Broken/Azimuth

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An azimuth (/ˈæzɪməθ/ (About this soundlisten); from Arabic اَلسُّمُوت‎ as-sumūt, “the directions”, the plural form of the Arabic noun السَّمْت as-samt, meaning "the direction") is an angular measurement in a spherical coordinate system. The vector from an observer (origin) to a point of interest is projected perpendicularly onto a reference plane; the angle between the projected vector and a reference vector on the reference plane is called the azimuth.

When used as a celestial coordinate, the azimuth is the horizontal direction of a star or other astronomical object in the sky. The star is the point of interest, the reference plane is the local area (e.g. a circular area 5 km in radius at sea level) around an observer on Earth's surface, and the reference vector points to true north. The azimuth is the angle between the north vector and the star's vector on the horizontal plane.[1]

Azimuth is usually measured in degrees (°). The concept is used in navigation, astronomy, engineering, mapping, mining, and ballistics.

Navigation

Azimuth Marker, Mount Allen (Sandstone Peak), Southern California, USA.

In land navigation, azimuth is usually denoted alpha, α, and defined as a horizontal angle measured clockwise from a north base line or meridian.[2][3] Azimuth has also been more generally defined as a horizontal angle measured clockwise from any fixed reference plane or easily established base direction line.[4][5][6]

Today, the reference plane for an azimuth is typically true north, measured as a 0° azimuth, though other angular units (grad, mil) can be used. Moving clockwise on a 360 degree circle, east has azimuth 90°, south 180°, and west 270°. There are exceptions: some navigation systems use south as the reference vector. Any direction can be the reference vector, as long as it is clearly defined.

Quite commonly, azimuths or compass bearings are stated in a system in which either north or south can be the zero, and the angle may be measured clockwise or anticlockwise from the zero. For example, a bearing might be described as "(from) south, (turn) thirty degrees (toward the) east" (the words in brackets are usually omitted), abbreviated "S30°E", which is the bearing 30 degrees in the eastward direction from south, i.e. the bearing 150 degrees clockwise from north. The reference direction, stated first, is always north or south, and the turning direction, stated last, is east or west. The directions are chosen so that the angle, stated between them, is positive, between zero and 90 degrees. If the bearing happens to be exactly in the direction of one of the cardinal points, a different notation, e.g. "due east", is used instead.

True north-based azimuths

From north
North South 180°
North-northeast 22.5° South-southwest 202.5°
Northeast 45° Southwest 225°
East-northeast 67.5° West-southwest 247.5°
East 90° West 270°
East-southeast 112.5° West-northwest 292.5°
Southeast 135° Northwest 315°
South-southeast 157.5° North-northwest 337.5°

Cartographical azimuth

The cartographical azimuth (in decimal degrees) can be calculated when the coordinates of 2 points are known in a flat plane (cartographical coordinates):

[math]\displaystyle{ \alpha = \frac{180}{\pi} \operatorname{atan2}(X_2 - X_1, Y_2 - Y_1) }[/math]

Remark that the reference axes are swapped relative to the (counterclockwise) mathematical polar coordinate system and that the azimuth is clockwise relative to the north. This is the reason why the X and Y axis in the above formula are swapped. If the azimuth becomes negative, one can always add 360°.

The formula in radians would be slightly easier:

[math]\displaystyle{ \alpha = \operatorname{atan2}(X_2 - X_1, Y_2 - Y_1) }[/math]
Caveat: Most computer libraries (C/C++, Python, Java, ...) reverse the order of the atan2 parameters.

Calculating coordinates

When the coordinates (X1, Y1) of one point, the distance L, and the azimuth α to another point (X2, Y2) are known, one can calculate its coordinates:

[math]\displaystyle{ \begin{align} X_2 &= X_1 + L \sin\alpha \\ Y_2 &= Y_1 + L \cos\alpha \end{align} }[/math]

This is typically used in triangulation.

Calculating azimuth

The azimuth between Cape Town and Melbourne along the geodesic (the shortest route) changes from 141° to 42°. Azimuthal orthographic projection and Miller cylindrical projection.

We are standing at latitude [math]\displaystyle{ \varphi_1 }[/math], longitude zero; we want to find the azimuth from our viewpoint to Point 2 at latitude [math]\displaystyle{ \varphi_2 }[/math], longitude L (positive eastward). We can get a fair approximation by assuming the Earth is a sphere, in which case the azimuth α is given by

[math]\displaystyle{ \tan\alpha = \frac{\sin L}{\cos\varphi_1 \tan\varphi_2 - \sin\varphi_1 \cos L} }[/math]

A better approximation assumes the Earth is a slightly-squashed sphere (an oblate spheroid); azimuth then has at least two very slightly different meanings. Normal-section azimuth is the angle measured at our viewpoint by a theodolite whose axis is perpendicular to the surface of the spheroid; geodetic azimuth is the angle between north and the geodesic; that is, the shortest path on the surface of the spheroid from our viewpoint to Point 2. The difference is usually immeasurably small; if Point 2 is not more than 100 km away, the difference will not exceed 0.03 arc second.

