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[[Continuous function]]s are of utmost importance in [[mathematics]], functions and applications. However, not all [[function (mathematics)|functions]] are continuous. If a function is not continuous at a point in its [[domain (mathematics)|domain]], one says that it has a '''discontinuity''' there. The set of all points of discontinuity of a function may be a [[discrete set]], a [[dense set]], or even the entire domain of the function.
 
This article describes the '''classification of discontinuities''' in the simplest case of functions of a single [[real number|real]] variable taking real values.
 
Consider a real valued function ''ƒ'' of a real variable ''x'', defined in a neighborhood of the point ''x''<sub>0</sub> at which ''ƒ'' is discontinuous. Three situations can be distinguished:
 
{{ordered list
|1= The [[one-sided limit]] from the negative direction
:<math>L^{-}=\lim_{x\to x_0^{-}} f(x)</math>
 
and the one-sided limit from the positive direction
:<math>L^{+}=\lim_{x\to x_0^{+}} f(x)</math>
 
at <math>\scriptstyle x_0</math> exist, are finite, and are equal to <math>\scriptstyle L \;=\; L^{-} \;=\; L^{+}</math>. Then, if ''ƒ''(''x''<sub>0</sub>) is not equal to <math>\scriptstyle L</math>, ''x''<sub>0</sub> is called a ''removable discontinuity''. This discontinuity can be 'removed to make ''ƒ'' continuous at ''x''<sub>0</sub>', or more precisely, the function
:<math>g(x) = \begin{cases}f(x) & x\ne x_0 \\ L & x = x_0\end{cases}</math>
 
is continuous at ''x''=''x''<sub>0</sub>.
 
|2= The limits <math>\scriptstyle L^{-}</math> and <math>\scriptstyle L^{+}</math> exist and are finite, but not equal. Then, ''x''<sub>0</sub> is called a ''jump discontinuity'' or ''step discontinuity''. For this type of discontinuity, the function ''ƒ'' may have any value at ''x''<sub>0</sub>.
 
|3= One or both of the limits <math>\scriptstyle L^{-}</math> and <math>\scriptstyle L^{+}</math> does not exist or is infinite. Then, ''x''<sub>0</sub> is called an ''essential discontinuity'', or ''infinite discontinuity''. (This is distinct from the term ''[[essential singularity]]'' which is often used when studying [[complex analysis|functions of complex variables]].)
}}
 
The term ''removable discontinuity'' is sometimes used by [[abuse of terminology]] for cases in which the limits in both directions exist and are equal, while the function is [[defined and undefined|undefined]] at the point <math>\scriptstyle x_0</math>.<ref>See, for example, the last sentence in the definition given at Mathwords.[http://www.mathwords.com/r/removable_discontinuity.htm]</ref> This use is abusive because [[Continuous function|continuity]] and discontinuity of a function are concepts defined only for points in the function's domain. Such a point not in the domain is properly named a [[removable singularity]].
 
The [[Oscillation (mathematics)|oscillation]] of a function at a point quantifies these discontinuities as follows:
* in a removable discontinuity, the distance that the value of the function is off by is the oscillation;
* in a jump discontinuity, the size of the jump is the oscillation (assuming that the value ''at'' the point lies between these limits from the two sides);
* in an essential discontinuity, oscillation measures the failure of a limit to exist.
 
==Examples==
[[File:Discontinuity removable.eps.png|thumb|left|The function in example 1, a removable discontinuity]]
1. Consider the function
:<math>f(x) = \begin{cases}
  x^2 & \mbox{ for } x < 1 \\
  0  & \mbox{ for } x = 1 \\
  2-x & \mbox{ for } x > 1
\end{cases}</math>
 
Then, the point <math>\scriptstyle x_0 \;=\; 1</math> is a ''removable discontinuity''.
{{clear}}
 
[[File:Discontinuity jump.eps.png|thumb|left|The function in example 2, a jump discontinuity]]
2. Consider the function 
:<math>f(x) = \begin{cases}
  x^2        & \mbox{ for } x < 1 \\
  0          & \mbox{ for } x = 1 \\
  2 - (x-1)^2 & \mbox{ for } x > 1
\end{cases}</math>
 
Then, the point <math>\scriptstyle x_0 \;=\; 1</math> is a ''jump discontinuity''.
{{clear}}
 
[[File:Discontinuity essential.eps.png|thumb|left|The function in example 3, an essential discontinuity]]
3. Consider the function
:<math>f(x) = \begin{cases}
  \sin\frac{5}{x-1} & \mbox{ for } x < 1 \\
  0                & \mbox{ for } x = 1 \\
  \frac{1}{x-1}  & \mbox{ for } x > 1
\end{cases}</math>
 
Then, the point <math>\scriptstyle x_0 \;=\; 1</math> is an ''essential discontinuity (sometimes called infinite discontinuity)''. For it to be an essential discontinuity, it would have sufficed that only one of the two one-sided limits did not exist or were infinite. However, given this example the discontinuity is also an ''essential discontinuity'' for the extension of the function into complex variables.
{{clear}}
 
==The set of discontinuities of a function==
 
The set of points at which a function is continuous is always a [[G-delta set|G<sub>δ</sub> set]]. The set of discontinuities is an [[F-sigma set|F<sub>σ</sub> set]].
 
The set of discontinuities of a [[monotonic function]] is [[countable|at most countable]]. This is [[Froda's theorem]].
 
''[[Thomae's function]]'' is discontinuous at every [[rational point]], but continuous at every irrational point.
 
The [[indicator function]] of the rationals, also known as the ''[[Dirichlet function]]'', is [[nowhere continuous|discontinuous everywhere]].
 
==See also==
*[[Removable singularity]]
*[[Mathematical singularity]]
*[[Regular_space#Extension_by_continuity|Extension by continuity]]
 
==Notes==
<references />
 
==References==
*{{cite book
| last      = Malik
| first      = S. C.
| coauthors  = Arora, Savita
| title      = Mathematical analysis, 2nd ed
| publisher  = New York: Wiley
| year      = 1992
| pages      =
| isbn      = 0-470-21858-4
}}
 
==External links==
* {{planetmath reference|title=Discontinuous|id=4447}}
* [http://demonstrations.wolfram.com/Discontinuity/ "Discontinuity"] by [[Ed Pegg, Jr.]], [[The Wolfram Demonstrations Project]], 2007.
* {{MathWorld | urlname=Discontinuity | title=Discontinuity}}
* {{SpringerEOM| title=Discontinuity point | id=Discontinuity_point | oldid=12112 | first=L.D. | last=Kudryavtsev }}
 
[[Category:Mathematical analysis]]

Revision as of 21:17, 27 February 2014

Hello and welcome. My name is Figures Wunder. Her family members lives in Minnesota. Playing baseball is the pastime he will never quit performing. For years he's been operating as a receptionist.

Feel free to visit my website hooddirectory.com