Beispiel #1
0
def test_ne():
    objs = [
        batoid.Mirror(batoid.Plane()),
        batoid.Detector(batoid.Plane()),
        batoid.Baffle(batoid.Plane()),
        batoid.RefractiveInterface(batoid.Plane()),
        batoid.Mirror(batoid.Paraboloid(0.1)),
        batoid.Detector(batoid.Paraboloid(0.1)),
        batoid.Baffle(batoid.Paraboloid(0.1)),
        batoid.RefractiveInterface(batoid.Paraboloid(0.1)),
        batoid.Mirror(batoid.Plane(), obscuration=batoid.ObscCircle(0.1)),
        batoid.Mirror(batoid.Plane(), inMedium=batoid.ConstMedium(1.1)),
        batoid.Mirror(batoid.Plane(), outMedium=batoid.ConstMedium(1.1)),
        batoid.Mirror(batoid.Plane(), coordSys=batoid.CoordSys([0, 0, 1])),
        batoid.CompoundOptic(
            [batoid.Mirror(batoid.Plane()),
             batoid.Mirror(batoid.Plane())]),
        batoid.CompoundOptic(
            [batoid.Mirror(batoid.Plane()),
             batoid.Baffle(batoid.Plane())]),
        batoid.CompoundOptic([
            batoid.RefractiveInterface(batoid.Plane()),
            batoid.RefractiveInterface(batoid.Plane())
        ]),
        batoid.Lens([
            batoid.RefractiveInterface(batoid.Plane()),
            batoid.RefractiveInterface(batoid.Plane())
        ]),
    ]
    all_obj_diff(objs)
Beispiel #2
0
def test_huygens_paraboloid(plot=False):
    if __name__ == '__main__':
        obscurations = [0.0, 0.25, 0.5, 0.75]
    else:
        obscurations = [0.25]

    print("Testing HuygensPSF")
    # Just do a single parabolic mirror test
    focalLength = 1.5
    diam = 0.3
    R = 2*focalLength
    for obscuration in obscurations:
        telescope = batoid.CompoundOptic(
            items = [
                batoid.Mirror(
                    batoid.Paraboloid(R),
                    name="Mirror",
                    obscuration=batoid.ObscNegation(
                        batoid.ObscAnnulus(0.5*obscuration*diam, 0.5*diam)
                    )
                ),
                batoid.Detector(
                    batoid.Plane(),
                    name="detector",
                    coordSys=batoid.CoordSys(origin=[0, 0, focalLength])
                )
            ],
            pupilSize=diam,
            backDist=10.0,
            inMedium=batoid.ConstMedium(1.0)
        )

        airy_size = 1.22*500e-9/diam * 206265
        print()
        print("Airy radius: {:4.2f} arcsec".format(airy_size))

        # Start with the HuygensPSF
        npix = 96
        size = 3.0 # arcsec
        dsize = size/npix
        dsize_X = dsize*focalLength/206265  # meters

        psf = batoid.huygensPSF(
            telescope, 0.0, 0.0, 500e-9,
            nx=npix, dx=dsize_X, dy=dsize_X
        )
        psf.array /= np.max(psf.array)

        scale = np.sqrt(np.abs(np.linalg.det(psf.primitiveVectors)))  # meters
        scale *= 206265/focalLength  # arcsec
        obj = galsim.Airy(lam=500, diam=diam, obscuration=obscuration)
        # Need to shift by half a pixel.
        obj = obj.shift(scale/2, scale/2)
        im = obj.drawImage(nx=npix, ny=npix, scale=scale, method='no_pixel')
        arr = im.array/np.max(im.array)
        gs_mom = galsim.hsm.FindAdaptiveMom(im)

        psfim = galsim.Image(psf.array)
        jt_mom = galsim.hsm.FindAdaptiveMom(psfim)

        print("GalSim shape: ", gs_mom.observed_shape)
        print("batoid shape: ", jt_mom.observed_shape)
        print("GalSim centroid:  ", gs_mom.moments_centroid)
        print("batoid centroid:  ", jt_mom.moments_centroid)
        print("GalSim size: ", gs_mom.moments_sigma)
        print("batoid size: ", jt_mom.moments_sigma)
        print("GalSim rho4: ", gs_mom.moments_rho4)
        print("batoid rho4: ", jt_mom.moments_rho4)

        np.testing.assert_allclose(
            gs_mom.observed_shape.g1,
            jt_mom.observed_shape.g1,
            rtol=0.0, atol=3e-3
        )
        np.testing.assert_allclose(
            gs_mom.observed_shape.g2,
            jt_mom.observed_shape.g2,
            rtol=0.0, atol=3e-3
        )
        np.testing.assert_allclose(
            gs_mom.moments_centroid.x,
            jt_mom.moments_centroid.x,
            rtol=0.0, atol=1e-9
        )
        np.testing.assert_allclose(
            gs_mom.moments_centroid.y,
            jt_mom.moments_centroid.y,
            rtol=0.0, atol=1e-9
        )
        np.testing.assert_allclose(
            gs_mom.moments_sigma,
            jt_mom.moments_sigma,
            rtol=1e-2  # why not better?!
        )
        np.testing.assert_allclose(
            gs_mom.moments_rho4,
            jt_mom.moments_rho4,
            rtol=2e-2
        )

