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Ellipse

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{{otheruses}} ''Elliptical redirects here, for the exercise machine, see Elliptical trainer.'' Image:Elipse.png thumb|right|200px|The ellipse and some of its mathematical properties. In mathematics, an '''ellipse''' (from the Greek language Greek for ''absence'') is a plane algebraic curve where the sum of the distances from any point on the curve to two fixed points is constant. The two fixed points are called '''foci''' (plural of '''focus (geometry) focus'''). An ellipse is a type of conic section: if a conical surface is cut with a plane which does not intersect the cone's base, the intersection of the cone and plane is an ellipse. For a short elementary proof of this, see Dandelin spheres. Algebraically, an ellipse is a curve in the Cartesian coordinate system Cartesian plane defined by an equation of the form :$A\; x^2\; +\; B\; xy\; +\; C\; y^2\; +\; D\; x\; +\; E\; y\; +\; F\; =\; 0$ such that , where all of the coefficients are real, and where more than one solution, defining a pair of points (x, y) on the ellipse, exists. An ellipse can be drawn with two pins, a loop of string, and a pencil. The pins are placed at the foci and the pins and pencil are enclosed inside the string. The pencil is placed on the paper inside the string, so the string is taut. The string will form a triangle. If the pencil is moved around so that the string stays taut, the sum of the distances from the pencil to the pins will remain constant, satisfying the definition of an ellipse. The line segment which passes through the foci and terminates on the ellipse is called the '''major axis'''. The major axis is along the longest segment that passes through the ellipse. The line which passes through the center (halfway between the foci), at right angles to the major axis, is called the '''minor axis'''. A '''semimajor axis''' is one half the major axis: the line segment from the center, through a focus, and to the edge of the ellipse. Likewise, the '''semiminor axis''' is one half the minor axis. If the two foci coincide, then the ellipse is a circle; in other words, a circle is a special case of an ellipse, one where the eccentricity is zero. An ellipse centred at the Origin (mathematics) origin can be viewed as the image of the unit circle under a linear map associated with a symmetric matrix $A\; =\; PDP^T$, D being a diagonal matrix with the eigenvalues of A, both of which are real positive, along the main diagonal, and P being a real unitary matrix having as columns the eigenvectors of A. Then the axes of the ellipse will lie along the eigenvectors of A, and the squares of the lengths of the axes are the inverses of the eigenvalues.

Parametrisation
The size of an ellipse is determined by two constants, conventionally denoted ''a'' and ''b''. The constant ''a'' equality (mathematics) equals the length of the semimajor axis; the constant ''b'' equals the length of the semiminor axis. Image:Elpsminr.png center|Ellipse, showing major and minor axes An ellipse centered at the origin of an ''x''-''y'' coordinate system with its major axis along the ''x''-axis is defined by the equation :$\backslash frac\{x^\{2\}\}\{a^\{2\}\}\; +\; \backslash frac\{y^\{2\}\}\{b^\{2\}\}\; =\; 1$ The Derivation of the cartesian formula for an ellipse derivation of this formula is quite instructive and not overly difficult. The following diagram shows an ellipse demonstrating the Pythagoras equation ''a''² = ''b''² + ''c''² as a special case of the non-parametric equation above (''x''=0, ''y''=b). Image:Ellipse_PLS_en.png center The same ellipse is also represented by the parametric equations: :$x\; =\; a\backslash ,\backslash cos\; t$ :$y\; =\; b\backslash ,\backslash sin\; t$ : which use the trigonometric functions sine and cosine. If an ellipse is not centered at the origin of an ''x''-''y'' coordinate system, but again has its major axis along the ''x''-axis, it may be specified by the equation :$\backslash frac\{(x-h)^\{2\}\}\{a^\{2\}\}\; +\; \backslash frac\{(y-k)^\{2\}\}\{b^\{2\}\}\; =\; 1$ where (h,k) is the center. A Gauss map Gauss-mapped form: :$\backslash left(\backslash frac\{a^2\backslash cos\backslash phi\}\{\backslash sqrt\{a^2\backslash cos^2\backslash phi+b^2\backslash sin^2\backslash phi\}\},\backslash frac\{b^2\backslash sin\backslash phi\}\{\backslash sqrt\{a^2\backslash cos^2\backslash phi+b^2\backslash sin^2\backslash phi\}\}\backslash right)$ has normal $(\backslash cos\backslash phi,\backslash sin\backslash phi)$.

