Example #1
0
def test_rotation_3d_1axis():
    rx = Rotation3dOperator('X', 90, degrees=True)
    ry = Rotation3dOperator('Y', 90, degrees=True)
    rz = Rotation3dOperator('Z', 90, degrees=True)
    ref = [[1, 0, 0], [0, 1, 0], [0, 0, 1]]

    # single axis rotations
    exps = ([[1, 0, 0], [0, 0, 1], [0, -1, 0]], [[0, 0, -1], [0, 1, 0],
                                                 [1, 0, 0]], [[0, 1, 0],
                                                              [-1, 0, 0],
                                                              [0, 0, 1]])

    def func(rot, exp):
        assert_allclose(rot(ref), exp, atol=1e-15)

    for rot, exp in zip((rx, ry, rz), exps):
        yield func, rot, exp
Example #2
0
 def cartesian_horizontal2instrument(self):
     """
     Return the galactic-to-instrument transform.
     """
     time = self.date_obs + TimeDelta(self.time, format='sec')
     with rule_manager(none=False):
         r = Rotation3dOperator("ZY'Z''", self.azimuth, 90 - self.elevation,
                                self.pitch, degrees=True).T 
     return r
Example #3
0
def create_random_pointings(center,
                            npointings,
                            dtheta,
                            date_obs=None,
                            period=None,
                            latitude=None,
                            longitude=None,
                            seed=None):
    """
    Return pointings randomly and uniformly distributed in a spherical cap.

    Parameters
    ----------
    center : 2-tuple
        The R.A. and declination of the center of the FOV, in degrees.
    npointings : int
        The number of requested pointings
    dtheta : float
        The maximum angular distance to the center.
    date_obs : str or astropy.time.Time, optional
        The starting date of the observation (UTC).
    period : float, optional
        The sampling period of the pointings, in seconds.
    latitude : float, optional
        The observer's latitude [degrees]. Default is DOMEC's.
    longitude : float, optional
        The observer's longitude [degrees]. Default is DOMEC's.

    """

    r = np.random.RandomState(seed)

    cosdtheta = np.cos(np.radians(dtheta))
    theta = np.degrees(
        np.arccos(cosdtheta + (1 - cosdtheta) * r.rand(npointings)))
    phi = r.rand(npointings) * 360
    pitch = r.rand(npointings) * 360
    p = QubicSampling(npointings,
                      date_obs=date_obs,
                      period=period,
                      latitude=latitude,
                      longitude=longitude)
    time = p.date_obs + TimeDelta(p.time, format='sec')
    c2s = Cartesian2SphericalOperator('azimuth,elevation', degrees=True)
    e2h = CartesianEquatorial2HorizontalOperator('NE', time, p.latitude,
                                                 p.longitude)
    rot = Rotation3dOperator("ZY'", center[0], 90 - center[1], degrees=True)
    s2c = Spherical2CartesianOperator('zenith,azimuth', degrees=True)
    rotation = c2s(e2h(rot(s2c)))
    coords = rotation(np.asarray([theta.T, phi.T]).T)
    p.azimuth = coords[..., 0]
    p.elevation = coords[..., 1]
    p.pitch = pitch
    p.angle_hwp = r.random_integers(0, 7, npointings) * 11.25
    p.fix_az = False
    return p
Example #4
0
    def cartesian_galactic2instrument(self):
        """
        Return the galactic-to-instrument transform.

        """
        time = self.date_obs + TimeDelta(self.time, format='sec')
        with rule_manager(none=False):
            r = Rotation3dOperator("ZY'Z''", self.azimuth, 90 - self.elevation,
                                   self.pitch, degrees=True).T * \
                CartesianEquatorial2HorizontalOperator(
                    'NE', time, self.latitude, self.longitude) * \
                CartesianGalactic2EquatorialOperator()
        return r
Example #5
0
    def get_hwp_operator(self, sampling, scene):
        """
        Return the rotation matrix for the half-wave plate.

        """
        shape = (len(self), len(sampling))
        if scene.kind == 'I':
            return IdentityOperator(shapein=shape)
        if scene.kind == 'QU':
            return Rotation2dOperator(-4 * sampling.angle_hwp,
                                      degrees=True, shapein=shape + (2,))
        return Rotation3dOperator('X', -4 * sampling.angle_hwp,
                                  degrees=True, shapein=shape + (3,))
Example #6
0
 def fill(array, dense, index, value, angle, n):
     for i, (j, v, a) in enumerate(zip(index, value, angle)):
         array[i, n].index = j
         if j == -1:
             array[i, n].r11 = 0
             array[i, n].r22 = 0
             array[i, n].r32 = 0
             continue
         r = v * Rotation3dOperator('X', a, degrees=True).todense(shapein=3)
         array[i, n].r11 = r[0, 0]
         array[i, n].r22 = r[1, 1]
         array[i, n].r32 = r[2, 1]
         dense[3*i:3*i+3, 3*j:3*j+3] += r
Example #7
0
def create_repeat_pointings(center,
                            npointings,
                            dtheta,
                            nhwp_angles=3,
                            date_obs=None,
                            period=None,
                            latitude=None,
                            longitude=None,
                            seed=None):
    """
    Return pointings randomly and uniformly distributed in a spherical cap. 
    The same pointing is repeated nhwp_angles times with a different
    hwp angle each time. 