        if plot:
            size = scale*npix
            import matplotlib.pyplot as plt
            fig = plt.figure(figsize=(15, 4))
            ax1 = fig.add_subplot(131)
            im1 = ax1.imshow(
                np.log10(arr),
                extent=np.r_[-1,1,-1,1]*size/2,
                vmin=-7, vmax=0
            )
            plt.colorbar(im1, ax=ax1, label=r'$\log_{10}$ flux')
            ax1.set_title('GalSim')
            ax1.set_xlabel("arcsec")
            ax1.set_ylabel("arcsec")

            sizeX = dsize_X * npix * 1e6  # microns
            ax2 = fig.add_subplot(132)
            im2 = ax2.imshow(
                np.log10(psf.array),
                extent=np.r_[-1,1,-1,1]*sizeX/2,
                vmin=-7, vmax=0
            )
            plt.colorbar(im2, ax=ax2, label=r'$\log_{10}$ flux')
            ax2.set_title('batoid')
            ax2.set_xlabel(r"$\mu m$")
            ax2.set_ylabel(r"$\mu m$")

            ax3 = fig.add_subplot(133)
            im3 = ax3.imshow(
                (psf.array-arr)/np.max(arr),
                vmin=-0.01, vmax=0.01,
                cmap='seismic'
            )
            plt.colorbar(im3, ax=ax3, label="(batoid-GalSim)/max(GalSim)")
            ax3.set_title('resid')
            ax3.set_xlabel(r"$\mu m$")
            ax3.set_ylabel(r"$\mu m$")

            fig.tight_layout()

            plt.show()
Beispiel #3
0
def test_traceSplit_simple():
    telescope = batoid.CompoundOptic(
        name = "simple",
        stopSurface=batoid.Interface(batoid.Plane()),
        items = [
            batoid.Lens(
                name = "L1",
                items = [
                    batoid.RefractiveInterface(
                        batoid.Plane(),
                        name = "L1_entrance",
                        coordSys=batoid.CoordSys(origin=[0,0,0.3]),
                        inMedium=batoid.ConstMedium(1.0),
                        outMedium=batoid.ConstMedium(1.1)
                    ),
                    batoid.RefractiveInterface(
                        batoid.Plane(),
                        name = "L1_exit",
                        coordSys=batoid.CoordSys(origin=[0,0,0.2]),
                        inMedium=batoid.ConstMedium(1.1),
                        outMedium=batoid.ConstMedium(1.0)
                    )
                ]
            ),
            batoid.Mirror(
                batoid.Plane(),
                name="Mirror"
            ),
            batoid.Detector(
                batoid.Plane(),
                name="detector",
                coordSys=batoid.CoordSys(origin=[0, 0, 0.1])
            )
        ],
        pupilSize=1.0,
        backDist=1.0,
        inMedium=batoid.ConstMedium(1.0)
    )
    telescope['L1_entrance'].forwardCoating = batoid.SimpleCoating(0.02, 0.98)
    telescope['L1_entrance'].reverseCoating = batoid.SimpleCoating(0.02, 0.98)
    telescope['L1_exit'].forwardCoating = batoid.SimpleCoating(0.02, 0.98)
    telescope['L1_exit'].reverseCoating = batoid.SimpleCoating(0.02, 0.98)
    telescope['detector'].forwardCoating = batoid.SimpleCoating(0.02, 0.98)
    rays = batoid.RayVector.asPolar(
        telescope,
        wavelength=500e-9,
        theta_x=np.deg2rad(1.0),
        theta_y=0.0,
        nrad=10, naz=60
    )
    rForward, rReverse = telescope.traceSplit(rays.copy(), minFlux=1e-4)

    for r in rForward:
        r2 = telescope.trace(rays.copy(), path=r.path)
        w = ~r2.vignetted
        np.testing.assert_allclose(r.r, r2.r[w])
        np.testing.assert_allclose(r.v, r2.v[w])
        np.testing.assert_allclose(r.t, r2.t[w])

        tf = telescope.traceFull(rays.copy(), path=r.path)
        keys = []
        for item in r.path:
            j = 0
            key = f"{item}_{j}"
            while key in keys:
                j += 1
                key = f"{item}_{j}"
            keys.append(key)
        assert keys == [k for k in tf.keys()]

        r3 = tf[keys[-1]]['out']
        w = ~r3.vignetted
        np.testing.assert_allclose(r.r, r3.r[w])
        np.testing.assert_allclose(r.v, r3.v[w])
        np.testing.assert_allclose(r.t, r3.t[w])

    for r in rReverse:
        r2 = telescope.trace(rays.copy(), path=r.path)
        w = ~r2.vignetted
        np.testing.assert_allclose(r.r, r2.r[w])
        np.testing.assert_allclose(r.v, r2.v[w])
        np.testing.assert_allclose(r.t, r2.t[w])

        tf = telescope.traceFull(rays.copy(), path=r.path)
        keys = []
        for item in r.path:
            j = 0
            key = f"{item}_{j}"
            while key in keys:
                j += 1
                key = f"{item}_{j}"
            keys.append(key)
        assert keys == [k for k in tf.keys()]

        r3 = tf[keys[-1]]['out']
        w = ~r3.vignetted
        np.testing.assert_allclose(r.r, r3.r[w])
        np.testing.assert_allclose(r.v, r3.v[w])
        np.testing.assert_allclose(r.t, r3.t[w])