def _compute_zenith_angle(self, latitude, lst, ra, dec): """ Compute the zenith angle for one or many ra/dec. Parameters ---------- latitude : `float` Observatory latitude (degrees) lst : `float` Local sidereal time (degrees) ra : `np.ndarray` Right ascension dec : `np.ndarray` Declination Returns ------- zenith : `np.ndarray` Zenith angle(s) in radians """ c_ra = ra * coord.degrees c_dec = dec * coord.degrees c_ha = (lst - ra) * coord.degrees c_lat = latitude * coord.degrees c_zenith = coord.CelestialCoord(c_ha + c_ra, c_lat) c_pointing = coord.CelestialCoord(c_ra, c_dec) zenith_angle = c_pointing.distanceTo(c_zenith).rad return zenith_angle
def _compute_zenith_and_par_angles(self, lst, ra, dec): """ Compute the zenith angle for a given ra/dec Parameters ---------- lst : `float` Local sidereal time (degrees) ra : `float` RA in degrees dec : `float` Dec in degrees Returns ------- zenith_angle : `float` Zenith angle in radians. parallactic_angle : `float`, optional Parallactic angle in radians. """ c_ra = ra * coord.degrees c_dec = dec * coord.degrees c_ha = (lst - ra) * coord.degrees c_lat = self.config.latitude * coord.degrees c_zenith = coord.CelestialCoord(c_ha + c_ra, c_lat) c_pointing = coord.CelestialCoord(c_ra, c_dec) zenith_angle = c_pointing.distanceTo(c_zenith).rad c_NCP = coord.CelestialCoord(0.0 * coord.degrees, 90.0 * coord.degrees) parallactic_angle = c_pointing.angleBetween(c_NCP, c_zenith).rad return zenith_angle, parallactic_angle
def test_coord(): pole = coord.CelestialCoord(0. * coord.degrees, 90. * coord.degrees) u = np.random.uniform(-0.5, 0.5, size=10000) v = np.random.uniform(-0.5, 0.5, size=10000) for projection in ['gnomonic', 'stereographic', 'postel', 'lambert']: ra, dec = pole.deproject_rad(u, v, projection=projection) xcos, ycos, zcos = batoid.utils.fieldToDirCos(u, v, projection=projection) np.testing.assert_allclose(-np.sin(dec), zcos, rtol=0, atol=1e-13) np.testing.assert_allclose(np.abs((np.pi / 2 - ra) - np.arctan2(ycos, xcos)), np.pi, rtol=0, atol=1e-13)
def bestPA(world_pos, date): """ This routine determines the best position angle for the observatory for a given observation date and position on the sky. The best/optimal position angle is determined by the fact that the solar panels are at 90 degrees to the position being observed, and it is best to have those facing the Sun as directly as possible. Note that if a given ``world_pos`` is not actually observable on the given ``date``, then this routine will return None. Parameters: world_pos: A galsim.CelestialCoord indicating the position at which the observer wishes to look. date: A python datetime object indicating the desired date of observation. Returns: the best position angle for the observatory, as a galsim.Angle, or None if the position is not observable. """ # First check for observability. if not allowedPos(world_pos, date): return None # Find the location of the sun on this date. +X_observatory points out into the sky, towards # world_pos, while +Z is in the plane of the sky pointing towards the sun as much as possible. lam = coord.util.sun_position_ecliptic(date) sun = coord.CelestialCoord.from_ecliptic(lam, 0 * coord.radians, date.year) # Now we do a projection onto the sky centered at world_pos to find the (u, v) for the Sun. sun_tp_x, sun_tp_y = world_pos.project(sun, 'gnomonic') # We want to rotate around by 90 degrees to find the +Y obs direction. Specifically, we want # (+X, +Y, +Z)_obs to form a right-handed coordinate system. y_obs_tp_x, y_obs_tp_y = -sun_tp_y, sun_tp_x y_obs = world_pos.deproject(y_obs_tp_x, y_obs_tp_y, 'gnomonic') # Finally the observatory position angle is defined by the angle between +Y_observatory and the # celestial north pole. It is defined as position angle east of north. north = coord.CelestialCoord(y_obs.ra, 90. * coord.degrees) obs_pa = world_pos.angleBetween(y_obs, north) return obs_pa
def toSky(self, x, y): ''' Convert xy coordinates in the gnomonic project (in degrees) into ra, dec. ''' try: import coord pole = coord.CelestialCoord(self.pole_ra * coord.degrees, self.pole_dec * coord.degrees) deg_per_radian = coord.radians / coord.degrees # Coord wants these in radians, not degrees # Also, a - sign for x, since astropy uses +ra as +x direction. x /= -deg_per_radian y /= deg_per_radian # apply rotation if self.rotation != 0.: # TODO: I'm not sure if I have the sense of the rotation correct here. # The "complex wcs" test has PA = 0, so I wasn't able to test it. # There may be a sign error on the s terms. s, c = (self.rotation * coord.degrees).sincos() x, y = x * c - y * s, x * s + y * c # apply projection ra, dec = pole.deproject_rad(x, y, projection='gnomonic') ra *= deg_per_radian dec *= deg_per_radian return ra, dec except ImportError: if self.frame is None: self._set_frame() # Get the y and z components of unit-sphere coords, x on pole axis y, z = x, y y *= np.pi / 180. z *= np.pi / 180. temp = np.sqrt(1 + y * y + z * z) y /= temp z /= temp dec = np.arcsin(z) ra = np.arcsin(y / np.cos(dec)) coord = co.SkyCoord(ra, dec, unit='rad', frame=self.frame) return coord.icrs.ra.deg, coord.icrs.dec.deg
def test_coord(): rng = np.random.default_rng(57721566) import coord pole = coord.CelestialCoord(0. * coord.degrees, 90. * coord.degrees) u = rng.uniform(-0.5, 0.5, size=10000) v = rng.uniform(-0.5, 0.5, size=10000) for projection in ['gnomonic', 'stereographic', 'postel', 'lambert']: ra, dec = pole.deproject_rad(u, v, projection=projection) xcos, ycos, zcos = batoid.utils.fieldToDirCos(u, v, projection=projection) np.testing.assert_allclose(-np.sin(dec), zcos, rtol=0, atol=1e-13) np.testing.assert_allclose(np.abs((np.pi / 2 - ra) - np.arctan2(ycos, xcos)), np.pi, rtol=0, atol=1e-13) # Check invalid input with np.testing.assert_raises(ValueError): batoid.utils.fieldToDirCos(u, v, projection="banana") with np.testing.assert_raises(ValueError): batoid.utils.dirCosToField(u, v, v, projection="banana")
