Esempio n. 1
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def compute_scale(wcs: WCS, fiducial: Union[tuple, np.ndarray]) -> float:
    """Compute scaling transform.

    Parameters
    ----------
    wcs : `~gwcs.wcs.WCS`
        Reference WCS object from which to compute a scaling factor.

    fiducial : tuple
        Input fiducial of (RA, DEC) used in calculating reference points.

    Returns
    -------
    scale : float
        Scaling factor for x and y.

    """
    if len(fiducial) != 2:
        raise ValueError(f'Input fiducial must contain only (RA, DEC); Instead recieved: {fiducial}')

    crpix = np.array(wcs.invert(*fiducial))
    crpix_with_offsets = np.vstack((crpix, crpix + (1, 0), crpix + (0, 1))).T
    crval_with_offsets = wcs(*crpix_with_offsets)

    coords = SkyCoord(ra=crval_with_offsets[0], dec=crval_with_offsets[1], unit="deg")
    xscale = np.abs(coords[0].separation(coords[1]).value)
    yscale = np.abs(coords[0].separation(coords[2]).value)

    return np.sqrt(xscale * yscale)
Esempio n. 2
0
def compute_scale(wcs: WCS,
                  fiducial: Union[tuple, np.ndarray],
                  disp_axis: int = None,
                  pscale_ratio: float = None) -> float:
    """Compute scaling transform.

    Parameters
    ----------
    wcs : `~gwcs.wcs.WCS`
        Reference WCS object from which to compute a scaling factor.

    fiducial : tuple
        Input fiducial of (RA, DEC) or (RA, DEC, Wavelength) used in calculating reference points.

    disp_axis : int
        Dispersion axis integer. Assumes the same convention as `wcsinfo.dispersion_direction`

    pscale_ratio : int
        Ratio of input to output pixel scale

    Returns
    -------
    scale : float
        Scaling factor for x and y or cross-dispersion direction.

    """
    spectral = 'SPECTRAL' in wcs.output_frame.axes_type

    if spectral and disp_axis is None:
        raise ValueError('If input WCS is spectral, a disp_axis must be given')

    crpix = np.array(wcs.invert(*fiducial))

    delta = np.zeros_like(crpix)
    spatial_idx = np.where(
        np.array(wcs.output_frame.axes_type) == 'SPATIAL')[0]
    delta[spatial_idx[0]] = 1

    crpix_with_offsets = np.vstack(
        (crpix, crpix + delta, crpix + np.roll(delta, 1))).T
    crval_with_offsets = wcs(*crpix_with_offsets)

    coords = SkyCoord(ra=crval_with_offsets[spatial_idx[0]],
                      dec=crval_with_offsets[spatial_idx[1]],
                      unit="deg")
    xscale = np.abs(coords[0].separation(coords[1]).value)
    yscale = np.abs(coords[0].separation(coords[2]).value)

    if pscale_ratio is not None:
        xscale = xscale * pscale_ratio
        yscale = yscale * pscale_ratio

    if spectral:
        # Assuming scale doesn't change with wavelength
        # Assuming disp_axis is consistent with DataModel.meta.wcsinfo.dispersion.direction
        return yscale if disp_axis == 1 else xscale

    return np.sqrt(xscale * yscale)