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In geometry, a line that intersects a circle exactly once; in calculus, a line that touches a curve at one point and whose slope is equal to that of the curve at that point. Particularly useful as approximations of curves in the immediate vicinity of the point of tangency, tangent lines are the basis of many estimation techniques, including linear approximation. The numerical value of the slope of the tangent line to the graph of a function at any point equals that of the function's derivative at that point. This is one of the keystones of differential calculus. *Seealso* differential geometry.

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Encyclopedia Britannica, 2008. Encyclopedia Britannica Online.

- For the tangent function see trigonometric functions. For other uses, see tangent (disambiguation).

In geometry, the tangent line (or simply the tangent) to a curve at a given point is the straight line that "just touches" the curve at that point (in the sense explained more precisely below). As it passes through the point of tangency, the tangent line is "going in the same direction" as the curve, and in this sense it is the best straight-line approximation to the curve at that point. The same definition applies to space curves and curves in n-dimensional Euclidean space.

In a similar way, the tangent plane to a surface at a given point is the plane that "just touches" the surface at that point. The concept of a tangent is one of the most fundamental notions in differential geometry and has been extensively generalized — see Tangent space.

The word "tangent" comes from the Latin tangere, meaning "to touch".

The intuitive notion that a tangent "just touches" a curve can be made more explicit by considering the sequence of straight lines (secant lines) passing through two points, A and B, that lie on the curve. The tangent at A is the limit of the progression of secant lines as B moves ever closer to A. The existence and uniqueness of the tangent line depends on a certain type of mathematical smoothness, known as "differentiability". For example, if two circular arcs meet at a sharp point (a vertex) then there is no uniquely defined tangent at the vertex because the limit of the progression of secant lines depends on the direction in which "point B" approaches the vertex.

In most cases commonly encountered, the tangent to a curve does not cross the curve at the point of tangency (though it may, when continued, cross the curve at other places away from the point of tangency). This is true, for example, of all tangents to a circle or a parabola. However, at exceptional points called inflection points, the tangent line does cross the curve at the point of tangency. An example is the point (0,0) on the graph of the cubic parabola y = x^{3}.

Conversely, it may happen that the curve lies entirely on one side of a straight line passing through a point on it, and yet this straight line is not a tangent line. This is the case, for example, for a line passing through the vertex of a triangle and not interecting the triangle — where the tangent line does not exist for the reasons explained above. In convex geometry, such lines are called supporting lines.

- $frac\{f(a+h)-f(a)\}\{h\}.$

As the point q approaches p, which corresponds to making h smaller and smaller, the difference quotient should approach a certain limiting value k, which is the slope of the tangent line at the point p. If k is known, the equation of the tangent line can be found in the point-slope form:

- $y-f(a)\; =\; k(x-a).,$

- $y=f(a)+f\text{'}(a)(x-a).,$

Calculus provides rules for computing the derivatives of functions that are given by formulas, such as the power function, trigonometric functions, exponential function, logarithm, and their various combinations. Thus equations of the tangents to graphs of all these functions, as well as many others, can be found by the methods of calculus.

The graph y = x^{1/3} illustrates the first possibility: here the difference quotient at a = 0 is equal to h^{1/3}/h = h^{− 2/3}, which becomes very large as h approaches 0. The tangent line to this curve at the origin is vertical.

The graph y = |x| of the absolute value function consists of two straight lines with different slopes joined at the origin. As a point q approaches the origin from the right, the secant line always has slope 1. As a point q approaches the origin from the left, the secant line always has slope −1. Therefore, there is no unique tangent to the graph at the origin (although in a certain sense, there are two half-tangents, corresponding to two possible directions of approaching the origin).

- $left(x\_1-x\_2right)^2+left(y\_1-y\_2right)^2=left(r\_1pm\; r\_2right)^2.,$

The tangent plane to a surface at a given point p is defined in an analogous way to the tangent line in the case of curves. It is the best approximation of the surface by a plane at p, and can be obtained as the limiting position of the planes passing through 3 distinct points on the surface close to p as these points converge to p. More generally, there is a k-dimensional tangent space at each point of a k-dimensional manifold in the n-dimensional Euclidean space.

- Newton's method
- Normal vector
- Osculating circle
- Subtangent
- Tangent cone
- Tangential component
- Tangent lines to circles

- MathWorld: Tangent Line
- Tangent to a circle With interactive animation
- Tangent and first derivative - An interactive simulation
- The Tangent Parabola by John H. Mathews

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Last updated on Thursday October 09, 2008 at 05:30:34 PDT (GMT -0700)

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This article is licensed under the GNU Free Documentation License.

Last updated on Thursday October 09, 2008 at 05:30:34 PDT (GMT -0700)

View this article at Wikipedia.org - Edit this article at Wikipedia.org - Donate to the Wikimedia Foundation

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