def test_direct_spherical(): # Repeat in spherical coords ngal = 50 s = 10. rng = np.random.RandomState(8675309) x = rng.normal(0,s, (ngal,) ) y = rng.normal(0,s, (ngal,) ) + 200 # Put everything at large y, so small angle on sky z = rng.normal(0,s, (ngal,) ) w = rng.random_sample(ngal) g1 = rng.normal(0,0.2, (ngal,) ) g2 = rng.normal(0,0.2, (ngal,) ) w = np.ones_like(w) ra, dec = coord.CelestialCoord.xyz_to_radec(x,y,z) cat = treecorr.Catalog(ra=ra, dec=dec, ra_units='rad', dec_units='rad', w=w, g1=g1, g2=g2) min_sep = 1. bin_size = 0.2 nrbins = 10 nubins = 5 nvbins = 5 max_sep = min_sep * np.exp(nrbins * bin_size) ggg = treecorr.GGGCorrelation(min_sep=min_sep, bin_size=bin_size, nbins=nrbins, sep_units='deg', brute=True) ggg.process(cat) r = np.sqrt(x**2 + y**2 + z**2) x /= r; y /= r; z /= r north_pole = coord.CelestialCoord(0*coord.radians, 90*coord.degrees) true_ntri = np.zeros((nrbins, nubins, 2*nvbins), dtype=int) true_weight = np.zeros((nrbins, nubins, 2*nvbins), dtype=float) true_gam0 = np.zeros((nrbins, nubins, 2*nvbins), dtype=complex) true_gam1 = np.zeros((nrbins, nubins, 2*nvbins), dtype=complex) true_gam2 = np.zeros((nrbins, nubins, 2*nvbins), dtype=complex) true_gam3 = np.zeros((nrbins, nubins, 2*nvbins), dtype=complex) rad_min_sep = min_sep * coord.degrees / coord.radians rad_max_sep = max_sep * coord.degrees / coord.radians c = [coord.CelestialCoord(r*coord.radians, d*coord.radians) for (r,d) in zip(ra, dec)] for i in range(ngal): for j in range(i+1,ngal): for k in range(j+1,ngal): d12 = np.sqrt((x[i]-x[j])**2 + (y[i]-y[j])**2 + (z[i]-z[j])**2) d23 = np.sqrt((x[j]-x[k])**2 + (y[j]-y[k])**2 + (z[j]-z[k])**2) d31 = np.sqrt((x[k]-x[i])**2 + (y[k]-y[i])**2 + (z[k]-z[i])**2) d3, d2, d1 = sorted([d12, d23, d31]) rindex = np.floor(np.log(d2/rad_min_sep) / bin_size).astype(int) if rindex < 0 or rindex >= nrbins: continue if [d1, d2, d3] == [d23, d31, d12]: ii,jj,kk = i,j,k elif [d1, d2, d3] == [d23, d12, d31]: ii,jj,kk = i,k,j elif [d1, d2, d3] == [d31, d12, d23]: ii,jj,kk = j,k,i elif [d1, d2, d3] == [d31, d23, d12]: ii,jj,kk = j,i,k elif [d1, d2, d3] == [d12, d23, d31]: ii,jj,kk = k,i,j elif [d1, d2, d3] == [d12, d31, d23]: ii,jj,kk = k,j,i else: assert False # Now use ii, jj, kk rather than i,j,k, to get the indices # that correspond to the points in the right order. u = d3/d2 v = (d1-d2)/d3 if ( ((x[jj]-x[ii])*(y[kk]-y[ii]) - (x[kk]-x[ii])*(y[jj]-y[ii])) * z[ii] + ((y[jj]-y[ii])*(z[kk]-z[ii]) - (y[kk]-y[ii])*(z[jj]-z[ii])) * x[ii] + ((z[jj]-z[ii])*(x[kk]-x[ii]) - (z[kk]-z[ii])*(x[jj]-x[ii])) * y[ii] ) > 0: v = -v uindex = np.floor(u / bin_size).astype(int) assert 0 <= uindex < nubins vindex = np.floor((v+1) / bin_size).astype(int) assert 0 <= vindex < 2*nvbins # Rotate shears to coordinates where line connecting to center is horizontal. # Original orientation is where north is up. cenx = (x[i] + x[j] + x[k])/3. ceny = (y[i] + y[j] + y[k])/3. cenz = (z[i] + z[j] + z[k])/3. cen = coord.CelestialCoord.from_xyz(cenx,ceny,cenz) theta1 = 90*coord.degrees - c[ii].angleBetween(north_pole, cen) theta2 = 90*coord.degrees - c[jj].angleBetween(north_pole, cen) theta3 = 90*coord.degrees - c[kk].angleBetween(north_pole, cen) exp2theta1 = np.cos(2*theta1) + 1j * np.sin(2*theta1) exp2theta2 = np.cos(2*theta2) + 1j * np.sin(2*theta2) exp2theta3 = np.cos(2*theta3) + 1j * np.sin(2*theta3) www = w[i] * w[j] * w[k] g1p = (g1[ii] + 1j*g2[ii]) * exp2theta1 g2p = (g1[jj] + 1j*g2[jj]) * exp2theta2 g3p = (g1[kk] + 1j*g2[kk]) * exp2theta3 gam0 = www * g1p * g2p * g3p gam1 = www * np.conjugate(g1p) * g2p * g3p gam2 = www * g1p * np.conjugate(g2p) * g3p gam3 = www * g1p * g2p * np.conjugate(g3p) true_ntri[rindex,uindex,vindex] += 1 true_weight[rindex,uindex,vindex] += www true_gam0[rindex,uindex,vindex] += gam0 true_gam1[rindex,uindex,vindex] += gam1 true_gam2[rindex,uindex,vindex] += gam2 true_gam3[rindex,uindex,vindex] += gam3 pos = true_weight > 0 true_gam0[pos] /= true_weight[pos] true_gam1[pos] /= true_weight[pos] true_gam2[pos] /= true_weight[pos] true_gam3[pos] /= true_weight[pos] np.testing.assert_array_equal(ggg.ntri, true_ntri) np.testing.assert_allclose(ggg.weight, true_weight, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(ggg.gam0r, true_gam0.real, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(ggg.gam0i, true_gam0.imag, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(ggg.gam1r, true_gam1.real, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(ggg.gam1i, true_gam1.imag, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(ggg.gam2r, true_gam2.real, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(ggg.gam2i, true_gam2.imag, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(ggg.gam3r, true_gam3.real, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(ggg.gam3i, true_gam3.imag, rtol=1.e-5, atol=1.e-8) try: import fitsio except ImportError: print('Skipping FITS tests, since fitsio is not installed') return # Check that running via the corr3 script works correctly. config = treecorr.config.read_config('configs/ggg_direct_spherical.yaml') cat.write(config['file_name']) treecorr.corr3(config) data = fitsio.read(config['ggg_file_name']) np.testing.assert_allclose(data['r_nom'], ggg.rnom.flatten()) np.testing.assert_allclose(data['u_nom'], ggg.u.flatten()) np.testing.assert_allclose(data['v_nom'], ggg.v.flatten()) np.testing.assert_allclose(data['ntri'], ggg.ntri.flatten()) np.testing.assert_allclose(data['weight'], ggg.weight.flatten()) np.testing.assert_allclose(data['gam0r'], ggg.gam0r.flatten(), rtol=1.e-3) np.testing.assert_allclose(data['gam0i'], ggg.gam0i.flatten(), rtol=1.e-3) np.testing.assert_allclose(data['gam1r'], ggg.gam1r.flatten(), rtol=1.e-3) np.testing.assert_allclose(data['gam1i'], ggg.gam1i.flatten(), rtol=1.e-3) np.testing.assert_allclose(data['gam2r'], ggg.gam2r.flatten(), rtol=1.e-3) np.testing.assert_allclose(data['gam2i'], ggg.gam2i.flatten(), rtol=1.e-3) np.testing.assert_allclose(data['gam3r'], ggg.gam3r.flatten(), rtol=1.e-3) np.testing.assert_allclose(data['gam3i'], ggg.gam3i.flatten(), rtol=1.e-3) # Repeat with binslop = 0 # And don't do any top-level recursion so we actually test not going to the leaves. ggg = treecorr.GGGCorrelation(min_sep=min_sep, bin_size=bin_size, nbins=nrbins, sep_units='deg', bin_slop=0, max_top=0) ggg.process(cat) np.testing.assert_array_equal(ggg.ntri, true_ntri) np.testing.assert_allclose(ggg.weight, true_weight, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(ggg.gam0r, true_gam0.real, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(ggg.gam0i, true_gam0.imag, rtol=1.e-5, atol=1.e-4) np.testing.assert_allclose(ggg.gam1r, true_gam1.real, rtol=1.e-3, atol=1.e-4) np.testing.assert_allclose(ggg.gam1i, true_gam1.imag, rtol=1.e-3, atol=1.e-4) np.testing.assert_allclose(ggg.gam2r, true_gam2.real, rtol=1.e-3, atol=1.e-4) np.testing.assert_allclose(ggg.gam2i, true_gam2.imag, rtol=1.e-3, atol=1.e-4) np.testing.assert_allclose(ggg.gam3r, true_gam3.real, rtol=1.e-3, atol=1.e-4) np.testing.assert_allclose(ggg.gam3i, true_gam3.imag, rtol=1.e-3, atol=1.e-4)
