In analytic geometry, an asymptote (//) of a curve is a line such that the distance between the curve and the line approaches zero as they tend to infinity. Some sources include the requirement that the curve may not cross the line infinitely often, but this is unusual for modern authors.^{[1]} In some contexts, such as algebraic geometry, an asymptote is defined as a line which is tangent to a curve at infinity.^{[2]}^{[3]}
The word asymptote is derived from the Greek ἀσύμπτωτος (asumptotos) which means "not falling together," from ἀ priv. + σύν "together" + πτωτός "fallen."^{[4]} The term was introduced by Apollonius of Perga in his work on conic sections, but in contrast to its modern meaning, he used it to mean any line that does not intersect the given curve.^{[5]}
There are potentially three kinds of asymptotes: horizontal, vertical and oblique asymptotes. For curves given by the graph of a function y = ƒ(x), horizontal asymptotes are horizontal lines that the graph of the function approaches as x tends to +∞ or −∞. Vertical asymptotes are vertical lines near which the function grows without bound.
More generally, one curve is a curvilinear asymptote of another (as opposed to a linear asymptote) if the distance between the two curves tends to zero as they tend to infinity, although usually the term asymptote by itself is reserved for linear asymptotes.
Asymptotes convey information about the behavior of curves in the large, and determining the asymptotes of a function is an important step in sketching its graph.^{[6]} The study of asymptotes of functions, construed in a broad sense, forms a part of the subject of asymptotic analysis.
A "simple" example
The idea that a curve may come arbitrarily close to a line without actually becoming the same may seem to counter everyday experience. The representations of a line and a curve as marks on a piece of paper or as pixels on a computer screen have a positive width. So if they were to be extended far enough they would seem to merge, at least as far as the eye could discern. But these are physical representations of the corresponding mathematical entities; the line and the curve are idealized concepts whose width is 0 (see Line). Therefore the understanding of the idea of an asymptote requires an effort of reason rather than experience.
Consider the graph of the equation y = 1/x shown to the right. The coordinates of the points on the curve are of the form (x, 1/x) where x is a number other than 0. For example, the graph contains the points (1, 1), (2, 0.5), (5, 0.2), (10, 0.1), ... As the values of x become larger and larger, say 100, 1000, 10,000 ..., putting them far to the right of the illustration, the corresponding values of y, .01, .001, .0001, ..., become infinitesimal relative to the scale shown. But no matter how large x becomes, its reciprocal 1/x is never 0, so the curve never actually touches the xaxis. Similarly, as the values of x become smaller and smaller, say .01, .001, .0001, ..., making them infinitesimal relative to the scale shown, the corresponding values of y, 100, 1000, 10,000 ..., become larger and larger. So the curve extends farther and farther upward as it comes closer and closer to the yaxis. Thus, both the x and yaxes are asymptotes of the curve. These ideas are part of the basis of concept of a limit in mathematics, and this connection is explained more fully below.^{[7]}
Asymptotes of functions
The asymptotes most commonly encountered in the study of calculus are of curves of the form y = ƒ(x). These can be computed using limits and classified into horizontal, vertical and oblique asymptotes depending on its orientation. Horizontal asymptotes are horizontal lines that the graph of the function approaches as x tends to +∞ or −∞. As the name indicate they are parallel to the xaxis. Vertical asymptotes are vertical lines (perpendicular to the xaxis) near which the function grows without bound. Oblique asymptotes are diagonal lines so that the difference between the curve and the line approaches 0 as x tends to +∞ or −∞. More general type of asymptotes can be defined in this case. Only open curves that have some infinite branch, can have an asymptote. No closed curve can have an asymptote.
Vertical asymptotes
The line x = a is a vertical asymptote of the graph of the function y = ƒ(x) if at least one of the following statements is true:
 $\backslash lim\_\{x\; \backslash to\; a^\{\}\}\; f(x)=\backslash pm\backslash infty$
 $\backslash lim\_\{x\; \backslash to\; a^\{+\}\}\; f(x)=\backslash pm\backslash infty.$
The function ƒ(x) may or may not be defined at a, and its precise value at the point x = a does not affect the asymptote. For example, for the function
 $f(x)\; =\; \backslash begin\{cases\}\; \backslash frac\{1\}\{x\}\; \&\; \backslash mbox\{if\; \}\; x\; >\; 0,\; \backslash \backslash \; 5\; \&\; \backslash mbox\{if\; \}\; x\; \backslash le\; 0.\; \backslash end\{cases\}$
has a limit of +∞ as x → 0^{+}, ƒ(x) has the vertical asymptote x = 0, even though ƒ(0) = 5. The graph of this function does intersect the vertical asymptote once, at (0,5). It is impossible for the graph of a function to intersect a vertical asymptote (or a vertical line in general) in more than one point.
