Parabolic

Information about Parabolic

A parabola

A graph showing the reflective property, the directrix (green), and the lines connecting the focus and directrix to the parabola (blue)

In mathematics, the parabola (from the Greek: παραβολή) (IPA pronunciation: /pəˈrab(ə)lə/) is a conic section generated by the intersection of a right circular conical surface and a plane parallel to a generating straight line of that surface. A parabola can also be defined as locus of points in a plane which are equi distant from a given point (the focus) and a given line (the directrix).

A particular case arises when the plane is tangent to the conical surface. In this case, the intersection is a degenerate parabola consisting of a straight line.

The parabola is an important concept in abstract mathematics, but it is also seen with considerable frequency in the physical world, and there are many practical applications for the construct in engineering, physics, and other domains.

Analytic geometry equations

In Cartesian coordinates, a parabola with an axis parallel to the y axis with vertex (h, k), focus (h, k + p), and directrix y = k - p, with p being the distance from the vertex to the focus, has the equation with axis parallel to the y-axis

$\text{[math]}$

or, alternatively with axis parallel to the x-axis

$\text{[math]}$

More generally, a parabola is a curve in the Cartesian plane defined by an irreducible equation of the form

$\text{[math]}$

such that $\text{[math]}$ , where all of the coefficients are real, where $\text{[math]}$ or $\text{[math]}$ , and where more than one solution, defining a pair of points (x, y) on the parabola, exists. That the equation is irreducible means it does not factor as a product of two not necessarily distinct linear equations.

Other geometric definitions

A parabola may also be characterized as a conic section with an eccentricity of 1. As a consequence of this, all parabolas are similar. A parabola can also be obtained as the limit of a sequence of ellipses where one focus is kept fixed as the other is allowed to move arbitrarily far away in one direction. In this sense, a parabola may be considered an ellipse that has one focus at infinity. The parabola is an inverse transform of a cardioid.

A parabola has a single axis of reflective symmetry, which passes through its focus and is perpendicular to its directrix. The point of intersection of this axis and the parabola is called the vertex. A parabola spun about this axis in three dimensions traces out a shape known as a paraboloid of revolution.

The parabola is found in numerous situations in the physical world (see below).

Equations

(with vertex (h, k) and distance p between vertex and focus - note that if the vertex is below the focus, or equivalently above the directrix, p is positive, otherwise p is negative; similarly with horizontal axis of symmetry p is positive if vertex is to the left of the focus, or equivalently to the right of the directrix)

Cartesian

Vertical axis of symmetry

$\text{[math]}$

: $\text{[math]}$

: $\text{[math]}$ .

$\text{[math]}$

Horizontal axis of symmetry

$\text{[math]}$

: $\text{[math]}$

: $\text{[math]}$ .

$\text{[math]}$ '''

Semi-latus rectum and polar coordinates

In polar coordinates, a parabola with the focus at the origin and the directrix on the positive x-axis, is given by the equation

$\text{[math]}$

where l is the semilatus rectum: the distance from the focus to the parabola itself, measured along a line perpendicular to the axis. Note that this is twice the distance from the focus to the apex of the parabola or the perpendicular distance from the focus to the latus rectum.

Gauss-mapped form

A Gauss-mapped form: $\text{[math]}$ has normal $\text{[math]}$ .

Derivation of the focus

Given a parabola parallel to the y-axis with vertex (0,0) and with equation

$\text{[math]}$

then there is a point (0,f) — the focus — such that any point P on the parabola will be equidistant from both the focus and a line perpendicular to the axis of symmetry of the parabola (the linea directrix), in this case parallel to the x axis. Since the vertex is one of the possible points P, it follows that the linea directrix passes through the point (0,-f). So for any point P=(x,y), it will be equidistant from (0,f) and (x,-f). It is desired to find the value of f which has this property.

Let F denote the focus, and let Q denote the point at (x,-f). Line FP has the same length as line QP.

$\text{[math]}$

Square both sides,

$\text{[math]}$

:: $\text{[math]}$

$\text{[math]}$

Cancel out terms from both sides,

$\text{[math]}$

Cancel out the xÂ² from both sides (x is generally not zero),

$\text{[math]}$

Now let p=f and the equation for the parabola becomes

$\text{[math]}$

Q.E.D.