def test_direct_spherical(): # Repeat in spherical coords ngal = 100 s = 10. rng = np.random.RandomState(8675309) x1 = rng.normal(0,s, (ngal,) ) y1 = rng.normal(0,s, (ngal,) ) + 200 # Put everything at large y, so small angle on sky z1 = rng.normal(0,s, (ngal,) ) w1 = rng.random_sample(ngal) k1 = rng.normal(5,1, (ngal,) ) x2 = rng.normal(0,s, (ngal,) ) y2 = rng.normal(0,s, (ngal,) ) + 200 z2 = rng.normal(0,s, (ngal,) ) w2 = rng.random_sample(ngal) g12 = rng.normal(0,0.2, (ngal,) ) g22 = rng.normal(0,0.2, (ngal,) ) ra1, dec1 = coord.CelestialCoord.xyz_to_radec(x1,y1,z1) ra2, dec2 = coord.CelestialCoord.xyz_to_radec(x2,y2,z2) cat1 = treecorr.Catalog(ra=ra1, dec=dec1, ra_units='rad', dec_units='rad', w=w1, k=k1) cat2 = treecorr.Catalog(ra=ra2, dec=dec2, ra_units='rad', dec_units='rad', w=w2, g1=g12, g2=g22) min_sep = 1. max_sep = 10. nbins = 50 bin_size = np.log(max_sep/min_sep) / nbins kg = treecorr.KGCorrelation(min_sep=min_sep, max_sep=max_sep, nbins=nbins, sep_units='deg', brute=True) kg.process(cat1, cat2) r1 = np.sqrt(x1**2 + y1**2 + z1**2) r2 = np.sqrt(x2**2 + y2**2 + z2**2) x1 /= r1; y1 /= r1; z1 /= r1 x2 /= r2; y2 /= r2; z2 /= r2 north_pole = coord.CelestialCoord(0*coord.radians, 90*coord.degrees) true_npairs = np.zeros(nbins, dtype=int) true_weight = np.zeros(nbins, dtype=float) true_xi = np.zeros(nbins, dtype=complex) c1 = [coord.CelestialCoord(r*coord.radians, d*coord.radians) for (r,d) in zip(ra1, dec1)] c2 = [coord.CelestialCoord(r*coord.radians, d*coord.radians) for (r,d) in zip(ra2, dec2)] for i in range(ngal): for j in range(ngal): rsq = (x1[i]-x2[j])**2 + (y1[i]-y2[j])**2 + (z1[i]-z2[j])**2 r = np.sqrt(rsq) r *= coord.radians / coord.degrees logr = np.log(r) index = np.floor(np.log(r/min_sep) / bin_size).astype(int) if index < 0 or index >= nbins: continue # Rotate shears to coordinates where line connecting is horizontal. # Original orientation is where north is up. theta2 = 90*coord.degrees - c2[j].angleBetween(c1[i], north_pole) expm2theta2 = np.cos(2*theta2) - 1j * np.sin(2*theta2) g2 = g12[j] + 1j * g22[j] g2 *= expm2theta2 ww = w1[i] * w2[j] xi = -ww * k1[i] * g2 true_npairs[index] += 1 true_weight[index] += ww true_xi[index] += xi true_xi /= true_weight print('true_npairs = ',true_npairs) print('diff = ',kg.npairs - true_npairs) np.testing.assert_array_equal(kg.npairs, true_npairs) print('true_weight = ',true_weight) print('diff = ',kg.weight - true_weight) np.testing.assert_allclose(kg.weight, true_weight, rtol=1.e-5, atol=1.e-8) print('true_xi = ',true_xi) print('kg.xi = ',kg.xi) np.testing.assert_allclose(kg.xi, true_xi.real, rtol=1.e-4, atol=1.e-8) np.testing.assert_allclose(kg.xi_im, true_xi.imag, rtol=1.e-4, atol=1.e-8) try: import fitsio except ImportError: print('Skipping FITS tests, since fitsio is not installed') return # Check that running via the corr2 script works correctly. config = treecorr.config.read_config('configs/kg_direct_spherical.yaml') cat1.write(config['file_name']) cat2.write(config['file_name2']) treecorr.corr2(config) data = fitsio.read(config['kg_file_name']) np.testing.assert_allclose(data['r_nom'], kg.rnom) np.testing.assert_allclose(data['npairs'], kg.npairs) np.testing.assert_allclose(data['weight'], kg.weight) np.testing.assert_allclose(data['kgamT'], kg.xi, rtol=1.e-3) np.testing.assert_allclose(data['kgamX'], kg.xi_im, rtol=1.e-3) # Repeat with binslop = 0 # And don't do any top-level recursion so we actually test not going to the leaves. kg = treecorr.KGCorrelation(min_sep=min_sep, max_sep=max_sep, nbins=nbins, sep_units='deg', bin_slop=0, max_top=0) kg.process(cat1, cat2) np.testing.assert_array_equal(kg.npairs, true_npairs) np.testing.assert_allclose(kg.weight, true_weight, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(kg.xi, true_xi.real, rtol=1.e-3, atol=1.e-3) np.testing.assert_allclose(kg.xi_im, true_xi.imag, rtol=1.e-3, atol=1.e-3)
def parse_xyzsep(args, kwargs, _coords): """Parse the different options for passing a coordinate and separation. The allowed parameters are: 1. If _coords == Flat: :param x: The x coordinate of the location for which to count nearby points. :param y: The y coordinate of the location for which to count nearby points. :param sep: The separation distance 2. If _coords == ThreeD: Either :param x: The x coordinate of the location for which to count nearby points. :param y: The y coordinate of the location for which to count nearby points. :param z: The z coordinate of the location for which to count nearby points. :param sep: The separation distance Or :param ra: The right ascension of the location for which to count nearby points. :param dec: The declination of the location for which to count nearby points. :param r: The distance to the location for which to count nearby points. :param sep: The separation distance 3. If _coords == Sphere: :param ra: The right ascension of the location for which to count nearby points. :param dec: The declination of the location for which to count nearby points. :param sep: The separation distance as an angle For all angle parameters (ra, dec, sep), this quantity may be a coord.Angle instance, or units maybe be provided as ra_units, dec_units or sep_units respectively. Finally, in cases where ra, dec are allowed, a coord.CelestialCoord instance may be provided as the first argument. :returns: The effective (x, y, z, sep) as a tuple. """ radec = False if _coords == treecorr._lib.Flat: if len(args) == 0: if 'x' not in kwargs: raise TypeError("Missing required argument x") if 'y' not in kwargs: raise TypeError("Missing required argument y") if 'sep' not in kwargs: raise TypeError("Missing required argument sep") x = kwargs.pop('x') y = kwargs.pop('y') sep = kwargs.pop('sep') elif len(args) == 1: raise TypeError( "x,y should be given as either args or kwargs, not mixed.") elif len(args) == 2: if 'sep' not in kwargs: raise TypeError("Missing required argument sep") x, y = args sep = kwargs.pop('sep') elif len(args) == 3: x, y, sep = args else: raise TypeError("Too many positional args") z = 0 elif _coords == treecorr._lib.ThreeD: if len(args) == 0: if 'x' in kwargs: if 'y' not in kwargs: raise TypeError("Missing required argument y") if 'z' not in kwargs: raise TypeError("Missing required argument z") x = kwargs.pop('x') y = kwargs.pop('y') z = kwargs.pop('z') else: if 'ra' not in kwargs: raise TypeError("Missing required argument ra") if 'dec' not in kwargs: raise TypeError("Missing required argument dec") ra = kwargs.pop('ra') dec = kwargs.pop('dec') radec = True if 'r' not in kwargs: raise TypeError("Missing required argument r") r = kwargs.pop('r') if 'sep' not in kwargs: raise TypeError("Missing required argument sep") sep = kwargs.pop('sep') elif len(args) == 1: if not isinstance(args[0], coord.CelestialCoord): raise TypeError("Invalid unnamed argument %r" % args[0]) ra = args[0].ra dec = args[0].dec radec = True if 'r' not in kwargs: raise TypeError("Missing required argument r") r = kwargs.pop('r') if 'sep' not in kwargs: raise TypeError("Missing required argument sep") sep = kwargs.pop('sep') elif len(args) == 2: if isinstance(args[0], coord.CelestialCoord): ra = args[0].ra dec = args[0].dec radec = True r = args[1] else: ra, dec = args radec = True if 'r' not in kwargs: raise TypeError("Missing required argument r") r = kwargs.pop('r') if 'sep' not in kwargs: raise TypeError("Missing required argument sep") sep = kwargs.pop('sep') elif len(args) == 3: if isinstance(args[0], coord.CelestialCoord): ra = args[0].ra dec = args[0].dec radec = True r = args[1] sep = args[2] elif isinstance(args[0], coord.Angle): ra, dec, r = args radec = True if 'sep' not in kwargs: raise TypeError("Missing required argument sep") sep = kwargs.pop('sep') elif 'ra_units' in kwargs or 'dec_units' in kwargs: ra, dec, r = args radec = True if 'sep' not in kwargs: raise TypeError("Missing required argument sep") sep = kwargs.pop('sep') else: x, y, z = args if 'sep' not in kwargs: raise TypeError("Missing required argument sep") sep = kwargs.pop('sep') elif len(args) == 4: if isinstance(args[0], coord.Angle): ra, dec, r, sep = args radec = True elif 'ra_units' in kwargs or 'dec_units' in kwargs: ra, dec, r, sep = args radec = True else: x, y, z, sep = args else: raise TypeError("Too many positional args") else: # Sphere if len(args) == 0: if 'ra' not in kwargs: raise TypeError("Missing required argument ra") if 'dec' not in kwargs: raise TypeError("Missing required argument dec") ra = kwargs.pop('ra') dec = kwargs.pop('dec') radec = True if 'sep' not in kwargs: raise TypeError("Missing required argument sep") sep = kwargs.pop('sep') elif len(args) == 1: if not isinstance(args[0], coord.CelestialCoord): raise TypeError("Invalid unnamed argument %r" % args[0]) ra = args[0].ra dec = args[0].dec radec = True if 'sep' not in kwargs: raise TypeError("Missing required argument sep") sep = kwargs.pop('sep') elif len(args) == 2: if isinstance(args[0], coord.CelestialCoord): ra = args[0].ra dec = args[0].dec radec = True sep = args[1] else: ra, dec = args radec = True if 'sep' not in kwargs: raise TypeError("Missing required argument sep") sep = kwargs.pop('sep') elif len(args) == 3: ra, dec, sep = args radec = True else: raise TypeError("Too many positional args") if not isinstance(sep, coord.Angle): if 'sep_units' not in kwargs: raise TypeError("Missing required argument sep_units") sep = sep * coord.AngleUnit.from_name(kwargs.pop('sep_units')) # We actually want the chord distance for this angle. sep = 2. * np.sin(sep / 2.) if radec: if not isinstance(ra, coord.Angle): if 'ra_units' not in kwargs: raise TypeError("Missing required argument ra_units") ra = ra * coord.AngleUnit.from_name(kwargs.pop('ra_units')) if not isinstance(dec, coord.Angle): if 'dec_units' not in kwargs: raise TypeError("Missing required argument dec_units") dec = dec * coord.AngleUnit.from_name(kwargs.pop('dec_units')) x, y, z = coord.CelestialCoord(ra, dec).get_xyz() if _coords == treecorr._lib.ThreeD: x *= r y *= r z *= r if len(kwargs) > 0: raise TypeError("Invalid kwargs: %s" % (kwargs)) return float(x), float(y), float(z), float(sep)
def test_sample_pairs(): nobj = 10000 rng = np.random.RandomState(8675309) x1 = rng.random_sample(nobj) # All from 0..1 y1 = rng.random_sample(nobj) z1 = rng.random_sample(nobj) w1 = rng.random_sample(nobj) use = rng.randint(30, size=nobj).astype(float) w1[use == 0] = 0 g11 = rng.random_sample(nobj) g21 = rng.random_sample(nobj) k1 = rng.random_sample(nobj) x2 = rng.random_sample(nobj) # All from 0..1 y2 = rng.random_sample(nobj) z2 = rng.random_sample(nobj) w2 = rng.random_sample(nobj) use = rng.randint(30, size=nobj).astype(float) w2[use == 0] = 0 g12 = rng.random_sample(nobj) g22 = rng.random_sample(nobj) k2 = rng.random_sample(nobj) # Start with flat coords cat1 = treecorr.Catalog(x=x1, y=y1, w=w1, g1=g11, g2=g21, k=k1, keep_zero_weight=True) cat2 = treecorr.Catalog(x=x2, y=y2, w=w2, g1=g12, g2=g22, k=k2, keep_zero_weight=True) # Note: extend range low enough that some bins have < 100 pairs. nn = treecorr.NNCorrelation(min_sep=0.001, max_sep=0.01, bin_size=0.1, max_top=0) nn.process(cat1, cat2) print('rnom = ',nn.rnom) print('npairs = ',nn.npairs.astype(int)) # Start with a bin near the bottom with < 100 pairs # This only exercises case 1 in the sampleFrom function. b = 1 i1, i2, sep = nn.sample_pairs(100, cat1, cat2, min_sep=nn.left_edges[b], max_sep=nn.right_edges[b]) print('i1 = ',i1) print('i2 = ',i2) print('sep = ',sep) assert nn.npairs[b] <= 100 # i.e. make sure these next tests are what we want to do. assert len(i1) == nn.npairs[b] assert len(i2) == nn.npairs[b] assert len(sep) == nn.npairs[b] actual_sep = ((x1[i1]-x2[i2])**2 + (y1[i1]-y2[i2])**2)**0.5 np.testing.assert_allclose(sep, actual_sep, rtol=0.1) # half bin size with slop. np.testing.assert_array_less(sep, nn.right_edges[b]) np.testing.assert_array_less(nn.left_edges[b], sep) # Next one that still isn't too many pairs, but more than 100 # This exercises cases 1,2 in the sampleFrom function. b = 10 i1, i2, sep = nn.sample_pairs(100, cat1, cat2, min_sep=nn.left_edges[b], max_sep=nn.right_edges[b]) print('i1 = ',i1) print('i2 = ',i2) print('sep = ',sep) assert nn.npairs[b] > 100 assert len(i1) == 100 assert len(i2) == 100 assert len(sep) == 100 actual_sep = ((x1[i1]-x2[i2])**2 + (y1[i1]-y2[i2])**2)**0.5 np.testing.assert_allclose(sep, actual_sep, rtol=0.1) np.testing.assert_array_less(sep, nn.right_edges[b]) np.testing.assert_array_less(nn.left_edges[b], sep) # To exercise case 3, we need to go to larger separations, so the recursion # more often stops before getting to the leaves. # Also switch to 3d coordinates. cat1 = treecorr.Catalog(x=x1, y=y1, z=z1, w=w1, g1=g11, g2=g21, k=k1, keep_zero_weight=True) cat2 = treecorr.Catalog(x=x2, y=y2, z=z2, w=w2, g1=g12, g2=g22, k=k2, keep_zero_weight=True) gg = treecorr.GGCorrelation(min_sep=0.4, nbins=10, bin_size=0.1, max_top=0) gg.process(cat1, cat2) print('rnom = ',gg.rnom) print('npairs = ',gg.npairs.astype(int)) for b in [0,5]: i1, i2, sep = gg.sample_pairs(100, cat1, cat2, min_sep=gg.left_edges[b], max_sep=gg.right_edges[b]) print('len(npairs) = ',len(gg.npairs)) print('npairs = ',gg.npairs) print('i1 = ',i1) print('i2 = ',i2) print('sep = ',sep) assert len(i1) == 100 assert len(i2) == 100 assert len(sep) == 100 actual_sep = ((x1[i1]-x2[i2])**2 + (y1[i1]-y2[i2])**2 + (z1[i1]-z2[i2])**2)**0.5 np.testing.assert_allclose(sep, actual_sep, rtol=0.2) np.testing.assert_array_less(sep, gg.right_edges[b]) np.testing.assert_array_less(gg.left_edges[b], sep) # Check a different metric. # Also ability to generate the field automatically. cat1.clear_cache() # Clears the previously made cat1.field cat2.clear_cache() # and cat2.field b = 3 with CaptureLog() as cl: nk = treecorr.NKCorrelation(min_sep=0.4, max_sep=1.0, bin_size=0.1, max_top=0, logger=cl.logger) i1, i2, sep = nk.sample_pairs(100, cat1, cat2, metric='Arc', min_sep=nk.left_edges[b], max_sep=nk.right_edges[b]) print(cl.output) nk.process(cat1, cat2, metric='Arc') print('len(npairs) = ',len(nk.npairs)) print('npairs = ',nk.npairs) assert "Sampled %d pairs out of a total of %d"%(100, nk.npairs[b]) in cl.output print('i1 = ',i1) print('i2 = ',i2) print('sep = ',sep) assert len(i1) == 100 assert len(i2) == 100 assert len(sep) == 100 r1 = (x1**2 + y1**2 + z1**2)**0.5 r2 = (x2**2 + y2**2 + z2**2)**0.5 xx1 = x1/r1 yy1 = y1/r1 zz1 = z1/r1 xx2 = x2/r2 yy2 = y2/r2 zz2 = z2/r2 chord_sep = ((xx1[i1]-xx2[i2])**2 + (yy1[i1]-yy2[i2])**2 + (zz1[i1]-zz2[i2])**2)**0.5 arc_sep = np.arcsin(chord_sep/2.)*2. print('arc_sep = ',arc_sep) np.testing.assert_allclose(sep, arc_sep, rtol=0.1) np.testing.assert_array_less(sep, nk.right_edges[b]) np.testing.assert_array_less(nk.left_edges[b], sep) # Finally, check spherical coords with non-default units. ra1, dec1 = coord.CelestialCoord.xyz_to_radec(x1,y1,z1) ra2, dec2 = coord.CelestialCoord.xyz_to_radec(x2,y2,z2) cat1 = treecorr.Catalog(ra=ra1, dec=dec1, ra_units='rad', dec_units='rad') cat2 = treecorr.Catalog(ra=ra2, dec=dec2, ra_units='rad', dec_units='rad') nn = treecorr.NNCorrelation(min_sep=1., max_sep=60., nbins=50, sep_units='deg', metric='Arc') nn.process(cat1, cat2) print('rnom = ',nn.rnom) print('npairs = ',nn.npairs.astype(int)) b = 5 n = 50 i1, i2, sep = nn.sample_pairs(n, cat1, cat2, min_sep=nn.left_edges[b], max_sep=nn.right_edges[b]) print('i1 = ',i1) print('i2 = ',i2) print('sep = ',sep) assert nn.npairs[b] > n assert len(i1) == n assert len(i2) == n assert len(sep) == n c1 = [coord.CelestialCoord(r*coord.radians, d*coord.radians) for (r,d) in zip(ra1,dec1)] c2 = [coord.CelestialCoord(r*coord.radians, d*coord.radians) for (r,d) in zip(ra2,dec2)] actual_sep = np.array([c1[i1[k]].distanceTo(c2[i2[k]]) / coord.degrees for k in range(n)]) print('actual_sep = ',actual_sep) np.testing.assert_allclose(sep, actual_sep, rtol=0.1) np.testing.assert_array_less(sep, nn.right_edges[b]) np.testing.assert_array_less(nn.left_edges[b], sep)
def getWCS(world_pos, PA=None, date=None, SCAs=None, PA_is_FPA=False): """ This routine returns a dict containing a WCS for each of the WFIRST SCAs (Sensor Chip Array, the equivalent of a chip in an optical CCD). The WFIRST SCAs are labeled 1-18, so these numbers are used as the keys in the dict. Alternatively the user can request a subset of the SCAs using the ``SCAs`` option. The basic instrument parameters used to create the WCS correspond to those in Cycle 6, which includes some significant updates from Cycle 5, including a 90 degree rotation of the focal plane axes relative to the payload axes, and two rows of SCAs are swapped. The user must specify a position for observation, at which the center of the focal plane array will point. This must be supplied as a CelestialCoord ``world_pos``. In general, only certain positions are observable on certain dates, and for a given position there is an optimal position angle for the observatory (with the solar panels pointed as directly towards the sun as possible). Users who are knowledgable about these details may choose to supply a position angle as ``PA``, either for the observatory or for the focal plane (using ``PA_is_FPA`` to indicate this). But otherwise, the routine will simply choose the optimal position angle for a given date. To fully understand all possible inputs and outputs to this routine, users may wish to consult the diagram on the GalSim wiki, https://github.com/GalSim-developers/GalSim/wiki/GalSim-WFIRST-module-diagrams Parameters: world_pos: A `galsim.CelestialCoord` indicating the position to observe at the center of the focal plane array (FPA). Note that if the given position is not observable on the given date, then the routine will raise an exception. PA: A `galsim.Angle` representing the position angle of the observatory +Y axis, unless ``PA_is_FPA=True``, in which case it's the position angle of the FPA. For users to do not care about this, then leaving this as None will result in the routine using the supplied ``date`` and ``world_pos`` to select the optimal orientation for the observatory. Note that if a user supplies a ``PA`` value, the routine does not check whether this orientation is actually allowed. [default: None] date: The date of the observation, as a python datetime object. If None, then the vernal equinox in 2025 will be used. [default: None] PA_is_FPA: If True, then the position angle that was provided was the PA of the focal plane array, not the observatory. [default: False] SCAs: A single number or iterable giving the SCAs for which the WCS should be obtained. If None, then the WCS is calculated for all SCAs. [default: None] Returns: A dict of WCS objects for each SCA. """ from .. import GSFitsWCS, FitsHeader # First just parse the input quantities. date, SCAs, pa_fpa, pa_obsy = _parse_WCS_inputs(world_pos, PA, date, PA_is_FPA, SCAs) # Further gory details on coordinate systems, for developers: Observatory coordinate system is # defined such that +X_obs points along the boresight into the sky, +Z_obs points towards the # Sun in the absence of a roll offset (i.e., roll offset = 0 defines the optimal position angle # for the observatory), +Y_obs makes a right-handed system. # # Payload coordinate system: +X_pl points along -Y_obs, +Y_pl points along +Z_obs, +Z_pl points # along -X_obs (back towards observer). # # Wide field imager (WFI) focal plane assembly (FPA) coordinate system: This is defined by a # left-handed system f1, f2, that is rotated by an