Exponential function

Exponential function or exp, can be defined as solution of differential equaiton

${\displaystyle \exp ^{\prime }(z)=\exp(z)}$

with additional condition

${\displaystyle \exp(0)=1}$

Exponential function is believed to be invented by Leonarf Euler some centuries ago. Since that time, it is widely used in technology and science; in particular, the exponential growth is described with such function.

Properties

exp is entire function.

For any comples ${\displaystyle p}$ and ${\displaystyle q}$, the basic property holds:

${\displaystyle \exp(a)~\exp(b)=\exp(a+b)}$

The definition allows to calculate all the derrivatives at zero; so, the Tailor expansion has form

${\displaystyle \exp(z)=\sum _{n=0}^{\infty }{\frac {z^{n}}{n!}}~~\forall z\in \mathbb {C} }$

where ${\displaystyle \mathbb {C} }$ means the set of complex numbers. The series converges for and complex ${\displaystyle z}$. In particular, the series converge for any real value of the argument.

Inverse function

Inverse function of the exponential is logarithm; for any complex ${\displaystyle z\neq 0}$, the relation holds:

${\displaystyle \exp(\log(z))=z~\forall z\in \mathbb {C} }$

Exponential also can be considered as inverse of logarithm, while the imaginary part of the argument is smaller than ${\displaystyle \pi }$:

${\displaystyle \log(\exp(z))=z~\forall z\in \mathbb {C} ~\mathrm {~such~that~} |\Im (z)|<\pi }$

While lofarithm has cut at the negative part of the real axis, exp can be considered

Number e

${\displaystyle \mathrm {e} =\exp(1)}$ is widely used in applications; this notation is commonly accepted. Its approximate value is

Failed to parse (syntax error): {\displaystyle {\rm e}=\exp(1) \approx 2.71828 18284 59045 23536}

Relation with sin and cos functions

${\displaystyle \exp(\mathrm {i} z)=\cos(z)+\mathrm {i} \sin(z)~\forall z\in \mathbb {C} }$

Generalization of exponential

${\displaystyle \exp ^{c}(z)}$ in the complex ${\displaystyle z}$ plane for some real values of ${\displaystyle c}$.

${\displaystyle \exp ^{c}(x)}$ versus ${\displaystyle x}$ for some real values of ${\displaystyle c}$.

Notation ${\displaystyle \exp _{b}}$ is used for the exponential with scaled argument;

${\displaystyle \exp _{b}(z)=b^{z}=\exp(\log(b)z)}$

Notation ${\displaystyle \exp _{b}^{c}}$ is used for the iterated exponential:

${\displaystyle \exp _{b}^{0}(z)=z}$

${\displaystyle \exp _{b}^{1}(z)=\exp _{b}(z)}$

${\displaystyle \exp _{b}^{2}(z)=\exp _{b}(\exp _{b}(z)}$

${\displaystyle \exp _{b}^{c+1}(z)=\exp _{b}(\exp _{b}^{c}(z)}$

For non-integer values of ${\displaystyle c}$, the iterated exponential can be defined as

${\displaystyle \exp _{b}^{c}(z)=\mathrm {sexp} _{b}{\Big (}c+{\mathrm {sexp} _{b}}^{-1}(z){\Big )}}$

where ${\displaystyle \mathrm {sexp} _{b}(z)}$ is function ${\displaystyle F}$ satisfying conditions

${\displaystyle F(z+1)=\exp _{b}(F(z))}$

${\displaystyle F(0)=1}$

${\displaystyle F(z)~\mathrm {~is~holomorphic~and~bounded~at} ~|\Re (z)|<1}$

The inverse function is defined with condition

${\displaystyle F{\Big (}F^{-1}(z){\Big )}=z}$

and, within some range of values of ${\displaystyle z}$

${\displaystyle F^{-1}{\Big (}F(z){\Big )}=z}$

If in the notation ${\displaystyle \exp _{b}^{c}}$ superscript is omitted, it is assumed to be unity; for example ${\displaystyle \exp _{b}^{1}=\exp _{b}}$. If the lower superscript is omitter, it is assumed to be ${\displaystyle \mathrm {e} }$, id est, ${\displaystyle \exp ^{c}=\exp _{\mathrm {e} }^{c}}$

References

• Ahlfors, Lars V. (1953). Complex analysis. McGraw-Hill Book Company, Inc..
• H.Kneser. ``Reelle analytische L\"osungen der Gleichung ${\displaystyle \varphi (\varphi (x))=\mathrm {e} ^{x}}$

und verwandter Funktionalgleichungen. Journal f\"ur die reine und angewandte Mathematik, 187 (1950), 56-67.