Equatorial coordinate system
The equatorial coordinate system is probably the most widely used celestial coordinate system, whose
equatorial coordinates are:
* declination (δ)
* right ascension (α) -also RA-, or hour angle (H) -also HA-
It is the most closely related to the geographic coordinate system, because they use the same
fundamental plane, and the same poles. The projection of the Earth's equator onto the celestial
sphere is called the celestial equator. Similarly, projecting the geographic poles onto the
celestial sphere defines the north and south celestial poles.
There are two varieties:
* The hour angle system is fixed to the Earth like the geographic coordinate system
* The right ascension system is fixed to the stars, with the exception of precession and
nutation effects. Thus, during a night or a few nights, it appears to rotate across the sky with the
stars, but of course it's really the Earth rotating under the fixed sky. Because of the precession
and nutation just referred to, when considering long intervals between observations it is necessary
to specify an epoch (frequently J2000.0, for older data B1950.0) when specifying coordinates of
planets, stars, galaxies, etc.
Left A star is at culmination on an observer's meridian (HA = 0 h), then RA = LST. Right Now the
vernal equinox point is at culmination on the meridian m (LST = 0 h) (Positive angles: RA,
counterclockwise; HA and LST, clockwise)
Left A star is at culmination on an observer's meridian (HA = 0 h), then RA = LST. Right Now the
vernal equinox point is at culmination on the meridian m (LST = 0 h) (Positive angles: RA,
counterclockwise; HA and LST, clockwise)
The latitudinal (latitude-like) angle of the equatorial system is called declination (Dec for
short). It measures the angle of an object above or below the celestial equator. The longitudinal
angle is called the right ascension (RA for short). It measures the angle of an object east of the
vernal equinox point. Unlike longitude, right ascension is usually measured in hours instead of
degrees, because the apparent rotation of the equatorial coordinate system is closely related to
sidereal time and hour angle. Since a full rotation of the sky takes 24 hours to complete, there are
(360 degrees / 24 hours) = 15 degrees in one hour of right ascension.
The equatorial coordinate system is commonly used by telescopes equipped equatorial mounts by
employing Setting circles. Setting circles in conjunction with a star chart or ephemeris allow a
telescope to be easily pointed at known objects on the celestial sphere.