angle `theta_fpa` with respect to the payload # axes. +f1 points along the long axis of the focal plane, transverse to the radius from the # telescope optic axis. +f2 points radially out from the telescope optic axis, along the narrow # dimension of the focal plane. If +f2 points North, then +f1 points East. `theta_fpa` is a # positive CCW rotation of the f2 axis relative to -Y_pl, and of f1 relative to +X_pl. In terms # of focal plane geometry, if +Y_fp is pointing North, then SCAs 3 and 12 will be at highest # declination, 8 and 17 at the lowest. +Y_fp is aligned with the short axis of the focal plane # array. # # There is also a detector coordinate system (P1, P2). +P1 and +P2 point along the fast- and # slow-scan directions of the pixel readout, respectively. # # So, for reference, if the boresight is pointed at RA=90, DEC=0 on March 21st (Sun at vernal # equinox), then +X_obs points at (RA,DEC)=(90,0), +Y_obs points North, and +Z_obs points at the # Sun. The payload coordinates are +X_pl points South, -Y_pl points East. Finally, the FPA # coordinate system is defined by +f2 being at a position angle 90+theta_fpa east of North. If # the observatory +Y axis is at a position angle `pa_obsy` East of North, then the focal plane # (+f2) is at a position angle pa_fpa = pa_obsy + 90 + theta_fpa. # Figure out tangent-plane positions for FPA center: # Distortion function is zero there (so we could've passed this through _det_to_tangplane # routine, but we do not need to) xc_fpa_tp, yc_fpa_tp = xc_fpa, yc_fpa # Note, this routine reads in the coeffs. We don't use them until later, but read them in for # all SCAs at once. a_sip, b_sip = _parse_sip_file(sip_filename) # Loop over SCAs: wcs_dict = {} for i_sca in SCAs: # Set up the header. header = [] # Populate some necessary variables in the FITS header that are always the same, regardless of # input and SCA number. _populate_required_fields(header) # And populate some things that just depend on the overall locations or other input, not on # the SCA. header.extend([ ('RA_TARG', world_pos.ra / coord.degrees, "right ascension of the target (deg) (J2000)"), ('DEC_TARG', world_pos.dec / coord.degrees, "declination of the target (deg) (J2000)"), ('PA_OBSY', pa_obsy / coord.degrees, "position angle of observatory Y axis (deg)"), ('PA_FPA', pa_fpa / coord.degrees, "position angle of FPA Y axis (deg)"), ('SCA_NUM', i_sca, "SCA number (1 - 18)"), ]) # Leave phi_p at 180 (0 if dec_targ==-90), so that tangent plane axes remain oriented along # celestial coordinates. In other words, phi_p is the angle of the +Y axis in the tangent # plane, which is of course pi if we're measuring these phi angles clockwise from the -Y # axis. Note that this quantity is not used in any calculations at all, but for consistency # with the WCS code that comes from the WFIRST project office, we calculate this quantity # and put it in the FITS header. if world_pos.dec / coord.degrees > -90.: phi_p = np.pi * coord.radians else: phi_p = 0. * coord.radians # Get position of SCA center given the center of the FPA and the orientation angle of the # focal plane. crval, u, v = _get_sca_center_pos(i_sca, world_pos, pa_fpa) # Compute the position angle of the local pixel Y axis. # This requires projecting local North onto the detector axes. # Start by adding any SCA-unique rotation relative to FPA axes: sca_tp_rot = pa_fpa + sca_rot[i_sca] * coord.degrees # Go some reasonable distance from crval in the +y direction. Say, 1 degree. plus_y = world_pos.deproject(u, v + 1 * coord.degrees, projection='gnomonic') # Find the angle between this point, crval and due north. north = coord.CelestialCoord(0. * coord.degrees, 90. * coord.degrees) pa_sca = sca_tp_rot - crval.angleBetween(plus_y, north) # Compute CD coefficients: extract the linear terms from the a_sip, b_sip arrays. These # linear terms are stored in the SIP arrays for convenience, but are defined differently. # The other terms have been divided by the linear terms, so that these become pure # multiplicative factors. There is no need to change signs of the SIP coefficents associated # with odd powers of X! Change sign of a10, b10 because the tangent-plane X pixel coordinate # has sign opposite to the detector pixel X coordinate, and this transformation maps pixels # to tangent plane. a10 = -a_sip[i_sca, 1, 0] a11 = a_sip[i_sca, 0, 1] b10 = -b_sip[i_sca, 1, 0] b11 = b_sip[i_sca, 0, 1] # Rotate by pa_fpa. cos_pa_sca = np.cos(pa_sca) sin_pa_sca = np.sin(pa_sca) header.extend([ ('CRVAL1', crval.ra / coord.degrees, "first axis value at reference pixel"), ('CRVAL2', crval.dec / coord.degrees, "second axis value at reference pixel"), ('CD1_1', cos_pa_sca * a10 + sin_pa_sca * b10, "partial of first axis coordinate w.r.t. x"), ('CD1_2', cos_pa_sca * a11 + sin_pa_sca * b11, "partial of first axis coordinate w.r.t. y"), ('CD2_1', -sin_pa_sca * a10 + cos_pa_sca * b10, "partial of second axis coordinate w.r.t. x"), ('CD2_2', -sin_pa_sca * a11 + cos_pa_sca * b11, "partial of second axis coordinate w.r.t. y"), ('ORIENTAT', pa_sca / coord.degrees, "position angle of image y axis (deg. e of n)"), ('LONPOLE', phi_p / coord.degrees, "Native longitude of celestial pole"), ]) for i in range(n_sip): for j in range(n_sip): if i + j >= 2 and i + j < n_sip: sipstr = "A_%d_%d" % (i, j) header.append((sipstr, a_sip[i_sca, i, j])) sipstr = "B_%d_%d" % (i, j) header.append((sipstr, b_sip[i_sca, i, j])) header = FitsHeader(header) wcs = GSFitsWCS(header=header) # Store the original header as an attribute of the WCS. This ensures that we have all the # extra keywords for whenever an image with this WCS is written to file. wcs.header = header wcs_dict[i_sca] = wcs return wcs_dict
