Difference between revisions of "Periodic function"
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A function having a period (cf. [[Period of a function|Period of a function]]). | A function having a period (cf. [[Period of a function|Period of a function]]). | ||
| − | Let a function | + | Let a function $ f $ |
| + | be defined on $ X \subset \mathbf R $ | ||
| + | and have period $ T $. | ||
| + | To obtain the graph of $ f $ | ||
| + | it is sufficient to have the graph of $ f $ | ||
| + | on $ [ a, a+ T] \cap X $, | ||
| + | where $ a $ | ||
| + | is a certain number, and shift it along $ \mathbf R $ | ||
| + | over $ \pm T, \pm 2T ,\dots $. | ||
| + | If a periodic function $ f $ | ||
| + | with period $ T $ | ||
| + | has a finite derivative $ f ^ { \prime } $, | ||
| + | then $ f ^ { \prime } $ | ||
| + | is a periodic function with the same period. Let $ f $ | ||
| + | be integrable over any segment and have period $ T $. | ||
| + | The indefinite integral $ F( x)= \int _ {0} ^ {x} f( t) dt $ | ||
| + | has period $ T $ | ||
| + | if $ \int _ {0} ^ {T} f( t) dt = 0 $, | ||
| + | otherwise it is non-periodic, such as for example for $ f( x) = \cos x+ 1 $, | ||
| + | where $ F( x) = \sin x + x $. | ||
''A.A. Konyushkov'' | ''A.A. Konyushkov'' | ||
| − | A periodic function of a complex variable | + | A periodic function of a complex variable $ z $ |
| + | is a single-valued analytic function $ f( z) $ | ||
| + | having only isolated singular points (cf. [[Singular point|Singular point]]) in the complex $ z $- | ||
| + | plane $ \mathbf C $ | ||
| + | and for which there exists a complex number $ p \neq 0 $, | ||
| + | called a period of the function $ f( z) $, | ||
| + | such that | ||
| − | + | $$ | |
| + | f( z+ p) = f( z),\ \ | ||
| + | z \in \mathbf C . | ||
| + | $$ | ||
| − | Any linear combination of the periods of a given periodic function | + | Any linear combination of the periods of a given periodic function $ f( z) $ |
| + | with integer coefficients is also a period of $ f( z) $. | ||
| + | The set of all periods of a given periodic function $ f( z) \neq \textrm{ const } $ | ||
| + | constitutes a discrete Abelian group under addition, called the period group of $ f( z) $. | ||
| + | If the basis of this group consists of one unique basic, or primitive, period $ 2 \omega = 2 \omega _ {1} \neq 0 $, | ||
| + | i.e. if any period $ p $ | ||
| + | is an integer multiple of $ 2 \omega $, | ||
| + | then $ f( z) $ | ||
| + | is called a [[Simply-periodic function|simply-periodic function]]. In the case of a basis consisting of two basic periods $ 2 \omega _ {1} , 2 \omega _ {3} $, | ||
| + | $ \mathop{\rm Im} ( \omega _ {1} / \omega _ {3} ) \neq 0 $, | ||
| + | one has a [[Double-periodic function|double-periodic function]]. If the periodic function $ f( z) $ | ||
| + | is not a constant, then a basis of its period group cannot consist of more than two basic independent periods (Jacobi's theorem). | ||
Any strip of the form | Any strip of the form | ||
| − | + | $$ | |
| + | \{ {z = ( \tau e ^ {i \alpha } + t) 2 \omega } : {- \infty < \tau < \infty , 0 \leq t < 1 ,\ | ||
| + | 0 < \alpha \leq \pi /2 } \} | ||
| + | , | ||
| + | $$ | ||
| − | where | + | where $ 2 \omega $ |
| + | is one of the basic periods of $ f( z) $ | ||
| + | or is congruent to it, is called a period strip of $ f( z) $; | ||
| + | one usually takes $ \alpha = \pi /2 $, | ||
| + | i.e. one considers a period strip with sides perpendicular to the basic period $ 2 \omega $. | ||
| + | In each period strip, a periodic function takes any of its values and moreover equally often. | ||
| − | Any entire periodic function | + | Any entire periodic function $ f( z) $ |
| + | can be expanded into a Fourier series throughout $ \mathbf C $: | ||
| − | + | $$ \tag{* } | |
| + | f( z) = \sum _ {k=- \infty } ^ \infty a _ {k} e ^ {\pi ikz/ \omega } , | ||
| + | $$ | ||
| − | + | $$ | |
| + | a _ {k} = | ||
| + | \frac{1}{2 \omega } | ||
| + | \int\limits _ {- \infty } ^ \infty f( t) e ^ {- \pi ikt/ \omega } dt, | ||
| + | $$ | ||
| − | which converges uniformly and absolutely on the straight line | + | which converges uniformly and absolutely on the straight line $ \{ {z = t \omega } : {- \infty < t < \infty } \} $ |
| + | and, in general, on any arbitrarily wide strip of finite width parallel to that line. The case when an entire periodic function $ f( z) $ | ||
| + | tends to a certain finite or infinite limit at each of the two ends of the period strip is characterized by the fact that the series (*) contains only a finite number of terms, i.e. $ f( z) $ | ||
| + | should be a [[Trigonometric polynomial|trigonometric polynomial]]. | ||
| − | Any meromorphic periodic function | + | Any meromorphic periodic function $ f( z) $ |
| + | throughout $ \mathbf C $ | ||
| + | with basic period $ 2 \omega $ | ||
| + | can be represented as the quotient of two entire periodic functions with the same period, i.e. as the quotient of two series of the form (*). In particular, the class of all [[Trigonometric functions|trigonometric functions]] can be described as the class of meromorphic periodic functions with period $ 2 \pi $ | ||
| + | that in each period strip have only a finite number of poles and tend to a definite limit at each end of the period strip. | ||
====References==== | ====References==== | ||
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====Comments==== | ====Comments==== | ||
| − | In 1), the assertion that | + | In 1), the assertion that $ f $ |
| + | has period $ T $ | ||
| + | means that $ T \neq 0 $, | ||
| + | and $ x \in X $ | ||
| + | implies $ x \pm T \in X $ | ||
| + | and $ f( x \pm T) = f( x) $. | ||
Double-periodic functions are also known as elliptic functions (cf. [[Elliptic function|Elliptic function]]). | Double-periodic functions are also known as elliptic functions (cf. [[Elliptic function|Elliptic function]]). | ||
Latest revision as of 08:05, 6 June 2020
A function having a period (cf. Period of a function).