A common example of a vertical asymptote is the case of a rational function at a point x such that the denominator is zero and the numerator is nonzero.
Horizontal asymptotes
Horizontal asymptotes are horizontal lines that the graph of the function approaches as x → ±∞. The horizontal line y = c is a horizontal asymptote of the function y = ƒ(x) if
 $\backslash lim\_\{x\backslash rightarrow\; \backslash infty\}f(x)=c$ or $\backslash lim\_\{x\backslash rightarrow\; +\backslash infty\}f(x)=c$.
In the first case, ƒ(x) has y = c as asymptote when x tends to −∞, and in the second that ƒ(x) has y = c as an asymptote as x tends to +∞
For example the arctangent function satisfies
 $\backslash lim\_\{x\backslash rightarrow\; \backslash infty\}\backslash arctan(x)=\backslash pi/2$ and $\backslash lim\_\{x\backslash rightarrow+\backslash infty\}\backslash arctan(x)=\backslash pi/2.$
So the line y = −π/2 is a horizontal tangent for the arctangent when x tends to −∞, and y = π/2 is a horizontal tangent for the arctangent when x tends to +∞.
Functions may lack horizontal asymptotes on either or both sides, or may have one horizontal asymptote that is the same in both directions. For example, the function ƒ(x) = 1/(x^{2}+1) has a horizontal asymptote at y = 0 when x tends both to −∞ and +∞ because, respectively,
 $\backslash lim\_\{x\backslash to\; \backslash infty\}\backslash frac\{1\}\{x^2+1\}=\backslash lim\_\{x\backslash to\; +\backslash infty\}\backslash frac\{1\}\{x^2+1\}=0.$
Oblique asymptotes
When a linear asymptote is not parallel to the x or yaxis, it is called an oblique asymptote or slant asymptote. A function f(x) is asymptotic to the straight line y = mx + n (m ≠ 0) if
$\backslash lim\_\{x\; \backslash to\; +\backslash infty\}\backslash left[\; f(x)(mx+n)\backslash right]\; =\; 0\; \backslash ,\; \backslash mbox\{\; or\; \}\; \backslash lim\_\{x\; \backslash to\; \backslash infty\}\backslash left[\; f(x)(mx+n)\backslash right]\; =\; 0.$
In the first case the line y = mx + n is an oblique asymptote of ƒ(x) when x tends to +∞, and in the second case the line y = mx + n is an oblique asymptote of ƒ(x) when x tends to −∞
An example is ƒ(x) = x−1/x, which has the oblique asymptote y = x (m = 1, n = 0) as seen in the limits
 $\backslash lim\_\{x\backslash to\backslash pm\backslash infty\}\backslash left[f(x)x\backslash right]$
 $=\backslash lim\_\{x\backslash to\backslash pm\backslash infty\}\backslash left[\backslash frac\{x^21\}\{x\}x\backslash right]$
 $=\backslash lim\_\{x\backslash to\backslash pm\backslash infty\}\backslash left[\backslash left(x\backslash frac\{1\}\{x\}\backslash right)x\backslash right]$
 $=\backslash lim\_\{x\backslash to\backslash pm\backslash infty\}\backslash frac\{1\}\{x\}=0.$
Elementary methods for identifying asymptotes
Asymptotes of many elementary functions can be found without the explicit use of limits (although the derivations of such methods typically use limits).
General computation of oblique asymptotes for functions
The oblique asymptote, for the function f(x), will be given by the equation y=mx+n. The value for m is computed first and is given by
 $m\backslash stackrel\{\backslash text\{def\}\}\{=\}\backslash lim\_\{x\backslash rightarrow\; a\}f(x)/x$
where a is either $\backslash infty$ or $+\backslash infty$ depending on the case being studied. It is good practice to treat the two cases separately. If this limit doesn't exist then there is no oblique asymptote in that direction.
Having m then the value for n can be computed by
 $n\backslash stackrel\{\backslash text\{def\}\}\{=\}\backslash lim\_\{x\backslash rightarrow\; a\}(f(x)mx)$
where a should be the same value used before. If this limit fails to exist then there is no oblique asymptote in that direction, even should the limit defining m exist. Otherwise y = mx + n is the oblique asymptote of ƒ(x) as x tends to a.
For example, the function ƒ(x) = (2x^{2} + 3x + 1)/x has
 $m=\backslash lim\_\{x\backslash rightarrow+\backslash infty\}f(x)/x=\backslash lim\_\{x\backslash rightarrow+\backslash infty\}\backslash frac\{2x^2+3x+1\}\{x^2\}=2$ and then
 $n=\backslash lim\_\{x\backslash rightarrow+\backslash infty\}(f(x)mx)=\backslash lim\_\{x\backslash rightarrow+\backslash infty\}\backslash left(\backslash frac\{2x^2+3x+1\}\{x\}2x\backslash right)=3$
so that y = 2x + 3 is the asymptote of ƒ(x) when x tends to +∞.
The function ƒ(x) = ln x has
 $m=\backslash lim\_\{x\backslash rightarrow+\backslash infty\}f(x)/x=\backslash lim\_\{x\backslash rightarrow+\backslash infty\}\backslash frac\{\backslash ln\; x\}\{x\}=0$ and then
 $n=\backslash lim\_\{x\backslash rightarrow+\backslash infty\}(f(x)mx)=\backslash lim\_\{x\backslash rightarrow+\backslash infty\}\backslash ln\; x$, which does not exist.
So y = ln x does not have an asymptote when x tends to +∞.
Asymptotes for rational functions
A rational function has at most one horizontal asymptote or oblique (slant) asymptote, and possibly many vertical asymptotes.
The degree of the numerator and degree of the denominator determine whether or not there are any horizontal or oblique asymptotes. The cases are tabulated below, where deg(numerator) is the degree of the numerator, and deg(denominator) is the degree of the denominator.
Table listing the cases of horizontal and oblique asymptotes for rational functions
deg(numerator) − deg(denominator)