def convertCenter(world_pos, SCA, PA=None, date=None, PA_is_FPA=False, tol=0.5 * coord.arcsec): """ This is a simple helper routine that takes an input position ``world_pos`` that is meant to correspond to the position of the center of an SCA, and tells where the center of the focal plane array should be. The goal is to provide a position that can be used as an input to getWCS(), which wants the center of the focal plane array. The results of the calculation are deterministic if given a fixed position angle (PA). If it's not given one, it will try to determine the best one for this location and date, like getWCS() does. Because of distortions varying across the focal plane, this routine has to iteratively correct its initial result based on empirical tests. The ``tol`` kwarg can be used to adjust how careful it will be, but it always does at least one iteration. To fully understand all possible inputs and outputs to this routine, users may wish to consult the diagram on the GalSim wiki, https://github.com/GalSim-developers/GalSim/wiki/GalSim-WFIRST-module-diagrams Parameters: world_pos: A galsim.CelestialCoord indicating the position to observe at the center of the given SCA. Note that if the given position is not observable on the given date, then the routine will raise an exception. SCA: A single number giving the SCA for which the center should be located at ``world_pos``. PA: galsim.Angle representing the position angle of the observatory +Y axis, unless ``PA_is_FPA=True``, in which case it's the position angle of the FPA. For users to do not care about this, then leaving this as None will result in the routine using the supplied ``date`` and ``world_pos`` to select the optimal orientation for the observatory. Note that if a user supplies a ``PA`` value, the routine does not check whether this orientation is actually allowed. [default: None] date: The date of the observation, as a python datetime object. If None, then the vernal equinox in 2025 will be used. [default: None] PA_is_FPA: If True, then the position angle that was provided was the PA of the focal plane array, not the observatory. [default: False] tol: Tolerance for errors due to distortions, as a galsim.Angle. [default: 0.5*galsim.arcsec] Returns: A CelestialCoord object indicating the center of the focal plane array. """ from .. import PositionD from . import n_pix if not isinstance(SCA, int): raise TypeError("Must pass in an int corresponding to the SCA") if not isinstance(tol, coord.Angle): raise TypeError("tol must be a galsim.Angle") use_SCA = SCA # Parse inputs appropriately. _, _, pa_fpa, _ = _parse_WCS_inputs(world_pos, PA, date, PA_is_FPA, [SCA]) # Now pretend world_pos was the FPA center and we want to find the location of this SCA: _, u, v = _get_sca_center_pos(use_SCA, world_pos, pa_fpa) # The (u, v) values give an offset, and we can invert this. fpa_cent = world_pos.deproject(-u, -v, projection='gnomonic') # This is only approximately correct, especially for detectors that are far from the center of # the FPA, because of distortions etc. We can do an iterative correction. # For the default value of 'tol', typically just 1-2 iterations are needed. shift_val = 1000.0 # arcsec while shift_val > tol / coord.arcsec: test_wcs = getWCS(fpa_cent, PA, date, use_SCA, PA_is_FPA)[use_SCA] im_cent_pos = PositionD(n_pix / 2, n_pix / 2) test_sca_pos = test_wcs.toWorld(im_cent_pos) delta_ra = np.cos(world_pos.dec) * (world_pos.ra - test_sca_pos.ra) delta_dec = world_pos.dec - test_sca_pos.dec shift_val = np.abs(world_pos.distanceTo(test_sca_pos) / coord.arcsec) fpa_cent = coord.CelestialCoord(fpa_cent.ra + delta_ra, fpa_cent.dec + delta_dec) return fpa_cent
def test_direct_spherical(): # Repeat in spherical coords ngal = 50 s = 10. rng = np.random.RandomState(8675309) x = rng.normal(0, s, (ngal, )) y = rng.normal( 0, s, (ngal, )) + 200 # Put everything at large y, so small angle on sky z = rng.normal(0, s, (ngal, )) w = rng.random_sample(ngal) kap = rng.normal(0, 3, (ngal, )) w = np.ones_like(w) ra, dec = coord.CelestialCoord.xyz_to_radec(x, y, z) cat = treecorr.Catalog(ra=ra, dec=dec, ra_units='rad', dec_units='rad', w=w, k=kap) min_sep = 1. bin_size = 0.2 nrbins = 10 nubins = 5 nvbins = 5 max_sep = min_sep * np.exp(nrbins * bin_size) kkk = treecorr.KKKCorrelation(min_sep=min_sep, bin_size=bin_size, nbins=nrbins, sep_units='deg', brute=True) kkk.process(cat) r = np.sqrt(x**2 + y**2 + z**2) x /= r y /= r z /= r north_pole = coord.CelestialCoord(0 * coord.radians, 90 * coord.degrees) true_ntri = np.zeros((nrbins, nubins, 2 * nvbins), dtype=int) true_weight = np.zeros((nrbins, nubins, 2 * nvbins), dtype=float) true_zeta = np.zeros((nrbins, nubins, 2 * nvbins), dtype=float) rad_min_sep = min_sep * coord.degrees / coord.radians rad_max_sep = max_sep * coord.degrees / coord.radians c = [ coord.CelestialCoord(r * coord.radians, d * coord.radians) for (r, d) in zip(ra, dec) ] for i in range(ngal): for j in range(i + 1, ngal): for k in range(j + 1, ngal): d12 = np.sqrt((x[i] - x[j])**2 + (y[i] - y[j])**2 + (z[i] - z[j])**2) d23 = np.sqrt((x[j] - x[k])**2 + (y[j] - y[k])**2 + (z[j] - z[k])**2) d31 = np.sqrt((x[k] - x[i])**2 + (y[k] - y[i])**2 + (z[k] - z[i])**2) d3, d2, d1 = sorted([d12, d23, d31]) rindex = np.floor(np.log(d2 / rad_min_sep) / bin_size).astype(int) if rindex < 0 or rindex >= nrbins: continue if [d1, d2, d3] == [d23, d31, d12]: ii, jj, kk = i, j, k elif [d1, d2, d3] == [d23, d12, d31]: ii, jj, kk = i, k, j elif [d1, d2, d3] == [d31, d12, d23]: ii, jj, kk = j, k, i elif [d1, d2, d3] == [d31, d23, d12]: ii, jj, kk = j, i, k elif [d1, d2, d3] == [d12, d23, d31]: ii, jj, kk = k, i, j elif [d1, d2, d3] == [d12, d31, d23]: ii, jj, kk = k, j, i else: assert False # Now use ii, jj, kk rather than i,j,k, to get the indices # that correspond to the points in the right order. u = d3 / d2 v = (d1 - d2) / d3 if (((x[jj] - x[ii]) * (y[kk] - y[ii]) - (x[kk] - x[ii]) * (y[jj] - y[ii])) * z[ii] + ((y[jj] - y[ii]) * (z[kk] - z[ii]) - (y[kk] - y[ii]) * (z[jj] - z[ii])) * x[ii] + ((z[jj] - z[ii]) * (x[kk] - x[ii]) - (z[kk] - z[ii]) * (x[jj] - x[ii])) * y[ii]) > 0: v = -v uindex = np.floor(u / bin_size).astype(int) assert 0 <= uindex < nubins vindex = np.floor((v + 1) / bin_size).astype(int) assert 0 <= vindex < 2 * nvbins www = w[i] * w[j] * w[k] zeta = www * kap[i] * kap[j] * kap[k] true_ntri[rindex, uindex, vindex] += 1 true_weight[rindex, uindex, vindex] += www true_zeta[rindex, uindex, vindex] += zeta pos = true_weight > 0 true_zeta[pos] /= true_weight[pos] np.testing.assert_array_equal(kkk.ntri, true_ntri) np.testing.assert_allclose(kkk.weight, true_weight, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(kkk.zeta, true_zeta, rtol=1.e-4, atol=1.e-6) try: import fitsio except ImportError: print('Skipping FITS tests, since fitsio is not installed') return # Check that running via the corr3 script works correctly. config = treecorr.config.read_config('configs/kkk_direct_spherical.yaml') cat.write(config['file_name']) treecorr.corr3(config) data = fitsio.read(config['kkk_file_name']) np.testing.assert_allclose(data['r_nom'], kkk.rnom.flatten()) np.testing.assert_allclose(data['u_nom'], kkk.u.flatten()) np.testing.assert_allclose(data['v_nom'], kkk.v.flatten()) np.testing.assert_allclose(data['ntri'], kkk.ntri.flatten()) np.testing.assert_allclose(data['weight'], kkk.weight.flatten()) np.testing.assert_allclose(data['zeta'], kkk.zeta.flatten(), rtol=1.e-3) # Repeat with binslop = 0 # And don't do any top-level recursion so we actually test not going to the leaves. kkk = treecorr.KKKCorrelation(min_sep=min_sep, bin_size=bin_size, nbins=nrbins, sep_units='deg', bin_slop=0, max_top=0) kkk.process(cat) np.testing.assert_array_equal(kkk.ntri, true_ntri) np.testing.assert_allclose(kkk.weight, true_weight, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(kkk.zeta, true_zeta, rtol=1.e-4, atol=1.e-6)