All this was for a parabola centered at the origin. For any generalized parabola, with its equation given in the standard form

$\text{[math]}$ ,

the focus is located at the point

$\text{[math]}$

and the directrix is designated by the equation

$\text{[math]}$

Reflective property of the tangent

The tangent of the parabola described by equation (1) has slope

$\text{[math]}$

This line intersects the y-axis at the point (0,-y) = (0, - a xÂ²), and the x-axis at the point (x/2,0). Let this point be called G. Point G is also the midpoint of points F and Q:

$\text{[math]}$

Since G is the midpoint of line FQ, this means that

$\text{[math]}$

and it is already known that P is equidistant from both F and Q:

$\text{[math]}$

and, thirdly, line GP is equal to itself, therefore:

$\text{[math]}$

It follows that $\text{[math]}$ .

Line QP can be extended beyond P to some point T, and line GP can be extended beyond P to some point R. Then $\text{[math]}$ and $\text{[math]}$ are vertical, so they are equal (congruent). But $\text{[math]}$ is equal to $\text{[math]}$ . Therefore $\text{[math]}$ is equal to $\text{[math]}$ .

The line RG is tangent to the parabola at P, so any light beam bouncing off point P will behave as if line RG were a mirror and it were bouncing off that mirror.

Let a light beam travel down the vertical line TP and bounce off from P. The beam's angle of inclination from the mirror is $\text{[math]}$ , so when it bounces off, its angle of inclination must be equal to $\text{[math]}$ . But $\text{[math]}$ has been shown to be equal to $\text{[math]}$ . Therefore the beam bounces off along the line FP: directly towards the focus.

Conclusion: Any light beam moving vertically downwards in the concavity of the parabola (parallel to the axis of symmetry) will bounce off the parabola moving directly towards the focus. (See parabolic reflector.)

What happens to a parabola when "b" varies?

Vertex of a parabola: Finding the y-coordinate

We know the x-coordinate at the vertex is $\text{[math]}$ , so substitute it into the equation $\text{[math]}$

$\text{[math]}$

Thus, the vertex is at pointâ€¦

$\text{[math]}$

Parabolas in the physical world

In nature, approximations of parabolas and paraboloids are found in many diverse situations. The most well-known instance of the parabola in the history of physics is the trajectory of a particle or body in motion under the influence of a uniform gravitational field without air resistance (for instance, a baseball flying through the air, neglecting air friction). The parabolic trajectory of projectiles was discovered experimentally by Galileo in the early 17th century, who performed experiments with balls rolling on inclined planes. The parabolic shape for projectiles was later proven mathematically by Isaac Newton. For objects extended in space, such as a diver jumping from a diving board, the object itself follows a complex motion as it rotates, but the center of mass of the object nevertheless forms a parabola. As in all cases in the physical world, the trajectory is always an approximation of a parabola. The presence of air resistance, for example, always distorts the shape, although at low speeds, the shape is a good approximation of a parabola. At higher speeds, such as in ballistics, the shape is highly distorted and does not resemble a parabola.

Parabolic shape formed by the surface of a Newtonian liquid under rotation

Another situation in which parabola may arise in nature is in two-body orbits, for example, of a small planetoid or other object under the influence of the gravitation of the sun. Such parabolic orbits are a special case that are rarely found in nature. Orbits that form a hyperbola or an ellipse are much more common. In fact, the parabolic orbit is the borderline case between those two types of orbit. An object following a parabolic orbit moves at the exact escape velocity of the object it is orbitting, while elliptical orbits are slower and hyperbolic orbits are faster.

Approximations of parabolas are also found in the shape of cables of suspension bridges. Freely hanging cables do not describe parabolas, but rather catenary curves. Under the influence of a uniform load (for example, the deck of bridge), however, the cable is deformed toward a parabola.

Paraboloids arise in several physical situations as well. The most well-known instance is the parabolic reflector, which is a mirror or similar reflective device that concentrates light or other forms of electromagnetic radiation to a common focal point. The principle of the parabolic reflector may have been discovered in the 3rd century BC by the geometer Archimedes, who, according to a legend of debatable veracity,^[1] constructed parabolic mirrors to defend Syracuse against the Roman fleet, by concentrating the sun's rays to set fire to the decks of the Roman ships. The principle was applied to telescopes in the 17th century. Today, paraboloid reflectors can be commonly observed throughout much of the world in microwave and satellite dish antennas.