asymptotes

example, asymptote

< 0

y = 0

$\backslash frac\{1\}\{x^2+1\},\; y=0$

= 0

y = the ratio of leading coefficients

$\backslash frac\{2x^2+7\}\{3x^2+x+12\},\; y=\backslash frac\{2\}\{3\}$

= 1

y = the quotient, in the long division of the fraction

$\backslash frac\{x^2+x+1\}\{x\},\; y=x+1$

> 1

none

$\backslash frac\{2x^4\}\{3x^2+1\},\; \backslash mbox\{none\}$

The vertical asymptotes occur only when the denominator is zero (If both the numerator and denominator are zero, the multiplicities of the zero are compared). For example, the following function has vertical asymptotes at x = 0, and x = 1, but not at x = 2.
 $f(x)=\backslash frac\{x^25x+6\}\{x^33x^2+2x\}=\backslash frac\{(x2)(x3)\}\{x(x1)(x2)\}$
Oblique asymptotes of rational functions
When the numerator of a rational function has degree exactly one greater than the denominator, the function has an oblique (slant) asymptote. The asymptote is the polynomial term after dividing the numerator and denominator. This phenomenon occurs because when dividing the fraction, there will be a linear term, and a remainder. For example, consider the function
 $f(x)=\backslash frac\{x^2+x+1\}\{x+1\}=x+\backslash frac\{1\}\{x+1\}$
shown to the right. As the value of x increases, f approaches the asymptote y = x. This is because the other term, y = 1/(x+1) becomes smaller.
If the degree of the numerator is more than 1 larger than the degree of the denominator, and the denominator does not divide the numerator, there will be a nonzero remainder that goes to zero as x increases, but the quotient will not be linear, and the function does not have an oblique asymptote.
Transformations of known functions
If a known function has an asymptote (such as y=0 for f(x)=e^{x}), then the translations of it also have an asymptote.
 If x=a is a vertical asymptote of f(x), then x=a+h is a vertical asymptote of f(xh)
 If y=c is a horizontal asymptote of f(x), then y=c+k is a horizontal asymptote of f(x)+k
If a known function has an asymptote, then the scaling of the function also have an asymptote.
 If y=ax+b is an asymptote of f(x), then y=cax+cb is an asymptote of cf(x)
For example, f(x)=e^{x1}+2 has horizontal asymptote y=0+2=2, and no vertical or oblique asymptotes.
General definition
Let A : (a,b) → R^{2} be a parametric plane curve, in coordinates A(t) = (x(t),y(t)). Suppose that the curve tends to infinity, that is:
 $\backslash lim\_\{t\backslash rightarrow\; b\}(x^2(t)+y^2(t))=\backslash infty.$
A line ℓ is an asymptote of A if the distance from the point A(t) to ℓ tends to zero as t → b.^{[8]}
For example, the upper right branch of the curve y = 1/x can be defined parametrically as x = t, y = 1/t (where t>0). First, x → ∞ as t → ∞ and the distance from the curve to the xaxis is 1/t which approaches 0 as t → ∞. Therefore the xaxis is an asymptote of the curve. Also, y → ∞ as t → 0 from the right, and the distance between the curve and the yaxis is t which approaches 0 as t → 0. So the yaxis is also an asymptote. A similar argument shows that the lower left branch of the curve also has the same two lines as asymptotes.
Although the definition here uses a parameterization of the curve, the notion of asymptote does not depend on the parameterization. In fact, if the equation of the line is $ax+by+c=0$ then the distance from the point A(t) = (x(t),y(t)) to the line is given by
 $\backslash frac\{ax(t)+by(t)+c\}\{\backslash sqrt\{a^2+b^2\}\}$
if γ(t) is a change of parameterization then the distance becomes
 $\backslash frac\{ax(\backslash gamma(t))+by(\backslash gamma(t))+c\}\{\backslash sqrt\{a^2+b^2\}\}$
which tends to zero simultaneously as the previous expression.
An important case is when the curve is the graph of a real function (a function of one real variable and returning real values). The graph of the function y = ƒ(x) is the set of points of the plane with coordinates (x,ƒ(x)). For this, a parameterization is
 $t\backslash mapsto\; (t,f(t)).$
This parameterization is to be considered over the open intervals (a,b), where a can be −∞ and b can be +∞.