    Parameters
    ----------
    center : 2-tuple
        The R.A. and declination of the center of the FOV, in degrees.
    npointings : int
        The number of requested pointings
    dtheta : float
        The maximum angular distance to the center.
    nhwp_angles : int
        The number of HWP angles used.
    date_obs : str or astropy.time.Time, optional
        The starting date of the observation (UTC).
    period : float, optional
        The sampling period of the pointings, in seconds.
    latitude : float, optional
        The observer's latitude [degrees]. Default is DOMEC's.
    longitude : float, optional
        The observer's longitude [degrees]. Default is DOMEC's.
    seed : int
        Random seed.
    """

    r = np.random.RandomState(seed)
    nrandom = np.int(npointings /
                     nhwp_angles)  # number of real random pointings

    # Creation of nrandom pointing
    cosdtheta = np.cos(np.radians(dtheta))
    theta = np.degrees(np.arccos(cosdtheta +
                                 (1 - cosdtheta) * r.rand(nrandom)))
    phi = r.rand(nrandom) * 360
    pitch = r.rand(nrandom) * 360

    p = QubicSampling(nrandom,
                      date_obs=date_obs,
                      period=period,
                      latitude=latitude,
                      longitude=longitude)

    time = p.date_obs + TimeDelta(p.time, format='sec')

    c2s = Cartesian2SphericalOperator('azimuth,elevation', degrees=True)
    e2h = CartesianEquatorial2HorizontalOperator('NE', time, p.latitude,
                                                 p.longitude)
    rot = Rotation3dOperator("ZY'", center[0], 90 - center[1], degrees=True)
    s2c = Spherical2CartesianOperator('zenith,azimuth', degrees=True)
    rotation = c2s(e2h(rot(s2c)))
    coords = rotation(np.asarray([theta.T, phi.T]).T)

    p.azimuth = coords[..., 0]
    p.elevation = coords[..., 1]
    p.pitch = pitch
    p.fix_az = False

    # Replication of the same pointing with others fix hwp angles
    pp = QubicSampling(nrandom * nhwp_angles,
                       date_obs=date_obs,
                       period=period,
                       latitude=latitude,
                       longitude=longitude)

    pp.azimuth = np.tile(p.azimuth, nhwp_angles)
    pp.elevation = np.tile(p.elevation, nhwp_angles)
    pp.pitch = np.tile(p.pitch, nhwp_angles)
    pp.time = np.tile(p.time, nhwp_angles)
    pp.angle_hwp = np.zeros(nrandom * nhwp_angles)
    pp.fix_az = False
    for hwp in range(nhwp_angles):
        pp.angle_hwp[hwp * nrandom:(hwp + 1) * nrandom] = np.array(
            np.rad2deg(hwp * np.pi / (nhwp_angles * 2)))

    return pp
Example #8
0
def create_random_pointings(center,
                            npointings,
                            dtheta,
                            hwp_stepsize,
                            date_obs=None,
                            period=None,
                            latitude=None,
                            longitude=None,
                            seed=None):
    """
    Return pointings randomly and uniformly distributed in a spherical cap.

    1) Creates random coordinates theta, phi. Range: 0 < theta < dtheta, 0 < phi < 360 
    (then are converted from spherical to cartesian coordinates), 
    2) It rotates the points to center them in direction (RA, DEC) using Rotation3dOperator 
    (equatorial reference system)
    3) Convertion: Equatorial to Horizontal reference system 
    (using CartesianEquatorial2HorizontalOperator's operator) 
    4) Back to cartesian coordinates (using Cartesian2SphericalOperator) 

    Parameters
    ----------
    center : 2-tuple
        The R.A. and declination of the center of the FOV, in degrees.
    npointings : int
        The number of requested pointings
    dtheta : float
        The maximum angular distance to the center.
    hwp_stepsize : float
        Step angle size for the HWP.
    date_obs : str or astropy.time.Time, optional
        The starting date of the observation (UTC).
    period : float, optional
        The sampling period of the pointings, in seconds.
    latitude : float, optional
        The observer's latitude [degrees]. Default is DOMEC's.
    longitude : float, optional
        The observer's longitude [degrees]. Default is DOMEC's.
    seed : int
        Random seed.

    """

    r = np.random.RandomState(seed)

    cosdtheta = np.cos(np.radians(dtheta))
    theta = np.degrees(
        np.arccos(cosdtheta + (1 - cosdtheta) * r.rand(npointings)))
    phi = r.rand(npointings) * 360
    pitch = r.rand(npointings) * 360
    p = QubicSampling(npointings,
                      date_obs=date_obs,
                      period=period,
                      latitude=latitude,
                      longitude=longitude)
    time = p.date_obs + TimeDelta(p.time, format='sec')
    c2s = Cartesian2SphericalOperator('azimuth,elevation', degrees=True)
    e2h = CartesianEquatorial2HorizontalOperator('NE', time, p.latitude,
                                                 p.longitude)
    rot = Rotation3dOperator("ZY'", center[0], 90 - center[1], degrees=True)
    s2c = Spherical2CartesianOperator('zenith,azimuth', degrees=True)
    rotation = c2s(e2h(rot(s2c)))
    coords = rotation(np.asarray([theta.T, phi.T]).T)
    p.azimuth = coords[..., 0]
    p.elevation = coords[..., 1]
    p.pitch = pitch
    p.fix_az = False
    p.angle_hwp = r.randint(0, int(90 / hwp_stepsize + 1),
                            npointings) * hwp_stepsize
    return p
Example #9
0
 def func(c):
     r = Rotation3dOperator(c, alpha, beta, gamma)
     r2 = Rotation3dOperator(c[2], gamma) * \
          Rotation3dOperator(c[1], beta) * \
          Rotation3dOperator(c[0], alpha)
     assert_allclose(r(ref), r2(ref))