The radian is the standard unit of angular measure, used in many areas of mathematics. An angle's measurement in radians is numerically equal to the length of a corresponding arc of a unit circle, so one radian is just under 57.3 degrees (when the arc length is equal to the radius). The unit was formerly an SI supplementary unit, but this category was abolished in 1995 and the radian is now considered an SI derived unit. The SI unit of solid angle measurement is the steradian.
The radian is represented by the symbol "rad" or, more rarely, by the superscript c (for "circular measure"). For example, an angle of 1.2 radians would be written as "1.2 rad" or "1.2c" (the latter symbol is often mistaken for a degree: "1.2°").
- 1 Definition
- 2 History
- 3 Conversions
- 4 Advantages of measuring in radians
- 5 Dimensional analysis
- 6 Use in physics
- 7 Multiples of radian units
- 8 See also
- 9 Notes and references
- 10 External links
Radian describes the plane angle subtended by a circular arc as the length of the arc divided by the radius of the arc. One radian is the angle subtended at the center of a circle by an arc that is equal in length to the radius of the circle. More generally, the magnitude in radians of such a subtended angle is equal to the ratio of the arc length to the radius of the circle; that is, θ = s /r, where θ is the subtended angle in radians, s is arc length, and r is radius. Conversely, the length of the enclosed arc is equal to the radius multiplied by the magnitude of the angle in radians; that is, s = rθ. As the ratio of two lengths, the radian is a "pure number" that needs no unit symbol, and in mathematical writing the symbol "rad" is almost always omitted. In the absence of any symbol radians are assumed, and when degrees are meant the symbol ° is used.
It follows that the magnitude in radians of one complete revolution (360 degrees) is the length of the entire circumference divided by the radius, or 2πr /r, or 2π. Thus 2π radians is equal to 360 degrees, meaning that one radian is equal to 180/π degrees.
The concept of radian measure, as opposed to the degree of an angle, is normally credited to Roger Cotes in 1714. He had the radian in everything but name, and he recognized its naturalness as a unit of angular measure. The idea of measuring angles by the length of the arc was used already by other mathematicians. For example al-Kashi (c. 1400) used so-called diameter parts as units where one diameter part was 1 radian and they also used sexagesimal subunits of the diameter part.
The term radian first appeared in print on 5 June 1873, in examination questions set by James Thomson (brother of Lord Kelvin) at Queen's College, Belfast. He used the term as early as 1871, while in 1869, Thomas Muir, then of the University of St Andrews, vacillated between rad, radial and radian. In 1874, Muir adopted radian after a consultation with James Thomson.
Conversion between radians and degrees
As stated, one radian is equal to 180/π degrees. Thus, to convert from radians to degrees, multiply by 180/π.
Conversely, to convert from degrees to radians, multiply by π/180.
Radians can be converted to turns by dividing the number of radians by 2π.
Radian to degree conversion derivation
The length of circumference of a circle is given by , where is the radius of the circle.
So the following equivalent relation is true:
[Since a sweep is needed to draw a full circle]
By the definition of radian, a full circle represents:
Combining both the above relations:
Conversion between radians and grads
Conversion of some common angles
The table shows the conversion of some common angles.
|Grads||0g||16 2g||33 1g||40g||50g||66 2g||80g||100g||133 1g||160g||200g||300g||400g|
Advantages of measuring in radians
In calculus and most other branches of mathematics beyond practical geometry, angles are universally measured in radians. This is because radians have a mathematical "naturalness" that leads to a more elegant formulation of a number of important results.
Most notably, results in analysis involving trigonometric functions are simple and elegant when the functions' arguments are expressed in radians. For example, the use of radians leads to the simple limit formula
which is the basis of many other identities in mathematics, including
Because of these and other properties, the trigonometric functions appear in solutions to mathematical problems that are not obviously related to the functions' geometrical meanings (for example, the solutions to the differential equation , the evaluation of the integral , and so on). In all such cases it is found that the arguments to the functions are most naturally written in the form that corresponds, in geometrical contexts, to the radian measurement of angles.
The trigonometric functions also have simple and elegant series expansions when radians are used; for example, the following Taylor series for sin x :
If x were expressed in degrees then the series would contain messy factors involving powers of π/180: if x is the number of degrees, the number of radians is y = πx /180, so
Mathematically important relationships between the sine and cosine functions and the exponential function (see, for example, Euler's formula) are, again, elegant when the functions' arguments are in radians and messy otherwise.
