![]() ![]() ![]() We like to do it by defining one to three research questions. When viewed from the equator, objects on the celestial poles stay at fixed points, perched on the horizon.In the beginning, it is crucial to narrow down your topic.The Sun, Moon, and planets can rise or set over the span of a year when viewed from the poles because their declinations are constantly changing. When viewed from either pole, a star (or any object with fixed equatorial coordinates) has constant altitude and thus never rises or sets. All directions are south when viewed from the North Pole, and all directions are north when viewed from the South Pole, so the azimuth is undefined in both locations.If the azimuth is between 180° and 360° (south–west–north), the object is setting.If the azimuth is between 0° and 180° (north–east–south), the object is rising.However, all objects on the celestial sphere are subject to diurnal motion, which always appears to be westward.Ī northern observer can determine whether altitude is increasing or decreasing by instead considering the azimuth of the celestial object: If at that moment its altitude is increasing, it is rising, but if its altitude is decreasing, it is setting. When an object's altitude is 0°, it is on the horizon. Horizontal coordinates are very useful for determining the rise and set times of an object in the sky. The cardinal points on the horizon have specific values of azimuth that are helpful references.Īzimuth values for the cardinal directions In addition, since the horizontal system is defined by the observer's local horizon, the same object viewed from different locations on Earth at the same time will have different values of altitude and azimuth. Therefore, the altitude and azimuth of an object in the sky changes with time, as the object appears to drift across the sky with Earth's rotation. The horizontal coordinate system is fixed to a location on Earth, not the stars. Horizontal coordinates define the observer's orientation, but not location of the origin, while topocentric coordinates define the origin location, on the Earth's surface, in contrast to a geocentric celestial system. Exceptions are, for example, ESO's FITS convention where it is measured from the south and increasing westward, or the FITS convention of the Sloan Digital Sky Survey where it is measured from the south and increasing eastward.Ī horizontal coordinate system should not be confused with a topocentric coordinate system. Azimuth (az.) is the angle of the object around the horizon, usually measured from true north and increasing eastward.For visible objects, it is an angle between 0° and 90°. ![]() Altitude (alt.), sometimes referred to as elevation (el.) or apparent height, is the angle between the object and the observer's local horizon.The following are two independent horizontal angular coordinates: The pole of the lower hemisphere is called the nadir. The pole of the upper hemisphere is called the zenith. In practice, the horizon can be defined as the plane tangent to a quiet, liquid surface, such as a pool of mercury. The great circle separating the hemispheres is called the celestial horizon, which is defined as the great circle on the celestial sphere whose plane is normal to the local gravity vector. This celestial coordinate system divides the sky into two hemispheres: The upper hemisphere, where objects are above the horizon and are visible, and the lower hemisphere, where objects are below the horizon and cannot be seen, since the Earth obstructs views of them. In an altazimuth mount of a telescope, the instrument's two axes follow altitude and azimuth. Therefore, the horizontal coordinate system is sometimes called as the az/el system, the alt/az system, or the alt-azimuth system, among others. The horizontal coordinate system is a celestial coordinate system that uses the observer's local horizon as the fundamental plane to define two angles: altitude and azimuth. Azimuth is measured eastward from the north point (sometimes from the south point) of the horizon altitude is the angle above the horizon. Horizontal coordinates use a celestial sphere centered on the observer. ![]()
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