Let a function $ f $ be defined on $ X \subset \mathbf R $ and have period $ T $. To obtain the graph of $ f $ it is sufficient to have the graph of $ f $ on $ [ a, a+ T] \cap X $, where $ a $ is a certain number, and shift it along $ \mathbf R $ over $ \pm T, \pm 2T ,\dots $. If a periodic function $ f $ with period $ T $ has a finite derivative $ f ^ { \prime } $, then $ f ^ { \prime } $ is a periodic function with the same period. Let $ f $ be integrable over any segment and have period $ T $. The indefinite integral $ F( x)= \int _ {0} ^ {x} f( t) dt $ has period $ T $ if $ \int _ {0} ^ {T} f( t) dt = 0 $, otherwise it is non-periodic, such as for example for $ f( x) = \cos x+ 1 $, where $ F( x) = \sin x + x $.
A.A. Konyushkov
A periodic function of a complex variable $ z $ is a single-valued analytic function $ f( z) $ having only isolated singular points (cf. Singular point) in the complex $ z $- plane $ \mathbf C $ and for which there exists a complex number $ p \neq 0 $, called a period of the function $ f( z) $, such that
$$ f( z+ p) = f( z),\ \ z \in \mathbf C . $$
Any linear combination of the periods of a given periodic function $ f( z) $ with integer coefficients is also a period of $ f( z) $. The set of all periods of a given periodic function $ f( z) \neq \textrm{ const } $ constitutes a discrete Abelian group under addition, called the period group of $ f( z) $. If the basis of this group consists of one unique basic, or primitive, period $ 2 \omega = 2 \omega _ {1} \neq 0 $, i.e. if any period $ p $ is an integer multiple of $ 2 \omega $, then $ f( z) $ is called a simply-periodic function. In the case of a basis consisting of two basic periods $ 2 \omega _ {1} , 2 \omega _ {3} $, $ \mathop{\rm Im} ( \omega _ {1} / \omega _ {3} ) \neq 0 $, one has a double-periodic function. If the periodic function $ f( z) $ is not a constant, then a basis of its period group cannot consist of more than two basic independent periods (Jacobi's theorem).
Any strip of the form
$$ \{ {z = ( \tau e ^ {i \alpha } + t) 2 \omega } : {- \infty < \tau < \infty , 0 \leq t < 1 ,\ 0 < \alpha \leq \pi /2 } \} , $$
where $ 2 \omega $ is one of the basic periods of $ f( z) $ or is congruent to it, is called a period strip of $ f( z) $; one usually takes $ \alpha = \pi /2 $, i.e. one considers a period strip with sides perpendicular to the basic period $ 2 \omega $. In each period strip, a periodic function takes any of its values and moreover equally often.
Any entire periodic function $ f( z) $ can be expanded into a Fourier series throughout $ \mathbf C $:
$$ \tag{* } f( z) = \sum _ {k=- \infty } ^ \infty a _ {k} e ^ {\pi ikz/ \omega } , $$
$$ a _ {k} = \frac{1}{2 \omega } \int\limits _ {- \infty } ^ \infty f( t) e ^ {- \pi ikt/ \omega } dt, $$
which converges uniformly and absolutely on the straight line $ \{ {z = t \omega } : {- \infty < t < \infty } \} $ and, in general, on any arbitrarily wide strip of finite width parallel to that line. The case when an entire periodic function $ f( z) $ tends to a certain finite or infinite limit at each of the two ends of the period strip is characterized by the fact that the series (*) contains only a finite number of terms, i.e. $ f( z) $ should be a trigonometric polynomial.
Any meromorphic periodic function $ f( z) $ throughout $ \mathbf C $ with basic period $ 2 \omega $ can be represented as the quotient of two entire periodic functions with the same period, i.e. as the quotient of two series of the form (*). In particular, the class of all trigonometric functions can be described as the class of meromorphic periodic functions with period $ 2 \pi $ that in each period strip have only a finite number of poles and tend to a definite limit at each end of the period strip.
References
| [1] | A.I. Markushevich, "Theory of functions of a complex variable" , 2 , Chelsea (1977) (Translated from Russian) |
E.D. Solomentsev
Comments
In 1), the assertion that $ f $ has period $ T $ means that $ T \neq 0 $, and $ x \in X $ implies $ x \pm T \in X $ and $ f( x \pm T) = f( x) $.
Double-periodic functions are also known as elliptic functions (cf. Elliptic function).
References
| [a1] | C.L. Siegel, "Topics in complex functions" , 1 , Wiley, reprint (1988) |
Periodic function. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Periodic_function&oldid=15049