Entire function

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In complex analysis, an entire function, also called an integral function, is a complex-valued function that is holomorphic on the whole complex plane. Typical examples of entire functions are polynomials and the exponential function, and any finite sums, products and compositions of these, such as the trigonometric functions sine and cosine and their hyperbolic counterparts sinh and cosh, as well as derivatives and integrals of entire functions such as the error function. If an entire function has a root at , then , taking the limit value at , is an entire function. On the other hand, the natural logarithm, the reciprocal function, and the square root are all not entire functions, nor can they be continued analytically to an entire function.

A transcendental entire function is an entire function that is not a polynomial.

Just as meromorphic functions can be viewed as a generalization of rational fractions, entire functions can be viewed as a generalization of polynomials. In particular, if for meromorphic functions one can generalize the factorization into simple fractions (the Mittag-Leffler theorem on the decomposition of a meromorphic function), then for entire functions there is a generalization of the factorization — the Weierstrass theorem on entire functions.

Properties

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Every entire function   can be represented as a single power series   that converges everywhere in the complex plane, hence uniformly on compact sets. The radius of convergence is infinite, which implies that   or, equivalently,[a]   Any power series satisfying this criterion will represent an entire function.

If (and only if) the coefficients of the power series are all real then the function evidently takes real values for real arguments, and the value of the function at the complex conjugate of   will be the complex conjugate of the value at   Such functions are sometimes called self-conjugate (the conjugate function,   being given by  ).[1]

If the real part of an entire function is known in a neighborhood of a point then both the real and imaginary parts are known for the whole complex plane, up to an imaginary constant. For instance, if the real part is known in a neighborhood of zero, then we can find the coefficients for   from the following derivatives with respect to a real variable  :

 

(Likewise, if the imaginary part is known in a neighborhood then the function is determined up to a real constant.) In fact, if the real part is known just on an arc of a circle, then the function is determined up to an imaginary constant.[b]} Note however that an entire function is not determined by its real part on all curves. In particular, if the real part is given on any curve in the complex plane where the real part of some other entire function is zero, then any multiple of that function can be added to the function we are trying to determine. For example, if the curve where the real part is known is the real line, then we can add   times any self-conjugate function. If the curve forms a loop, then it is determined by the real part of the function on the loop since the only functions whose real part is zero on the curve are those that are everywhere equal to some imaginary number.

The Weierstrass factorization theorem asserts that any entire function can be represented by a product involving its zeroes (or "roots").

The entire functions on the complex plane form an integral domain (in fact a Prüfer domain). They also form a commutative unital associative algebra over the complex numbers.

Liouville's theorem states that any bounded entire function must be constant.[c]

As a consequence of Liouville's theorem, any function that is entire on the whole Riemann sphere[d] is constant. Thus any non-constant entire function must have a singularity at the complex point at infinity, either a pole for a polynomial or an essential singularity for a transcendental entire function. Specifically, by the Casorati–Weierstrass theorem, for any transcendental entire function   and any complex   there is a sequence   such that

 

Picard's little theorem is a much stronger result: Any non-constant entire function takes on every complex number as value, possibly with a single exception. When an exception exists, it is called a lacunary value of the function. The possibility of a lacunary value is illustrated by the exponential function, which never takes on the value  . One can take a suitable branch of the logarithm of an entire function that never hits  , so that this will also be an entire function (according to the Weierstrass factorization theorem). The logarithm hits every complex number except possibly one number, which implies that the first function will hit any value other than   an infinite number of times. Similarly, a non-constant, entire function that does not hit a particular value will hit every other value an infinite number of times.

Liouville's theorem is a special case of the following statement:

Theorem — Assume     are positive constants and   is a non-negative integer. An entire function   satisfying the inequality   for all   with   is necessarily a polynomial, of degree at most  [e] Similarly, an entire function   satisfying the inequality   for all   with   is necessarily a polynomial, of degree at least  .

Growth

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Entire functions may grow as fast as any increasing function: for any increasing function   there exists an entire function   such that   for all real  . Such a function   may be easily found of the form:

 

for a constant   and a strictly increasing sequence of positive integers  . Any such sequence defines an entire function  , and if the powers are chosen appropriately we may satisfy the inequality   for all real  . (For instance, it certainly holds if one chooses   and, for any integer   one chooses an even exponent   such that  ).

Order and type

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The order (at infinity) of an entire function   is defined using the limit superior as:

 

where   is the disk of radius   and   denotes the supremum norm of   on  . The order is a non-negative real number or infinity (except when   for all  ). In other words, the order of   is the infimum of all   such that:

 

The example of   shows that this does not mean   if   is of order  .

