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Line 1: ~~{{Use American English\|date = March 2019}}~~ {{Short description\|Linear combination of indicator functions of real intervals}} {{About\|a piecewise constant function\|the unit step function\|Heaviside step function}} ~~{{More footnotes\|date=February 2019}}~~ In mathematics, a [[function (mathematics)\|function]] on the [[real number]]s is called a '''step function''' ~~(or '''staircase function''')~~ if it can be written as a [[finite set\|finite]] [[linear combination]] of [[indicator function]]s of [[interval (mathematics)\|interval]]s. Informally speaking, a step function is a [[piecewise]] [[constant function]] having only finitely many pieces. [[Image:StepFunctionExample.png\|thumb\|right\|250px\|~~Example~~An example of a step ~~function~~functions (the red graph). In this function, each constant subfunction with a function value ''α<sub>i</sub>'' (''i'' = 0, 1, 2, ...) is defined by an interval ''A<sub>i</sub>'' and intervals are distinguished by points ''x<sub>j</sub>'' (''j'' = 1, 2, ...). This particular step function is [[~~Continuous_function~~Continuous function#~~Directional_and_semi~~Directional and semi-continuity\|right-continuous]].]] ==Definition and first consequences== Line 18 ⟶ 16: In this definition, the intervals <math>A_i</math> can be assumed to have the following two properties: # The intervals are [[disjoint ~~set~~sets\|pairwise disjoint]]: <math>A_i \cap A_j = \emptyset</math> for <math>i \neq j</math> # The [[union (set theory)\|union]] of the intervals is the entire real line: <math>\bigcup_{i=0}^n A_i = \mathbb R.</math> Line 28 ⟶ 26: ===Variations in the definition=== Sometimes, the intervals are required to be right-open<ref>{{Cite web\|url=http://mathworld.wolfram.com/StepFunction.html\|title = Step Function}}</ref> or allowed to be singleton .<ref>{{Cite web\|url=http://mathonline.wikidot.com/step-functions\|title = Step Functions - Mathonline}}</ref>. The condition that the collection of intervals must be finite is often dropped, especially in school mathematics,<ref>{{Cite web\|url=https://www.mathwords.com/s/step_function.htm\|title=Mathwords: Step Function}}</ref><ref>{{Cite web \| title=Archived copy \| url=https://study.com/academy/lesson/step-function-definition-equation-examples.html \| archive-url=https://web.archive.org/web/20150912010951/http://study.com:80/academy/lesson/step-function-definition-equation-examples.html \| access-date=2024-12-16 \| archive-date=2015-09-12}}</ref><ref>{{Cite web\|url=https://www.varsitytutors.com/hotmath/hotmath_help/topics/step-function\|title = Step Function}}</ref>, though it must still be [[Locally finite collection\|locally finite]], resulting in the definition of piecewise constant functions. ==Examples== [[Image:Dirac distribution CDF.svg\|325px\|thumb\|The [[Heaviside step function]] is an often-used step function.]] * A [[constant function]] is a trivial example of a step function. Then there is only one interval, <math>A_0=\mathbb R.</math> * The [[sign function]] <{{math>\\|sgn(''x'')}},~~</math>~~ which is −1 for negative numbers and +1 for positive numbers, and is the simplest non-constant step function. * The [[Heaviside step function\|Heaviside function]] {{math\|''H''(''x'')}}, which is 0 for negative numbers and 1 for positive numbers, is equivalent to the sign function, up to a shift and scale of range (<math>H = (\sgn + 1)/2</math>). It is the mathematical concept behind some test [[Signal (electronics)\|signals]], such as those used to determine the [[step response]] of a [[dynamical system (definition)\|dynamical system]]. [[File:Rectangular function.svg\|thumb\|The [[rectangular function]], the next simplest step function.]] * The [[rectangular function]], the normalized [[boxcar function]], is used to model a unit pulse. === Non-examples === * The [[integer part]] function is not a step function according to the definition of this article, since it has an infinite number of intervals. However, some authors<ref name=bachman_narici_beckenstein>{{Cite book \| author=Bachman, Narici, Beckenstein \| title=Fourier and Wavelet Analysis \| publisher=Springer, New York, 2000 \| isbn=0-387-98899-8 \| chapter =Example 7.2.2\| date=5 April 2002 }}</ref> also define step functions with an infinite number of intervals.<ref name=bachman_narici_beckenstein /> ==Properties== * The sum and product of two step functions is again a step function. The product of a step function with a number is also a step function. As such, the step functions form an [[algebra over a field\|algebra]] over the real numbers. * A step function takes only a finite number of values. If the intervals <math>A_i,</math> for <math>i=0, 1, \dots, n</math> in the above definition of the step function are disjoint and their union is the real line, then <math>f(x)=\alpha_i</math> for all <math>x\in A_i.</math> * The [[definite integral]] of a step function is a [[piecewise linear function]]. * The [[Lebesgue integral]] of a step function <math>\textstyle f = \~~sum\limits_~~sum_{i=0}^n \alpha_i \chi_{A_i}</math> is <math>\textstyle \int f\,dx = \~~sum\limits_~~sum_{i=0}^n \alpha_i \ell(A_i),\,</math> where <math>~~\textstyle~~\ell(A)</math> is the length of the interval <math>A,</math>, and it is assumed here that all intervals <math>A_i</math> have finite length. In fact, this equality (viewed as a definition) can be the first step in constructing the Lebesgue integral.<ref>{{Cite book \| author=Weir, Alan J ~~\| authorlink=~~ \| title=Lebesgue integration and measure \| date= 10 May 1973\| publisher=Cambridge University Press, 1973 ~~\| ___location=~~ \| isbn=0-521-09751-7 \|chapter= 3}}</ref> * A [[discrete random variable]] is sometimes defined as a [[random variable]] whose [[cumulative distribution function]] is piecewise constant.<ref name=":0">{{Cite book\|title=Introduction to Probability\|last=~~[[Dimitri_Bertsekas~~Bertsekas\|author-link=Dimitri Bertsekas]]\|first=Dimitri P.\|date=2002\|publisher=Athena Scientific\|others=[[~~John_Tsitsiklis~~John Tsitsiklis\|Tsitsiklis, John N.]], Τσιτσικλής, Γιάννης Ν.\|isbn=188652940X\|___location=Belmont, Mass.~~\|pages=~~\|oclc=51441829}}</ref> In this case, it is locally a step function (globally, it may have an infinite number of steps). Usually however, any random variable with only countably many possible values is called a discrete random variable, in this case their cumulative distribution function is not necessarily locally a step function, as infinitely many intervals can accumulate in a finite region. ==See also== * [[~~Unit step~~Crenel function]] * [[~~Crenel function~~Piecewise]] * [[~~Simple~~Sigmoid function]] * [[~~Piecewise defined~~Simple function]] * [[~~Sigmoid~~Step ~~function~~detection]] * [[Heaviside step function]] [[Step detection]] [[Piecewise-constant valuation]] ==References== {{~~reflist~~Reflist}} {{DEFAULTSORT:Step Function}}