E-function: Difference between revisions
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{{for|the generalization of hypergeometric series |MacRobert E function}} |
{{for|the generalization of hypergeometric series |MacRobert E function}} |
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In [[mathematics]], '''E-functions''' are a type of [[power series]] that satisfy particular arithmetic conditions on the coefficients. They are of interest in [[transcendental number theory]], and are |
In [[mathematics]], '''E-functions''' are a type of [[power series]] that satisfy particular arithmetic conditions on the coefficients. They are of interest in [[transcendental number theory]], and are closely related to [[G-function (power series)|G-function]]s. |
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==Definition== |
==Definition== |
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A power series with coefficients in the field of algebraic numbers |
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A function {{math|1=''f''(''x'')}} is called of '''type {{math|1=''E''}}''', or an '''{{math|1=''E''}}-function''',<ref>Carl Ludwig Siegel, ''Transcendental Numbers'', p.33, Princeton University Press, 1949.</ref> if the power series |
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:<math>f(x)=\sum_{n=0}^\infty c_n \frac{x^n}{n!}</math> |
:<math>f(x)=\sum_{n=0}^\infty c_n \frac{x^n}{n!} \in \overline{\mathbb{Q}}[\![x]\!]</math> |
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satisfies the following three conditions: |
is called an '''{{math|1=''E''}}-function'''<ref>Carl Ludwig Siegel, ''Transcendental Numbers'', p.33, Princeton University Press, 1949.</ref> if it satisfies the following three conditions: |
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* |
* It is a solution of a non-zero linear differential equation with polynomial coefficients (this implies that all the coefficients {{math|1=''c<sub>n</sub>''}} belong to the same [[algebraic number field]], {{math|1=''K''}}, which has [[Degree of a field extension|finite degree]] over the rational numbers); |
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* For all <math> \varepsilon>0</math>, <math>\overline{\left|c_n\right|}=O\left(n^{n\varepsilon}\right),</math> |
* For all <math> \varepsilon>0</math>, <math>\overline{\left|c_n\right|}=O\left(n^{n\varepsilon}\right),</math> |
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: where the left hand side represents the maximum of the absolute values of all the [[Conjugate element (field theory)|algebraic conjugates]] of {{math|1=''c<sub>n</sub>''}}; |
: where the left hand side represents the maximum of the absolute values of all the [[Conjugate element (field theory)|algebraic conjugates]] of {{math|1=''c<sub>n</sub>''}}; |
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* For all <math> \varepsilon>0</math> there is a sequence of natural numbers {{math|1=''q''<sub>0</sub>, ''q''<sub>1</sub>, ''q''<sub>2</sub>,...}} such that {{math|1=''q<sub>n</sub>c<sub>k</sub>''}} is an [[algebraic integer]] in {{math|1=''K''}} for {{math|1=''k'' = 0, 1, 2,..., ''n''}}, and {{math|1=''n'' = 0, 1, 2,...}} and for which |
* For all <math> \varepsilon>0</math> there is a sequence of natural numbers {{math|1=''q''<sub>0</sub>, ''q''<sub>1</sub>, ''q''<sub>2</sub>,...}} such that {{math|1=''q<sub>n</sub>c<sub>k</sub>''}} is an [[algebraic integer]] in {{math|1=''K''}} for {{math|1=''k'' = 0, 1, 2,..., ''n''}}, and {{math|1=''n'' = 0, 1, 2,...}} and for which <math>q_n=O\left(n^{n\varepsilon}\right). </math> |
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:<math>q_n=O\left(n^{n\varepsilon}\right). </math> |
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The second condition implies that {{math|1=''f''}} is an [[entire function]] of {{math|1=''x''}}. |
The second condition implies that {{math|1=''f''}} is an [[entire function]] of {{math|1=''x''}}. |
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# Any polynomial with algebraic coefficients is a simple example of an {{math|1=''E''}}-function. |
# Any polynomial with algebraic coefficients is a simple example of an {{math|1=''E''}}-function. |
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# The [[exponential function]] is an {{math|1=''E''}}-function, in its case {{math|1=''c<sub>n</sub>''=1}} for all of the {{math|1=''n''}}. |
