,xkey,ykey) : """ Average x,y coordinates given by xkey and ykey from a list of astropy tables and return an astropy table with the average coordinates. This function includes a match and a transformation per table. The tables do not necessarily have the same number of entries (in case of false detections). Args tables: list of astropy.Table objects with same columns Returns astropy.Table with same columns as input """ table1=None x1=None y1=None indices=None xx=[] yy=[] for table in tables : x2=np.array(table[xkey]) y2=np.array(table[ykey]) if x1 is None : table1=table x1=x2 y1=y2 indices=np.arange(len(x1),dtype=int) else : # match the two sets of spots indices_1 = np.arange(len(x1),dtype=int) indices_2, distances = match_same_system(x1,y1,x2,y2) ok=np.where((indices_2>=0)&(distances<5.))[0] indices_1 = indices_1[ok] indices_2 = indices_2[ok] distances = distances[ok] x1=x1[indices_1] y1=y1[indices_1] indices=indices[indices_1] x2=x2[indices_2] y2=y2[indices_2] n=len(xx) for i in range(n) : xx[i]=xx[i][indices_1] yy[i]=yy[i][indices_1] # adjust a possible transfo between the two FVC images corr=SimpleCorr() corr.fit(x2,y2,x1,y1) x2,y2=corr.apply(x2,y2) xx.append(x2) yy.append(y2) xx=np.vstack(xx) yy=np.vstack(yy) xrms=np.std(xx,axis=0) yrms=np.std(yy,axis=0) mx=np.mean(xx,axis=0) my=np.mean(yy,axis=0) table1[xkey][indices]=mx table1[ykey][indices]=my print("number of entries found in all tables= {}".format(indices.size)) print("rms({})= {:4.3f}".format(xkey,np.median(xrms))) print("rms({})= {:4.3f}".format(ykey,np.median(yrms))) return table1
def findfiducials(spots, input_transform=None, separation=8.): global metrology_pinholes_table global metrology_fiducials_table log = get_logger() log.debug( "load input tranformation we will use to go from FP to FVC pixels") if input_transform is None: input_transform = resource_filename('desimeter', "data/single-lens-fvc2fp.json") log.info("loading input tranform from {}".format(input_transform)) try: input_tx = FVCFP_ZhaoBurge.read_jsonfile(input_transform) except AssertionError as e: log.warning( "Failed to read input transfo as Zhao Burge, try polynomial...") input_tx = FVCFP_Polynomial.read_jsonfile(input_transform) if metrology_pinholes_table is None: filename = resource_filename('desimeter', "data/fp-metrology.csv") if not os.path.isfile(filename): log.error("cannot find {}".format(filename)) raise IOError("cannot find {}".format(filename)) log.info("reading metrology in {}".format(filename)) metrology_table = Table.read(filename, format="csv") log.debug("keep only the pinholes") metrology_pinholes_table = metrology_table[:][ metrology_table["PINHOLE_ID"] > 0] # use input transform to convert X_FP,Y_FP to XPIX,YPIX xpix, ypix = input_tx.fp2fvc(metrology_pinholes_table["X_FP"], metrology_pinholes_table["Y_FP"]) metrology_pinholes_table["XPIX"] = xpix metrology_pinholes_table["YPIX"] = ypix log.debug("define fiducial location as central dot") metrology_fiducials_table = metrology_pinholes_table[:][ metrology_pinholes_table["PINHOLE_ID"] == 4] # find fiducials candidates log.info("select spots with at least two close neighbors (in pixel units)") xy = np.array([spots["XPIX"], spots["YPIX"]]).T tree = KDTree(xy) measured_spots_distances, measured_spots_indices = tree.query( xy, k=4, distance_upper_bound=separation) number_of_neighbors = np.sum(measured_spots_distances < separation, axis=1) fiducials_candidates_indices = np.where( number_of_neighbors >= 3)[0] # including self, so at least 3 pinholes # match candidates to fiducials from metrology log.info( "first match {} fiducials candidates to metrology ({}) with iterative fit" .format(fiducials_candidates_indices.size, len(metrology_fiducials_table))) x1 = spots["XPIX"][fiducials_candidates_indices] y1 = spots["YPIX"][fiducials_candidates_indices] x2 = metrology_fiducials_table["XPIX"] # do I need to do this? y2 = metrology_fiducials_table["YPIX"] nloop = 20 saved_median_distance = 0 for loop in range(nloop): indices_2, distances = match_same_system(x1, y1, x2, y2) mdist = np.median(distances[indices_2 >= 0]) if loop < nloop - 1: maxdistance = max(10, 3. * 1.4 * mdist) else: # final iteration maxdistance = 10 # pixel selection = np.where((indices_2 >= 0) & (distances < maxdistance))[0] log.info("iter #{} median_dist={} max_dist={} matches={}".format( loop, mdist, maxdistance, selection.size)) corr21 = SimpleCorr() corr21.fit(x2[indices_2[selection]], y2[indices_2[selection]], x1[selection], y1[selection]) x2, y2 = corr21.apply(x2, y2) if np.abs(saved_median_distance - mdist) < 0.0001: break # no more improvement saved_median_distance = mdist # use same coord system match (note we now match the otherway around) indices_1, distances = match_same_system(x2, y2, x1, y1) maxdistance = 10. # FVC pixels selection = np.where((indices_1 >= 0) & (distances < maxdistance))[0] fiducials_candidates_indices = fiducials_candidates_indices[ indices_1[selection]] matching_known_fiducials_indices = selection log.debug( "mean distance = {:4.2f} pixels for {} matched and {} known fiducials". format(np.mean(distances[distances < maxdistance]), fiducials_candidates_indices.size, metrology_fiducials_table["XPIX"].size)) log.debug("now matching pinholes ...") nspots = spots["XPIX"].size if 'LOCATION' not in spots.dtype.names: spots.add_column(Column(np.zeros(nspots, dtype=int)), name='LOCATION') if 'PINHOLE_ID' not in spots.dtype.names: spots.add_column(Column(np.zeros(nspots, dtype=int)), name='PINHOLE_ID') for index1, index2 in zip(fiducials_candidates_indices, matching_known_fiducials_indices): location = metrology_fiducials_table["LOCATION"][index2] # get indices of all pinholes for this matched fiducial # note we now use the full pinholes metrology table pi1 = measured_spots_indices[index1][ measured_spots_distances[index1] < separation] pi2 = np.where(metrology_pinholes_table["LOCATION"] == location)[0] x1 = spots["XPIX"][pi1] y1 = spots["YPIX"][pi1] x2 = metrology_pinholes_table["XPIX"][pi2] y2 = metrology_pinholes_table["YPIX"][pi2] indices_2, distances = match_arbitrary_translation_dilatation( x1, y1, x2, y2) metrology_pinhole_ids = metrology_pinholes_table["PINHOLE_ID"][pi2] pinhole_ids = np.zeros(x1.size, dtype=int) matched = (indices_2 >= 0) pinhole_ids[matched] = metrology_pinhole_ids[indices_2[matched]] spots["LOCATION"][pi1[matched]] = location spots["PINHOLE_ID"][pi1[matched]] = pinhole_ids[matched] if np.sum(pinhole_ids == 0) > 0: log.warning( "only matched pinholes {} for {} detected at LOCATION {} xpix~{} ypix~{}" .format(pinhole_ids[pinhole_ids > 0], x1.size, location, int(np.mean(x1)), int(np.mean(y1)))) # check duplicates if np.unique( pinhole_ids[pinhole_ids > 0]).size != np.sum(pinhole_ids > 0): xfp = np.mean(metrology_pinholes_table[pi2]["X_FP"]) yfp = np.mean(metrology_pinholes_table[pi2]["Y_FP"]) log.warning( "duplicate(s) pinhole ids in {} at LOCATION={} xpix~{} ypix~{} xfp~{} yfp~{}" .format(pinhole_ids, location, int(np.mean(x1)), int(np.mean(y1)), int(xfp), int(yfp))) bc = np.bincount(pinhole_ids[pinhole_ids > 0]) duplicates = np.where(bc > 1)[0] for duplicate in duplicates: log.warning( "Unmatch ambiguous pinhole id = {}".format(duplicate)) selection = (spots["LOCATION"] == location) & (spots["PINHOLE_ID"] == duplicate) spots["PINHOLE_ID"][selection] = 0 spots["PETAL_LOC"] = spots["LOCATION"] // 1000 spots["DEVICE_LOC"] = spots["LOCATION"] % 1000 n_matched_pinholes = np.sum(spots["PINHOLE_ID"] > 0) n_matched_fiducials = np.sum(spots["PINHOLE_ID"] == 4) log.info("matched {} pinholes from {} fiducials".format( n_matched_pinholes, n_matched_fiducials)) return spots