def __getCIPandCIOlocator(self,epoch: datetime.datetime):
        """
        Gets Celestial Intermediate Pole at epoch
        :param epoch:
        :return: X , Y of CIP
        """
        # Gets x,y coords of Celestial Intermediate Pole (CIP) and CIO locator s
        # CIO = Celestial Intermediate Origin
        # Both in GCRS

        mjd = pySat.pySatTime.UTC2MJD(epoch)
        Xcio, Ycio, Scio = erfa.xys06a(2400000.5, mjd)

        return  Xcio, Ycio, Scio
Exemplo n.º 2
0
def gcrs2irts_matrix_b(t, eop):
    """
    Ref: http://www.iausofa.org/sofa_pn_c.pdf
    Purpose:
        This function calculates the cartesian transformation matrix for transforming GCRS to ITRS or vice versa
    :param eop:
        eop is a dataframe containing the Earth Orientation Parameters as per IAU definitions
    :param t:
        t is a datetime object or a list of datetime objects with the UTC times for the transformation matrix to be
        calculated for
    :return:
        matrix is a [3,3] numpy array or list of arrays used for transforming GCRS to ITRS or vice versa at the
        specified times; ITRS = matrix @ GCRS
    """
    if not (isinstance(t, Iterable)):
        t = [t]
    matrix = []
    for ti in t:
        year = ti.year
        month = ti.month
        day = ti.day
        hour = ti.hour
        minute = ti.minute
        second = ti.second

        # TT (MJD). */
        djmjd0, date = erfa.cal2jd(iy=year, im=month, id=day)
        # jd = djmjd0 + date
        day_frac = (60.0 * (60.0 * hour + minute) + second) / DAYSEC
        utc = date + day_frac
        Dat = erfa.dat(year, month, day, day_frac)
        tai = utc + Dat / DAYSEC
        tt = tai + 32.184 / DAYSEC

        # UT1. */
        dut1 = eop["UT1-UTC"][date] * (
            1 - day_frac) + eop["UT1-UTC"][date + 1] * day_frac
        tut = day_frac + dut1 / DAYSEC
        # ut1 = date + tut

        # CIP and CIO, IAU 2006/2000A. */
        x, y, s = erfa.xys06a(djmjd0, tt)

        # X, Y offsets
        dx06 = (eop["dX"][date] *
                (1 - day_frac) + eop["dX"][date + 1] * day_frac) * DAS2R
        dy06 = (eop["dY"][date] *
                (1 - day_frac) + eop["dY"][date + 1] * day_frac) * DAS2R

        # Add CIP corrections. */
        x = x + dx06
        y = y + dy06

        # GCRS to CIRS matrix. */
        rc2i = erfa.c2ixys(x, y, s)

        # Earth rotation angle. */
        era = erfa.era00(djmjd0 + date, tut)

        # Form celestial-terrestrial matrix (no polar motion yet). */
        rc2ti = erfa.cr(rc2i)
        rc2ti = eraRZ(era, rc2ti)
        #rc2ti = erfa.rz(era, rc2ti)

        # Polar motion matrix (TIRS->ITRS, IERS 2003). */
        xp = (eop["x"][date] *
              (1 - day_frac) + eop["x"][date + 1] * day_frac) * DAS2R
        yp = (eop["y"][date] *
              (1 - day_frac) + eop["y"][date + 1] * day_frac) * DAS2R
        rpom = erfa.pom00(xp, yp, erfa.sp00(djmjd0, tt))

        # Form celestial-terrestrial matrix (including polar motion). */
        rc2it = erfa.rxr(rpom, rc2ti)
        matrix.append(rc2it)
    if len(matrix) == 1:
        matrix = matrix[0]
    return matrix