Eccentricity
The shape of an ellipse is usually expressed by a number called the eccentricity (mathematics) eccentricity of the ellipse, conventionally denoted ''e'' (not to be confused with the mathematical constant e (mathematical constant) e). The eccentricity is related to ''a'' and ''b'' by the statement :$e\; =\; \backslash sqrt\{1\; -\; \backslash frac\{b^2\}\{a^2\}\}$ or where $c$ (the linear eccentricity of the ellipse) equals the distance from the center to either focus :$e\; =\; \backslash frac\{c\}\{a\}$ The eccentricity is a negative and non-negative numbers positive number less than 1, or 0 in the case of a circle. The greater the eccentricity is, the larger the ratio of ''a'' to ''b'' is, and therefore the more elongated the ellipse is. The ellipse shown in the image below has an eccentricity of approximately 0.8733. The distance between the foci is 2''ae''.

Semi-latus rectum and polar coordinates
The ''semi-latus rectum'' of an ellipse, usually denoted $l\backslash ,\backslash !$ (lowercase L), is the distance from a focus of the ellipse to the ellipse itself, measured along a line perpendicular to the major axis. It is related to $a\backslash ,\backslash !$ and $b\backslash ,\backslash !$ (the ellipse's semi-axes) by the formula $al=b^2\backslash ,\backslash !$ or, if using the eccentricity, $l=a(1-e^2)\backslash ,\backslash !$. Image:Elps-slr.png center|Ellipse, showing semi-latus rectum In coordinates (elementary mathematics) polar coordinates, an ellipse with one focus at the origin and the other on the negative ''x''-axis is given by the equation : $r\; (1\; +\; e\; \backslash cos\; \backslash theta)\; =\; l\; \backslash ,\backslash !$ An ellipse can also be thought of as a projection of a circle: a circle on a plane at angle φ to the horizontal projected vertically onto a horizontal plane gives an ellipse of eccentricity sin φ, provided φ is not 90°.

Area
The area (geometry) area enclosed by an ellipse is $\backslash pi\; ab\backslash ,\backslash !$, where $\backslash pi$ is Pi Archimedes' constant.

Circumference
The circumference of an ellipse is 4''aE''(''e''), where the function ''E'' is the complete elliptic integral of the second kind. The exact infinite series is: :$c\; =\; 2\backslash pi\; a\; \backslash left[\{1\; -\; \backslash left(\{1\backslash over\; 2\}\backslash right)^2e^2\; -\; \backslash left(\{1\backslash cdot\; 3\backslash over\; 2\backslash cdot\; 4\}\backslash right)^2\{e^4\backslash over\; 3\}\; -\; \backslash left(\{1\backslash cdot\; 3\backslash cdot\; 5\backslash over\; 2\backslash cdot\; 4\backslash cdot\; 6\}\backslash right)^2\{e^6\backslash over5\}\; -\; \backslash dots\}\backslash right]\backslash !\backslash ,$ A good approximation is Ramanujan's: :$c\; \backslash approx\; \backslash pi\; \backslash left[3(a+b)\; -\; \backslash sqrt\{(3a+b)(a+3b)\}\backslash right]\backslash !\backslash ,$ which can also be written as: :$c\; \backslash approx\; \backslash pi\; a\; \backslash left[\; 3\; (1+\backslash sqrt\{1-e^2\})\; -\; \backslash sqrt\{(3+\; \backslash sqrt\{1-e^2\})(1+3\; \backslash sqrt\{1-e^2\})\}\; \backslash right]\; \backslash !\backslash ,$ More generally, the arc length of a portion of the circumference, as a function of the angle subtended, is given by an incomplete elliptic integral. The inverse function, the angle subtended as a function of the arc length, is given by the elliptic functions.