def test_des_wcs(): """Test the get_nominal_wcs function. """ # Read a random DES image image_file = 'input/DECam_00241238_01.fits.fz' print('read DES image ', image_file) im = galsim.fits.read(image_file, read_header=True) print(list(im.header.keys())) print('ra = ', im.header['TELRA']) print('dec = ', im.header['TELDEC']) ra = coord.Angle.from_hms(im.header['TELRA']) dec = coord.Angle.from_dms(im.header['TELDEC']) pointing = coord.CelestialCoord(ra, dec) print('raw wcs = ', im.wcs) print('world coord at center = ', im.wcs.toWorld(im.center)) print('pointing = ', pointing) print('dist = ', pointing.distanceTo(im.wcs.toWorld(im.center)).deg) # This chip is near the edge, but check that we're at least close to the nominal pointing. assert pointing.distanceTo(im.wcs.toWorld(im.center)) < 1.2 * coord.degrees # Get the local affine approximation relative to the pointing center wcs1 = im.wcs.affine(world_pos=pointing) print('wcs1 = ', wcs1) print('u,v at image center = ', wcs1.toWorld(im.center)) # A different approach. Get the local wcs at the image center, and adjust # the origin to the pointing center. wcs2 = im.wcs.local(im.center).withOrigin(im.wcs.toImage(pointing)) print('wcs2 = ', wcs2) print('u,v at image center = ', wcs2.toWorld(im.center)) # Finally, compare with the mock up approximate version we have in piff wcs3 = piff.des.DECamInfo().get_nominal_wcs(chipnum=1) print('wcs3 = ', wcs3) print('u,v at image center = ', wcs3.toWorld(im.center)) # Check that these are all vaguley similar. # wcs2 is probably the most accurate of these, since it Taylor expands the nonlinear # stuff at the image center. wcs1 expands around a point way off the chip, so there # are expected to be some errors in this extrapolation. # And of course wcs3 is just an approximation, so it's only expected to be good to a # few arcsec or so. np.testing.assert_allclose(wcs3.jacobian().getMatrix(), wcs2.jacobian().getMatrix(), rtol=0.02, atol=0.003) np.testing.assert_allclose(wcs3.toWorld(im.center).x, wcs2.toWorld(im.center).x, rtol=0.02) np.testing.assert_allclose(wcs3.toWorld(im.center).y, wcs2.toWorld(im.center).y, rtol=0.02) # As mentioned, wcs1 is not as close, but that's ok. np.testing.assert_allclose(wcs3.jacobian().getMatrix(), wcs1.jacobian().getMatrix(), rtol=0.04, atol=0.002) np.testing.assert_allclose(wcs3.toWorld(im.center).x, wcs1.toWorld(im.center).x, rtol=0.04) np.testing.assert_allclose(wcs3.toWorld(im.center).y, wcs1.toWorld(im.center).y, rtol=0.04)
def test_direct_spherical(): # Repeat in spherical coords ngal = 100 s = 10. rng = np.random.RandomState(8675309) x1 = rng.normal(0, s, (ngal, )) y1 = rng.normal( 0, s, (ngal, )) + 200 # Put everything at large y, so small angle on sky z1 = rng.normal(0, s, (ngal, )) w1 = rng.random_sample(ngal) k1 = rng.normal(10, 1, (ngal, )) x2 = rng.normal(0, s, (ngal, )) y2 = rng.normal(0, s, (ngal, )) + 200 z2 = rng.normal(0, s, (ngal, )) w2 = rng.random_sample(ngal) k2 = rng.normal(0, 3, (ngal, )) ra1, dec1 = coord.CelestialCoord.xyz_to_radec(x1, y1, z1) ra2, dec2 = coord.CelestialCoord.xyz_to_radec(x2, y2, z2) cat1 = treecorr.Catalog(ra=ra1, dec=dec1, ra_units='rad', dec_units='rad', w=w1, k=k1) cat2 = treecorr.Catalog(ra=ra2, dec=dec2, ra_units='rad', dec_units='rad', w=w2, k=k2) min_sep = 1. max_sep = 10. nbins = 50 bin_size = np.log(max_sep / min_sep) / nbins kk = treecorr.KKCorrelation(min_sep=min_sep, max_sep=max_sep, nbins=nbins, sep_units='deg', brute=True) kk.process(cat1, cat2) r1 = np.sqrt(x1**2 + y1**2 + z1**2) r2 = np.sqrt(x2**2 + y2**2 + z2**2) x1 /= r1 y1 /= r1 z1 /= r1 x2 /= r2 y2 /= r2 z2 /= r2 north_pole = coord.CelestialCoord(0 * coord.radians, 90 * coord.degrees) true_npairs = np.zeros(nbins, dtype=int) true_weight = np.zeros(nbins, dtype=float) true_xi = np.zeros(nbins, dtype=float) c1 = [ coord.CelestialCoord(r * coord.radians, d * coord.radians) for (r, d) in zip(ra1, dec1) ] c2 = [ coord.CelestialCoord(r * coord.radians, d * coord.radians) for (r, d) in zip(ra2, dec2) ] for i in range(ngal): for j in range(ngal): rsq = (x1[i] - x2[j])**2 + (y1[i] - y2[j])**2 + (z1[i] - z2[j])**2 r = np.sqrt(rsq) r *= coord.radians / coord.degrees logr = np.log(r) index = np.floor(np.log(r / min_sep) / bin_size).astype(int) if index < 0 or index >= nbins: continue ww = w1[i] * w2[j] xi = ww * k1[i] * k2[j] true_npairs[index] += 1 true_weight[index] += ww true_xi[index] += xi true_xi /= true_weight print('true_npairs = ', true_npairs) print('diff = ', kk.npairs - true_npairs) np.testing.assert_array_equal(kk.npairs, true_npairs) print('true_weight = ', true_weight) print('diff = ', kk.weight - true_weight) np.testing.assert_allclose(kk.weight, true_weight, rtol=1.e-5, atol=1.e-8) print('true_xi = ', true_xi) print('kk.xi = ', kk.xi) np.testing.assert_allclose(kk.xi, true_xi, rtol=1.e-4, atol=1.e-8) try: import fitsio except ImportError: print('Skipping FITS tests, since fitsio is not installed') return # Check that running via the corr2 script works correctly. config = treecorr.config.read_config('configs/kk_direct_spherical.yaml') cat1.write(config['file_name']) cat2.write(config['file_name2']) treecorr.corr2(config) data = fitsio.read(config['kk_file_name']) np.testing.assert_allclose(data['r_nom'], kk.rnom) np.testing.assert_allclose(data['npairs'], kk.npairs) np.testing.assert_allclose(data['weight'], kk.weight) np.testing.assert_allclose(data['xi'], kk.xi, rtol=1.e-3) # Repeat with binslop = 0 # And don't do any top-level recursion so we actually test not going to the leaves. kk = treecorr.KKCorrelation(min_sep=min_sep, max_sep=max_sep, nbins=nbins, sep_units='deg', bin_slop=0, max_top=0) kk.process(cat1, cat2) np.testing.assert_array_equal(kk.npairs, true_npairs) np.testing.assert_allclose(kk.weight, true_weight, rtol=1.e-5, atol=1.e-8) np.testing.assert_allclose(kk.xi, true_xi, rtol=1.e-3, atol=1.e-6)