Various websites will calculate geodetic azimuth; e.g., GeoScience Australia site. Formulas for calculating geodetic azimuth are linked in the distance article.

Normal-section azimuth is simpler to calculate; Bomford says Cunningham's formula is exact for any distance.[citation needed] If f is the flattening, and e the eccentricity, for the chosen spheroid (e.g., ​1298.257223563 for WGS84) then

[math]\displaystyle{ \begin{align} e^2 &= f(2 - f) \\ 1 - e^2 &= (1 - f)^2 \\ \Lambda &= \left(1 - e^2\right) \frac{\tan\varphi_2}{\tan\varphi_1} + e^2 \sqrt{\frac{1 + \left(1 - e^2\right)\left(\tan\varphi_2\right)^2} {1 + \left(1 - e^2\right)\left(\tan\varphi_1\right)^2}} \\ \tan\alpha &= \frac{\sin L}{(\Lambda - \cos L)\sin\varphi_1} \end{align} }[/math]

If φ1 = 0 then

[math]\displaystyle{ \tan\alpha = \frac{\sin L}{\left(1 - e^2\right)\tan\varphi_2} }[/math]

To calculate the azimuth of the sun or a star given its declination and hour angle at our location, we modify the formula for a spherical earth. Replace φ2 with declination and longitude difference with hour angle, and change the sign (since the hour angle is positive westward instead of east).

Mapping

There is a wide variety of azimuthal map projections. They all have the property that directions (the azimuths) from a central point are preserved. Some navigation systems use south as the reference plane. However, any direction can serve as the plane of reference, as long as it is clearly defined for everyone using that system.

A standard Brunton Geo compass, commonly used by geologists and surveyors to measure azimuth
Comparison of some azimuthal projections centred on 90° N at the same scale, ordered by projection altitude in Earth radii. (click for detail)

Astronomy

Used in celestial navigation, an azimuth is the direction of a celestial body from the observer.[7] In astronomy, an azimuth is sometimes referred to as a bearing. In modern astronomy azimuth is nearly always measured from the north. (The article on coordinate systems, for example, uses a convention measuring from the south.) In former times, it was common to refer to azimuth from the south, as it was then zero at the same time that the hour angle of a star was zero. This assumes, however, that the star (upper) culminates in the south, which is only true if the star's declination is less than (i.e. further south than) the observer's latitude.

Other systems

Right ascension

If, instead of measuring from and along the horizon, the angles are measured from and along the celestial equator, the angles are called right ascension if referenced to the Vernal Equinox, or hour angle if referenced to the celestial meridian.

Horizontal coordinate

In the horizontal coordinate system, used in celestial navigation and satellite dish installation, azimuth is one of the two coordinates. The other is altitude, sometimes called elevation above the horizon. See also: Sat finder.

Polar coordinate

In mathematics, the azimuth angle of a point in cylindrical coordinates or spherical coordinates is the anticlockwise angle between the positive x-axis and the projection of the vector onto the xy-plane. The angle is the same as an angle in polar coordinates of the component of the vector in the xy-plane and is normally measured in radians rather than degrees. As well as measuring the angle differently, in mathematical applications theta, θ, is very often used to represent the azimuth rather than the representation of symbol phi φ.

  1. "Azimuth". Dictionary.com. http://dictionary.reference.com/browse/azimuth. 
  2. U.S. Army, Map Reading and Land Navigation, FM 21–26, Headquarters, Dept. of the Army, Washington, D.C. (7 May 1993), ch. 6, p. 2
  3. U.S. Army, Map Reading and Land Navigation, FM 21–26, Headquarters, Dept. of the Army, Washington, D.C. (28 March 1956), ch. 3, p. 63
  4. U.S. Army, ch. 6 p. 2
  5. U.S. Army, Advanced Map and Aerial Photograph Reading, Headquarters, War Department, Washington, D.C. (17 September 1941), pp. 24–25
  6. U.S. Army, Advanced Map and Aerial Photograph Reading, Headquarters, War Department, Washington, D.C. (23 December 1944), p. 15
  7. Rutstrum, Carl, The Wilderness Route Finder, University of Minnesota Press (2000), ISBN:0-8166-3661-3, p. 194

References

  • Rutstrum, Carl, The Wilderness Route Finder, University of Minnesota Press (2000), ISBN:0-8166-3661-3
  • U.S. Army, Advanced Map and Aerial Photograph Reading, FM 21–26, Headquarters, War Department, Washington, D.C. (17 September 1941)
  • U.S. Army, Advanced Map and Aerial Photograph Reading, FM 21–26, Headquarters, War Department, Washington, D.C. (23 December 1944)
  • U.S. Army, Map Reading and Land Navigation, FM 21–26, Headquarters, Dept. of the Army, Washington, D.C. (7 May 1993)

External links