Stretching and Projection
An ellipse may be uniformly stretched along any axis, in or out of the plane of the ellipse, and it will still be an ellipse. The stretched ellipse will have different properties (perhaps changed eccentricity and semi-major axis length, for instance), but it will still be an ellipse (or a degenerate ellipse: a circle or a line). Similarly, any oblique projection onto a plane results in a conic section. If the projection is a closed curve on the plane, then the curve is an ellipse or a degenerate ellipse.

Reflection property
Assume an elliptic mirror with a light source at one of the foci. Then all rays are Reflection (physics) reflected to a single point — the second focus. Since no other curve has such a property, it can be used as an alternative definition of an ellipse.

Ellipses in physics
Indian astronomer Aryabhata discovered that the orbits of the planets around the sun are ellipses in 499, which he described in his book, the ''Aryabhatiya'' [http://www-groups.dcs.st-and.ac.uk/~history/Mathematicians/Aryabhata_I.html]. In the 17th century, Johannes Kepler explained that the orbits along which the planets travel around the Sun are ellipses, which is Kepler's laws of planetary motion Kepler's first law. Later, Isaac Newton explained this as a corollary of his law of universal gravitation. More generally, in the gravitational two-body problem, if the two bodies are bound to each other (i.e., the total energy is negative), their orbits are similar ellipses with the common barycenter being one of the foci of each ellipse. Interestingly, the orbit of either body in the reference frame of the other is also an ellipse, with the other body at one focus. The general solution for a harmonic oscillator in two or more dimensions is also an ellipse, but this time with the origin of the force located at the center of the ellipse. Albert Einstein also used the ellipse to prove his theory of relativity by using an elliptical shaped mass. Einstein's contributions to modern physics may not have been discovered if it were not for ellipses.

Ellipses in computer graphics
Drawing an ellipse is a common graphics primitive in standard display libraries, such as the QuickDraw and GDI interfaces on the Macintosh and Windows systems. Often such libraries are limited and can only draw an ellipse with either the major axis or the minor axis horizontal. Jack Bresenham at IBM is most famous for the invention of 2D drawing primitives, including line and circle drawing, using only fast integer operations such as addition and branch on carry bit. An efficient generalization to draw ellipses was invented in 1984 by Jerry Van Aken (IEEE CG&A, Sept. 1984). A more challenging task is to perform these drawing operations with antialiasing, to create a smooth-looking curve. The curve drawing algorithms of Xiaolin Wu (SIGGRAPH 91) are an example.

See also
* Ellipsoid, a higher dimensional analog of an ellipse * Spheroid, the ellipsoids obtained by rotating an ellipse about its major or minor axis. * Super ellipse, a generalization of an ellipse that can look more rectangular * Hyperbola * Parabola * Orbit * Oval (geometry) * true anomaly True, eccentric anomaly eccentric, and mean anomaly mean anomalies Category:Conic sections ar:قطع ناقص bg:ЕлипÑ?а ca:El·lipse cs:Elipsa da:Ellipse (geometri) de:Ellipse es:Elipse eo:Elipso fr:Ellipse (mathématiques) ko:타ì›? id:Elips ia:Ellipse it:Ellisse he:×?ליפסה ka:ელიფსი lt:ElipsÄ— nl:Ellips (wiskunde) ja:楕円 no:Ellipse (matematikk) nn:Ellipse pl:Elipsa (matematyka) pt:Elipse ru:ЭллипÑ? scn:Ellissi sk:Elipsa sl:Elipsa fi:Ellipsi sv:Ellips (matematik) ta:நீளà¯?வடà¯?டமà¯? tr:Elips uk:ЕліпÑ? zh:椭圆

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