Although the radian is a unit of measure, it is a dimensionless quantity. This can be seen from the definition given earlier: the angle subtended at the centre of a circle, measured in radians, is equal to the ratio of the length of the enclosed arc to the length of the circle's radius. Since the units of measurement cancel, this ratio is dimensionless.
Although polar and spherical coordinates use radians to describe coordinates in two and three dimensions, the unit is derived from the radius coordinate, so the angle measure is still dimensionless.
Use in physics
The radian is widely used in physics when angular measurements are required. For example, angular velocity is typically measured in radians per second (rad/s). One revolution per second is equal to 2π radians per second.
Similarly, angular acceleration is often measured in radians per second per second (rad/s2).
For the purpose of dimensional analysis, the units are s−1 and s−2 respectively.
Likewise, the phase difference of two waves can also be measured in radians. For example, if the phase difference of two waves is (k·2π) radians, where k is an integer, they are considered in phase, whilst if the phase difference of two waves is (k·2π + π), where k is an integer, they are considered in antiphase.
Multiples of radian units
Metric prefixes have limited use with radians, and none in mathematics.
There are 2π × 1000 milliradians (≈ 6283.185 mrad) in a circle. So a trigonometric milliradian is just under 1⁄6283 of a circle. This “real” trigonometric unit of angular measurement of a circle is in use by telescopic sight manufacturers using (stadiametric) rangefinding in reticles. The divergence of laser beams is also usually measured in milliradians.
An approximation of the trigonometric milliradian (0.001 rad), known as the (angular) mil, is used by NATO and other military organizations in gunnery and targeting. Each angular mil represents 1⁄6400 of a circle and is 1-⅞% smaller than the trigonometric milliradian. For the small angles typically found in targeting work, the convenience of using the number 6400 in calculation outweighs the small mathematical errors it introduces. In the past, other gunnery systems have used different approximations to 1⁄2000π; for example Sweden used the 1⁄6300 streck and the USSR used 1⁄6000. Being based on the milliradian, the NATO mil subtends roughly 1 m at a range of 1000 m (at such small angles, the curvature is negligible).
Smaller units like microradians (μrad) and nanoradians (nrad) are used in astronomy, and can also be used to measure the beam quality of lasers with ultra-low divergence. Similarly, the prefixes smaller than milli- are potentially useful in measuring extremely small angles.
- Angular frequency
- Angular mil - military measurement
- Harmonic analysis
- Steradian - the "square radian"
Notes and references
- O'Connor, J. J.; Robertson, E. F. (February 2005). "Biography of Roger Cotes". The MacTutor History of Mathematics.
- Luckey, Paul (1953) [Translation of 1424 book]. Siggel, A., ed. Der Lehrbrief über den kreisumfang von Gamshid b. Mas'ud al-Kasi [Treatise on the Circumference of al-Kashi] (6). Berlin: Akademie Verlag. p. 40.
- Cajori, Florian (1929). History of Mathematical Notations 2. pp. 147–148. ISBN 0-486-67766-4.
- Muir, Thos. (1910). "The Term "Radian" in Trigonometry". Nature 83 (2110): 156. Bibcode:1910Natur..83..156M. doi:10.1038/083156a0.Thomson, James (1910). "The Term "Radian" in Trigonometry". Nature 83 (2112): 217. Bibcode:1910Natur..83..217T. doi:10.1038/083217c0.Muir, Thos. (1910). "The Term "Radian" in Trigonometry". Nature 83 (2120): 459–460. Bibcode:1910Natur..83..459M. doi:10.1038/083459d0.
- Miller, Jeff (Nov. 23, 2009). "Earliest Known Uses of Some of the Words of Mathematics". Retrieved Sep. 30, 2011.
- For a debate on this meaning and use see: Brownstein, K. R. (1997). "Angles—Let's treat them squarely". American Journal of Physics 65 (7): 605. Bibcode:1997AmJPh..65..605B. doi:10.1119/1.18616., Romain, J.E. (1962). "Angles as a fourth fundamental quantity". Journal of Research of the National Bureau of Standards-B. Mathematics and Mathematical Physics 66B (3): 97., LéVy-Leblond, Jean-Marc (1998). "Dimensional angles and universal constants". American Journal of Physics 66 (9): 814. Bibcode:1998AmJPh..66..814L. doi:10.1119/1.18964., and Romer, Robert H. (1999). "Units—SI-Only, or Multicultural Diversity?". American Journal of Physics 67: 13. Bibcode:1999AmJPh..67...13R. doi:10.1119/1.19185.
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