Parallactic angle


In spherical astronomy, the parallactic angle is the angle between the great circle through a celestial object and the zenith, and the hour circle of the object. It is usually denoted q. In the triangle zenith—object—celestial pole, the parallactic angle will be the position angle of the zenith at the celestial object. Despite its name, this angle is unrelated with parallax. The parallactic angle is zero or 180° when the object crosses the meridian.

Uses

For ground-based observatories, the Earth atmosphere acts like a prism which disperses light
of different wavelengths such that a star generates a rainbow along the direction that points
to the zenith. So given an astronomical picture with a coordinate system with a known direction
to the North Celestial Pole, the parallactic angle represents the direction of that prismatic effect relative
to that reference direction.
Depending on the type of mount of the telescope, this angle may also affect the orientation of the celestial object's disk as seen in a telescope. With an equatorial mount, the cardinal points of the celestial object's disk are aligned with the vertical and horizontal direction of the view in the telescope. With an altazimuth mount, those directions are rotated by the amount of the parallactic angle. The cardinal points referred to here are the points on the limb located such that a line from the center of the disk through them will point to one of the celestial poles or 90° away from them; these are not the cardinal points defined by the object's axis of rotation.
The orientation of the disk of the Moon, as related to the horizon, changes throughout its diurnal motion and the parallactic angle changes equivalently. This is also the case with other celestial objects.
In an ephemeris, the position angle of the midpoint of the bright limb of the Moon or planets, and the position angles of their North poles may be tabulated. If this angle is measured from the North point on the limb, it can be converted to an angle measured from the zenith point as seen by an observer by subtracting the parallactic angle. The position angle of the bright limb is directly related to that of the subsolar point.

Derivation

The vector algebra to derive the standard formula is equivalent to the calculation of the
long derivation for the compass course.
The sign of the angle is basically kept, north over east in both cases,
but as astronomers look at stars from the inside of the celestial sphere,
the definition uses the convention that the is the angle in an image that turns the direction to the NCP counterclockwise into the direction of the zenith.
In the equatorial system of right ascension and declination
the star is at
In the same coordinate system the zenith is found by inserting,
into the transformation formulas
where is the observer's geographic latitude, the star's altitude,
the zenith distance, and the local sidereal time. The North Celestial Pole is at
The normalized cross product is the rotation axis that turns the star into the direction of the zenith:
Finally is the third axis of the tilted coordinate system and the direction into which the star is moved on the great circle towards the zenith.
The plane tangential to the celestial sphere at the star is spanned by the unit vectors to the north,
and to the east
These are orthogonal:
The parallactic angle is the angle of the initial section of the great circle
at s, east of north,
The values of and of are positive, so using atan2 functions one may
divide both expressions through these without losing signs; eventually
yields the angle in the full range. The advantage of this expression is that it
does not depend on the various offset conventions of ; the uncontroversial offset
of the hour angle
takes care of this.
For a sidereal target, by definition a target where and are not time-dependent,
the angle changes with a period of a sidereal day.
Let dots denote time derivatives; then the hour angle changes as
and the time derivative of the expression is