An asymptote can be either vertical or nonvertical (oblique or horizontal). In the first case its equation is x = c, for some real number c. The nonvertical case has equation y = mx + n, where m and $n$ are real numbers. All three types of asymptotes can be present at the same time in specific examples. Unlike asymptotes for curves that are graphs of functions, a general curve may have more than two nonvertical asymptotes, and may cross its vertical asymptotes more than once.
Curvilinear asymptotes
Let A : (a,b) → R^{2} be a parametric plane curve, in coordinates A(t) = (x(t),y(t)), and B be another (unparameterized) curve. Suppose, as before, that the curve A tends to infinity. The curve B is a curvilinear asymptote of A if the shortest of the distance from the point A(t) to a point on B tends to zero as t → b. Sometimes B is simply referred to as an asymptote of A, when there is no risk of confusion with linear asymptotes.^{[9]}
For example, the function
 $y\; =\; \backslash frac\{x^3+2x^2+3x+4\}\{x\}$
has a curvilinear asymptote y = x^{2} + 2x + 3, which is known as a parabolic asymptote because it is a parabola rather than a straight line.^{[10]}
Asymptotes and curve sketching
The notion of asymptote is related to procedures of curve sketching. An asymptote serves as a guide line that serves to show the behavior of the curve towards infinity.^{[11]} In order to get better approximations of the curve, asymptotes that are general curves have also been used ^{[12]} although the term asymptotic curve seems to be preferred.^{[13]}
Algebraic curves
The asymptotes of an algebraic curve in the affine plane are the lines that are tangent to the projectivized curve through a point at infinity.^{[14]} For example, one may identify the asymptotes to the unit hyperbola in this manner. Asymptotes are often considered only for real curves,^{[15]} although they also make sense when defined in this way for curves over an arbitrary field.^{[16]}
A plane curve of degree n intersects its asymptote at most at n−2 other points, by Bézout's theorem, as the intersection at infinity is of multiplicity at least two. For a conic, there are a pair of lines that do not intersect the conic at any complex point: these are the two asymptotes of the conic.
A plane algebraic curve is defined by an equation of the form P(x,y) = 0 where P is a polynomial of degree n
 $P(x,y)\; =\; P\_n(x,y)\; +\; P\_\{n1\}(x,y)\; +\; \backslash cdots\; +\; P\_1(x,y)\; +\; P\_0$
where P_{k} is homogeneous of degree k. Vanishing of the linear factors of the highest degree term P_{n} defines the asymptotes of the curve: setting Q = P_{n}, if P_{n}(x, y) = (ax − by) Q_{n−1}(x, y), then the line
 $Q\text{'}\_x(b,a)x+Q\text{'}\_y(b,a)y\; +\; P\_\{n1\}(b,a)=0$
is an asymptote if $Q\text{'}\_x(b,a)$ and $Q\text{'}\_y(b,a)$ are not both zero. If $Q\text{'}\_x(b,a)=Q\text{'}\_y(b,a)=0$ and $P\_\{n1\}(b,a)\backslash neq\; 0$, there is no asymptote, but the curve has a branch that looks like a branch of parabola. Such a branch is said a parabolic branch, even when it does not has any parabola that is a curvilinear asymptote. If $Q\text{'}\_x(b,a)=Q\text{'}\_y(b,a)=P\_\{n1\}(b,a)=0,$ the curve has a singular point at infinity which may have several asymptotes or parabolic branches.
Over the complex numbers, P_{n} splits into linear factors, each of which defines an asymptote (or several for multiple factors). 0ver the reals, P_{n} splits in factors that are linear or quadratic factors. Only the linear factors correspond to infinite (real) branches of the curve, but if a linear factor has multiplicity greater than one, the curve may have several asymptotes or parabolic branches. It may also occur that such a multiple linear factor corresponds to two complex conjugate branches, and does not corresponds to any infinite branch of the real curve. For example, the curve x^{4} + y^{2}  1 = 0 has no real points outside the square $x\backslash leq\; 1,\; y\backslash leq\; 1$, but its highest order term gives the linear factor x with multiplicity 4, leading to the unique asymptote x=0.
Asymptotic cone
The hyperbola
 $\backslash frac\{x^2\}\{a^2\}\backslash frac\{y^2\}\{b^2\}=\; 1$
has the two asymptotes
 $y=\backslash pm\backslash frac\{b\}\{a\}x.$
The equation for the union of these two lines is
 $\backslash frac\{x^2\}\{a^2\}\backslash frac\{y^2\}\{b^2\}=0.$