If   one can also define the type:

 

If the order is 1 and the type is  , the function is said to be "of exponential type  ". If it is of order less than 1 it is said to be of exponential type 0.

If   then the order and type can be found by the formulas  

Let   denote the  -th derivative of  . Then we may restate these formulas in terms of the derivatives at any arbitrary point  :

 

The type may be infinite, as in the case of the reciprocal gamma function, or zero (see example below under § Order 1).

Another way to find out the order and type is Matsaev's theorem.

Examples

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Here are some examples of functions of various orders:

Order ρ

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For arbitrary positive numbers   and   one can construct an example of an entire function of order   and type   using:

 

Order 0

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  • Non-zero polynomials
  •  

Order 1/4

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  where  

Order 1/3

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  where  

Order 1/2

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  with   (for which the type is given by  )

Order 1

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  •   with   ( )
  •  
  •  
  • the Bessel functions   and spherical Bessel functions   for integer values of  [2]
  • the reciprocal gamma function   (  is infinite)
  •  

Order 3/2

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Order 2

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  •   with   ( )
  • The Barnes G-function (  is infinite).

Order infinity

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  •  

Genus

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Entire functions of finite order have Hadamard's canonical representation (Hadamard factorization theorem):

 

where   are those roots of   that are not zero ( ),   is the order of the zero of   at   (the case   being taken to mean  ),   a polynomial (whose degree we shall call  ), and   is the smallest non-negative integer such that the series

 

converges. The non-negative integer   is called the genus of the entire function  .

If the order   is not an integer, then   is the integer part of  . If the order is a positive integer, then there are two possibilities:   or  .

For example,  ,   and   are entire functions of genus  .

Other examples

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According to J. E. Littlewood, the Weierstrass sigma function is a 'typical' entire function. This statement can be made precise in the theory of random entire functions: the asymptotic behavior of almost all entire functions is similar to that of the sigma function. Other examples include the Fresnel integrals, the Jacobi theta function, and the reciprocal Gamma function. The exponential function and the error function are special cases of the Mittag-Leffler function. According to the fundamental theorem of Paley and Wiener, Fourier transforms of functions (or distributions) with bounded support are entire functions of order   and finite type.

Other examples are solutions of linear differential equations with polynomial coefficients. If the coefficient at the highest derivative is constant, then all solutions of such equations are entire functions. For example, the exponential function, sine, cosine, Airy functions and Parabolic cylinder functions arise in this way. The class of entire functions is closed with respect to compositions. This makes it possible to study dynamics of entire functions.

An entire function of the square root of a complex number is entire if the original function is even, for example  .

If a sequence of polynomials all of whose roots are real converges in a neighborhood of the origin to a limit which is not identically equal to zero, then this limit is an entire function. Such entire functions form the Laguerre–Pólya class, which can also be characterized in terms of the Hadamard product, namely,   belongs to this class if and only if in the Hadamard representation all   are real,  , and  , where   and   are real, and  . For example, the sequence of polynomials

 

converges, as   increases, to  . The polynomials

 

have all real roots, and converge to  . The polynomials

 

also converge to  , showing the buildup of the Hadamard product for cosine.

See also

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Notes

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  1. ^ If necessary, the logarithm of zero is taken to be equal to minus infinity.
  2. ^ For instance, if the real part is known on part of the unit circle, then it is known on the whole unit circle by analytic extension, and then the coefficients of the infinite series are determined from the coefficients of the Fourier series for the real part on the unit circle.
  3. ^ Liouville's theorem may be used to elegantly prove the fundamental theorem of algebra.
  4. ^ The Riemann sphere is the whole complex plane augmented with a single point at infinity.
  5. ^ The converse is also true as for any polynomial   of degree   the inequality   holds for any  

References

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  1. ^ Boas 1954, p. 1.
  2. ^ See asymptotic expansion in Abramowitz and Stegun, p. 377, 9.7.1.

Sources

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  • Boas, Ralph P. (1954). Entire Functions. Academic Press. ISBN 9780080873138. OCLC 847696.
  • Levin, B. Ya. (1980) [1964]. Distribution of Zeros of Entire Functions. American Mathematical Society. ISBN 978-0-8218-4505-9.
  • Levin, B. Ya. (1996). Lectures on Entire Functions. American Mathematical Society. ISBN 978-0-8218-0897-9.