# The [[exponential function]] is an {{math|1=''E''}}-function, in its case {{math|1=''c<sub>n</sub>'' = 1}} for all of the {{math|1=''n''}}. |
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# If {{math|1=λ}} is an algebraic number then the [[Bessel function]] {{math|1=''J''<sub>λ</sub>}} is an {{math|1=''E''}}-function. |
# If {{math|1=λ}} is an algebraic number then the [[Bessel function]] {{math|1=''J''<sub>λ</sub>}} is an {{math|1=''E''}}-function. |
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# The sum or product of two {{math|1=''E''}}-functions is an {{math|1=''E''}}-function. In particular {{math|1=''E''}}-functions form a [[Ring (mathematics)|ring]]. |
# The sum or product of two {{math|1=''E''}}-functions is an {{math|1=''E''}}-function. In particular {{math|1=''E''}}-functions form a [[Ring (mathematics)|ring]]. |
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* {{mathworld|title=E-Function|urlname=E-Function}} |
* {{mathworld|title=E-Function|urlname=E-Function}} |
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[[Category: |
[[Category:Transcendental numbers]] |
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[[Category:Algebraic number theory]] |
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[[Category:Analytic functions]] |
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[[Category:Analytic number theory]] |
Latest revision as of 21:37, 16 September 2024
In mathematics, E-functions are a type of power series that satisfy particular arithmetic conditions on the coefficients. They are of interest in transcendental number theory, and are closely related to G-functions.
Definition
[edit]A power series with coefficients in the field of algebraic numbers
is called an E-function[1] if it satisfies the following three conditions:
- It is a solution of a non-zero linear differential equation with polynomial coefficients (this implies that all the coefficients cn belong to the same algebraic number field, K, which has finite degree over the rational numbers);
- For all ,
- where the left hand side represents the maximum of the absolute values of all the algebraic conjugates of cn;
- For all there is a sequence of natural numbers q0, q1, q2,... such that qnck is an algebraic integer in K for k = 0, 1, 2,..., n, and n = 0, 1, 2,... and for which
The second condition implies that f is an entire function of x.
Uses
[edit]E-functions were first studied by Siegel in 1929.[2] He found a method to show that the values taken by certain E-functions were algebraically independent. This was a result which established the algebraic independence of classes of numbers rather than just linear independence.[3] Since then these functions have proved somewhat useful in number theory and in particular they have application in transcendence proofs and differential equations.[4]
The Siegel–Shidlovsky theorem
[edit]Perhaps the main result connected to E-functions is the Siegel–Shidlovsky theorem (also known as the Siegel and Shidlovsky theorem), named after Carl Ludwig Siegel and Andrei Borisovich Shidlovsky.
Suppose that we are given n E-functions, E1(x),...,En(x), that satisfy a system of homogeneous linear differential equations
where the fij are rational functions of x, and the coefficients of each E and f are elements of an algebraic number field K. Then the theorem states that if E1(x),...,En(x) are algebraically independent over K(x), then for any non-zero algebraic number α that is not a pole of any of the fij the numbers E1(α),...,En(α) are algebraically independent.
Examples
[edit]- Any polynomial with algebraic coefficients is a simple example of an E-function.
- The exponential function is an E-function, in its case cn = 1 for all of the n.
- If λ is an algebraic number then the Bessel function Jλ is an E-function.
- The sum or product of two E-functions is an E-function. In particular E-functions form a ring.
- If a is an algebraic number and f(x) is an E-function then f(ax) will be an E-function.
- If f(x) is an E-function then the derivative and integral of f are also E-functions.
References
[edit]- ^ Carl Ludwig Siegel, Transcendental Numbers, p.33, Princeton University Press, 1949.
- ^ C.L. Siegel, Über einige Anwendungen diophantischer Approximationen, Abh. Preuss. Akad. Wiss. 1, 1929.
- ^ Alan Baker, Transcendental Number Theory, pp.109-112, Cambridge University Press, 1975.
- ^ Serge Lang, Introduction to Transcendental Numbers, pp.76-77, Addison-Wesley Publishing Company, 1966.