E-function

In mathematics, E-functions are a type of power series that satisfy particular arithmetic conditions on the coefficients. They are of interest in transcendence theory, and are more special than G-functions.

A function f(x) is called of type E, or an E-function^[1], if the power series

${\displaystyle f(x)=\sum _{n=0}^{\infty }c_{n}{\frac {x^{n}}{n!}}}$

satisfies the following three conditions:

• All the coefficients c_n belong to the same algebraic number field, K, which has finite degree over the rational numbers;
• For all ε > 0,

${\displaystyle {\overline {\left|c_{n}\right|}}=O\left(n^{n\varepsilon }\right)}$,

where the left hand side represents the maximum of the absolute values of all the algebraic conjugates of c_n;

• For all ε > 0 there is a sequence of natural numbers q₀, q₁, q₂,… such that q_nc_k is an algebraic integer in K for k=0, 1, 2,…, n, and n = 0, 1, 2,… and for which

${\displaystyle q_{n}=O\left(n^{n\varepsilon }\right)}$.

The second condition implies that f is an entire function of x.

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, one of the only results of the early twentieth century 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].

Perhaps the main result connected to E-functions is the Siegel-Shidlovsky theorem (known also as the Shidlovsky and Shidlovskii theorem).

Suppose that we are given n E-functions, E₁(x),…,E_n(x), that satisfy a system of homogeneous linear differential equations

${\displaystyle y_{i}^{\prime }=\sum _{j=1}^{n}f_{ij}(x)y_{j}\quad (1\leq i\leq n)}$

where the f_ij 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),…,E_n(x) are algebraically independent over K(x), then for any non-zero algebraic number α that is not a pole of any of the f_ij the numbers E₁(α),…,E_n(α) are algebraically independent.

1. Any polynomial with algebraic coefficients is a simple example of an E-function.
2. The exponential function is an E-function, in its case c_n=1 for all of the n.
3. If λ is an algebraic number then the Bessel function J_λ is an E-function.
4. The sum or product of two E-functions is an E-function. In particular E-functions form a ring.
5. If a is an algebraic number and f(x) is an E-function then f(ax) will be an E-function.
6. If f(x) is an E-function then the derivative and integral of f are also E-functions.

• Weisstein, Eric W. "E-Function". MathWorld.