def __init__(self, ra0_deg, dec0_deg):
self.ra0_deg = ra0_deg
self.dec0_deg = dec0_deg
#Construct rotation matrix used to convert ra/dec into
#angle relative to tangent point
Rdec = rotate.declinationRotationMatrix(-self.dec0_deg)
Rra = rotate.rightAscensionRotationMatrix(-self.ra0_deg)
self.Rmatrix = np.dot(Rdec, Rra)
#Check I created the matrix correctly.
origin = rotate.vecFromRaDec(self.ra0_deg, self.dec0_deg)
origin = np.dot(self.Rmatrix, origin)
assert (np.fabs(origin[0] - 1) < 1e-9)
assert (np.fabs(origin[1]) < 1e-9)
assert (np.fabs(origin[2]) < 1e-9)
def __init__(self, ra0_deg, dec0_deg):
self.ra0_deg = ra0_deg
self.dec0_deg = dec0_deg
#Construct rotation matrix used to convert ra/dec into
#angle relative to tangent point
Rdec = rotate.declinationRotationMatrix(-self.dec0_deg)
Rra = rotate.rightAscensionRotationMatrix(-self.ra0_deg)
self.Rmatrix = np.dot(Rdec, Rra)
#Check I created the matrix correctly.
origin = rotate.vecFromRaDec(self.ra0_deg, self.dec0_deg)
origin = np.dot(self.Rmatrix, origin)
assert( np.fabs(origin[0] -1 ) < 1e-9)
assert( np.fabs(origin[1]) < 1e-9)
assert( np.fabs(origin[2]) < 1e-9)
def __init__(self, ra0_deg, dec0_deg):
Projection.__init__(self)
self.ra0_deg = ra0_deg
self.dec0_deg = dec0_deg
self.ra0_deg = ra0_deg
self.dec0_deg = dec0_deg
#This projection assumes ra ranges from -180 to +180
#if self.ra0_deg > 180:
#self.ra0_deg -= 360
#Construct rotation matrix used to convert ra/dec into
#angle relative to tangent point
Rdec = rotate.declinationRotationMatrix(-self.dec0_deg)
Rra = rotate.rightAscensionRotationMatrix(-self.ra0_deg)
self.Rmatrix = np.dot(Rra, Rdec)
def __init__(self, ra0_deg, dec0_deg):
Projection.__init__(self)
self.ra0_deg = ra0_deg
self.dec0_deg = dec0_deg
self.ra0_deg = ra0_deg
self.dec0_deg = dec0_deg
#This projection assumes ra ranges from -180 to +180
#if self.ra0_deg > 180:
#self.ra0_deg -= 360
#Construct rotation matrix used to convert ra/dec into
#angle relative to tangent point
Rdec = rotate.declinationRotationMatrix(-self.dec0_deg)
Rra = rotate.rightAscensionRotationMatrix(-self.ra0_deg)
self.Rmatrix = np.dot(Rra, Rdec)
def getPointing(self, ra_deg, dec_deg, roll_deg, cartesian=False):
"""Compute a pointing model without changing the internal object pointing"""
#Roll FOV
Rrotate = r.rotateAboutVectorMatrix([1,0,0], roll_deg) #Roll
#Slew to ra/dec of zero
Ra = r.rightAscensionRotationMatrix(ra_deg)
Rd = r.declinationRotationMatrix(dec_deg)
Rslew = np.dot(Ra, Rd)
R = np.dot(Rslew, Rrotate)
slew = self.origin*1
for i, row in enumerate(self.origin):
slew[i, 3:6] = np.dot(R, row[3:6])
if cartesian is False:
slew = self.getRaDecs(slew)
return slew