Paraboloids are also observed in the surface of a liquid confined to a container and rotated around the central axis. In this case, the centrifugal force causes the liquid to climb the walls of the container, forming a parabolic surface. This is the principle behind the liquid mirror telescope.

Aircraft used to create a weightless state for purposes of experimentation, such as NASA's “vomit comet,” follow a vertically parabolic trajectory for brief periods in order to trace the course of an object in free fall, which produces the same effect as zero gravity for most purposes.

References

1. ^ Middleton, W. E. Knowles (December 1961). "Archimedes, Kircher, Buffon, and the Burning-Mirrors" (GIF). Isis 52 (4): 533–543. Retrieved on 2006-08-08.

External links

Apollonius' Derivation of the Parabola at Convergence
Eric W. Weisstein, Parabola at MathWorld.
Interactive parabola-drag focus, see axis of symmetry, directrix, standard and vertex forms
Archimedes Triangle and Squaring of Parabola at cut-the-knot
Two Tangents to Parabola at cut-the-knot
Parabola As Envelope of Straight Lines at cut-the-knot
Parabolic Mirror at cut-the-knot
Three Parabola Tangents at cut-the-knot
Module for the Tangent Parabola
Focal Properties of Parabola at cut-the-knot
Parabola As Envelope II at cut-the-knot
Parabola Construction - An interactive sketch showing how to trace a parabola. (Requires Java.)
Quadratic Bezier Construction - An interactive sketch showing how to trace the quadratic Bezier curve (a parabolic segment). (Requires Java.)
More Interactive Parabola Construction (Java-enabled)

Mathematics (colloquially, maths or math) is the body of knowledge centered on such concepts as quantity, structure, space, and change, and also the academic discipline that studies them. Benjamin Peirce called it "the science that draws necessary conclusions".
..... Click the link for more information.

Greek}}}
Writing system: Greek alphabet
Official status
Official language of: Greece
Cyprus
European Union
recognised as minority language in parts of:
European Union
Italy
Turkey
Regulated by:
..... Click the link for more information.

International Phonetic Alphabet

Note: This page may contain IPA phonetic symbols in Unicode.

The International
Phonetic Alphabet
History
Nonstandard symbols
Extended IPA
Naming conventions
IPA for English The
..... Click the link for more information.

conic section (or just conic) is a curve that can be formed by intersecting a cone (more precisely, a right circular conical surface) with a plane. The conic sections were named and studied as long ago as 200 BC, when Apollonius of Perga undertook a systematic study of their
..... Click the link for more information.

In geometry, a (general) conical surface is the unbounded surface formed by the union of all the straight lines that pass through a fixed point — the apex or vertex — and any point of some fixed space curve — the directrix
..... Click the link for more information.

plane is a two-dimensional manifold or surface that is perfectly flat. Informally it can be thought of as an infinitely vast and infinitesimally thin sheet oriented in some space.
..... Click the link for more information.

locus (Latin for "place", plural loci) is a collection of points which share a property. The term 'locus' is usually used of a condition which defines a continuous figure or figures, that is, a curve.
..... Click the link for more information.

A spatial point is a concept used to define an exact location in space. It has no volume, area or length, making it a zero dimensional object. Points are used in the basic language of geometry, physics, vector graphics (both 2D and 3D), and many other fields.
..... Click the link for more information.

equal if and only if they are precisely the same in every way. The complementary notion is distinctness. This defines a binary relation, equality, denoted by the sign of equality "=" in such a way that the statement "x = y" means that x
..... Click the link for more information.

Distance is a numerical description of how far apart objects are at any given moment in time. In physics or everyday discussion, distance may refer to a physical length, a period of time, or an estimation based on other criteria (e.g. "two counties over").
..... Click the link for more information.

In geometry, the foci (singular focus) are a pair of special points used in describing conic sections. The four types of conic sections are the circle, parabola, ellipse, and hyperbola.
..... Click the link for more information.

degenerate case is a limiting case in which a class of object changes its nature so as to belong to another, usually simpler, class.