Similarly, the hyperboloid
 $\backslash frac\{x^2\}\{a^2\}\backslash frac\{y^2\}\{b^2\}\backslash frac\{z^2\}\{c^2\}=1$
is said to have the asymptotic cone^{[17]}^{[18]}
 $\backslash frac\{x^2\}\{a^2\}\backslash frac\{y^2\}\{b^2\}\backslash frac\{z^2\}\{c^2\}=0.$
The distance between the hyperboloid and cone approaches 0 as the distance from the origin approaches infinity.

More generally, let us consider a surface that has an implicit equation
$P\_d(x,y,z)+P\_\{d2\}(x,y,z)\; +\; \backslash cdots\; P\_0=0,$
where the $P\_i$ are homogeneous polynomials of degree i and $P\_\{d1\}=0$. Then the equation $P\_d(x,y,z)=0$ defines a cone which is centered at the origin. It is called asymptotic cone, because the distance to the cone of a point of the surface tends to zero when the point on the surface tends to infinity.
See also
References
General references:
Specific references:
External links
 Template:Planetmath reference
 Hyperboloid and Asymptotic Cone, string surface model, 1872 from the Science Museum
This article was sourced from Creative Commons AttributionShareAlike License; additional terms may apply. World Heritage Encyclopedia content is assembled from numerous content providers, Open Access Publishing, and in compliance with The Fair Access to Science and Technology Research Act (FASTR), Wikimedia Foundation, Inc., Public Library of Science, The Encyclopedia of Life, Open Book Publishers (OBP), PubMed, U.S. National Library of Medicine, National Center for Biotechnology Information, U.S. National Library of Medicine, National Institutes of Health (NIH), U.S. Department of Health & Human Services, and USA.gov, which sources content from all federal, state, local, tribal, and territorial government publication portals (.gov, .mil, .edu). Funding for USA.gov and content contributors is made possible from the U.S. Congress, EGovernment Act of 2002.
Crowd sourced content that is contributed to World Heritage Encyclopedia is peer reviewed and edited by our editorial staff to ensure quality scholarly research articles.
By using this site, you agree to the Terms of Use and Privacy Policy. World Heritage Encyclopedia™ is a registered trademark of the World Public Library Association, a nonprofit organization.