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In astronomy, the culmination, at a given point, of a planet, star, constellation, etc. is the time within the diurnal motion when it appears on an observer's meridian.## The Sun, examples

Suppose at some day the declination of the Sun is +20°, then at a latitude of 52°N, where the celestial pole is at an altitude of 52°, we add or subtract the distance from the Sun to the pole, which is 70°. We get the upper culmination at 122°, is 58° in the south, and the lower at -18°, below the horizon, in the north.

In general use, culmination refers to completion or fulfillment.## See also

During a sidereal day, an astronomical object will cross the meridian twice: once at its upper culmination, when it is at its highest point as seen from the earth, and once at its lower culmination, its lowest point. Often, culmination is used to mean upper culmination.

The altitude of an object in degrees at its upper culmination is equal to (90 - l + d), where l is the observer's latitude, and d is the object's declination.

Generally, the sun is visible at its upper culmination (noon) and not visible at its lower culmination. But during winter near the North Pole, the sun is below the horizon at both of its culminations. In most of the northern hemisphere, Polaris, the "North Star", and the rest of the stars of the constellation Ursa Minor can be seen to rotate around the Celestial pole and are all visible at both culminations, as long as the sky is dark enough.

These three examples illustrate all three cases, dependent on the latitude of the observer and the declination of the celestial body.

- the upper culmination is above, and the lower below the horizon; in the other cases (i.e. if in absolute value the declination is less than the colatitude)
- the object is above the horizon even at its lower culmination: it is circumpolar; i.e. if |declination + latitude| > 90° (i.e. if in absolute value the declination is more than the colatitude, in the corresponding hemisphere)
- the object is below the horizon even at its upper culmination; i.e. if |declination - latitude| > 90° (i.e. if in absolute value the declination is more than the colatitude, in the opposite hemisphere)

The third case applies for objects in a part of the full sky equal to the cosine of the latitude (at the equator it applies for all objects, the sky turns around the horizontal north-south line; at the Poles it applies for none, the sky turns around the vertical line). The first and second case apply each for half of the remaining sky.

The time from one upper culmination to the next is approximately 24 hours, and from an upper to a lower culmination approximately 12 hours. The movement of the Earth on its orbit and proper motion of the celestial body affect the time between successive upper culminations of the body. Because of the proper and improper motions of the sun, one solar day (the time between two upper culminations of the sun) is longer than one sidereal day (the time between two like culminations of any fixed star). The mean difference is 1/365.24219 because the Earth needs 365.24219 days for its orbit around the Sun. (see also sidereal day)

At a latitude of 80°N we get the upper culmination at 30°, in the south, and the lower at 10°, also above the horizon (midnight sun), in the north.

In general use, culmination refers to completion or fulfillment.

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Last updated on Tuesday August 26, 2008 at 18:19:28 PDT (GMT -0700)

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This article is licensed under the GNU Free Documentation License.

Last updated on Tuesday August 26, 2008 at 18:19:28 PDT (GMT -0700)

View this article at Wikipedia.org - Edit this article at Wikipedia.org - Donate to the Wikimedia Foundation

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