A point is a degenerate circle, namely one with radius 0. The circle is a degenerate form of an ellipse, namely one with eccentricity 0.

..... Click the link for more information.

line can be described as an ideal zero-width, infinitely long, perfectly straight curve (the term curve in mathematics includes "straight curves") containing an infinite number of points. In Euclidean geometry, exactly one line can be found that passes through any two points.
..... Click the link for more information.

Engineering is the applied science of acquiring and applying knowledge to design, analysis, and/or construction of works for practical purposes. The American Engineers' Council for Professional Development, also known as ECPD,^[1] (later ABET ^[2]
..... Click the link for more information.

Physics is the science of matter^[1] and its motion^[2]^[3], as well as space and time^[4]^[5] —the science that deals with concepts such as force, energy, mass, and charge.
..... Click the link for more information.

Cartesian coordinate system (also called rectangular coordinate system) is used to determine each point uniquely in a plane through two numbers, usually called the x-coordinate and the y-coordinate of the point.
..... Click the link for more information.

In mathematics, the adjective irreducible means that an object cannot be expressed as a product of at least two non-trivial factors in a given set. See also factorization.

For any field F, the ring of polynomials with coefficients in F is denoted by .
..... Click the link for more information.

eccentricity, denoted e or , is a parameter associated with every conic section. It can be thought of as a measure of how much the conic section deviates from being circular.

In particular,

The eccentricity of a circle is zero.

..... Click the link for more information.

similar if one is congruent to the result of a uniform scaling (enlarging or shrinking) of the other. One can be obtained from the other by uniformly "stretching", possibly with additional rotation, i.e., both have the same shape, or additionally the mirror image is taken, i.e.
..... Click the link for more information.

In mathematics, the concept of a "limit" is used to describe the behavior of a function as its argument either "gets close" to some point, or as it becomes arbitrarily large; or the behavior of a sequence's elements as their index increases indefinitely.
..... Click the link for more information.

ellipse (from the Greek ἔλλειψις, literally absence) is the locus of points on a plane where the sum of the distances from any point on the curve to two fixed points is constant.
..... Click the link for more information.

The word infinity comes from the Latin infinitas or "unboundedness." It refers to several distinct concepts (usually linked to the idea of "without end") which arise in philosophy, mathematics, and theology.
..... Click the link for more information.

In geometry, an inversion is a particular type of transformation that maps all circles into circles, where by a circle one may also mean a line (a circle with infinite radius).
..... Click the link for more information.

In geometry, the cardioid is an epicycloid with one cusp. That is, a cardioid is a curve that can be produced as the path (or locus) of a point on the circumference of a circle as that circle rolls around another fixed circle with the same radius.
..... Click the link for more information.

Symmetry in common usage generally conveys two primary meanings. The first is an imprecise sense of harmonious or aesthetically-pleasing proportionality and balance; such that it reflects beauty or perfection.
..... Click the link for more information.

paraboloid is a quadric, a type of surface in three dimensions, described by the equation:

(elliptical paraboloid, opens upward),

(hyperbolic paraboloid, opens up on x-axis and down on y-axis).

..... Click the link for more information.

For a more advanced and general treatment, see .

Coordinates are numbers which describe the location of points in a plane or in space. For example, the height above sea level
..... Click the link for more information.

In mathematics, the latus rectum of a conic section is the chord parallel to the directrix and passing through the single focus, or one of the two foci. By extension, the length of the latus rectum is also referred to as the latus rectum and written .
..... Click the link for more information.

This article is copied from an article on Wikipedia.org - the free encyclopedia created and edited by online user community. The text was not checked or edited by anyone on our staff. Although the vast majority of the wikipedia encyclopedia articles provide accurate and timely information please do not assume the accuracy of any particular article. This article is distributed under the terms of GNU Free Documentation License.

Herod_Archelaus

iPedia Free Information Center

Parabolic

Information about Parabolic

Analytic geometry equations

Other geometric definitions

Equations

Cartesian

Vertical axis of symmetry

Horizontal axis of symmetry

Semi-latus rectum and polar coordinates

Gauss-mapped form

Derivation of the focus

Reflective property of the tangent

What happens to a parabola when "b" varies?

Parabolas in the physical world

See also

References

External links