Superfunction

Superfunction comes from iteration of another function. Roughly, for some function ${\displaystyle f}$ and for some constant ${\displaystyle t}$, the superfunction could be defined with expression

${\displaystyle {{S(z)} \atop \,}{= \atop \,}{{\underbrace {f{\Big (}f{\big (}...f(t)...{\big )}{\Big )}} } \atop {z\mathrm {~evaluations~of~function~} f\!\!\!\!\!\!}}}$

then ${\displaystyle S}$ can be interpreted as superfunction of function ${\displaystyle f}$. Such definition is valid only for positive integer ${\displaystyle z}$. The most research and appllications around the superfunctions is related with various extensions of superfunction; and analysis of the existence, uniqueness and ways of the evaluation. For simple function ${\displaystyle f}$, such as addition of a constant or multiplication by a constant, the superfunction can be expressed in terms of elementary function. In particular, the Ackernann functions and tetration can be interpreted in terms of super-functions.

Superfunctions and their inverse functions allow evaluation of not onlu minus-first power of a function (inverse function), but also function in any real or even complex power. Historically, first function of such kind considered was ${\displaystyle {\sqrt {\exp }}~}$; then, function ${\displaystyle {\sqrt {!~}}~}$ was used as logo of the Physics department of the Moscow State University. That time, researchers did not have computational facilities for evaluation of such functions, but the ${\displaystyle {\sqrt {\exp }}}$ was more lucky than the ${\displaystyle ~{\sqrt {!~}}~}$ : at least the existence of holomorphic function ${\displaystyle {\sqrt {\exp }}}$ has been demonstrated in 1950 by Belmuth Kneser ^[1].

Extensions

The recurrence above can be written as equations

${\displaystyle S(z\!+\!1)=f(S(z))~\forall z\in \mathbb {N} :z>0}$

${\displaystyle S(1)=f(t)}$.

Instead of the last equation, one could write

${\displaystyle S(0)=f(t)}$

and extend the range of definition of superfunction ${\displaystyle S}$ to the non-negative integers. Then, one may postulate

${\displaystyle S(-1)=t}$

and extend the range of validity to the integer values larger than ${\displaystyle -2}$. The following extension, for example,

${\displaystyle S(-2)=f^{-1}(t)}$

is not trifial, because the inverse function may happen to be not defined for some values of ${\displaystyle t}$. In particular, tetration can be interpreted as super-function of exponential for some real base ${\displaystyle b}$; in this case,

${\displaystyle f=\exp _{b}}$

then, at ${\displaystyle t=0}$,

${\displaystyle S(-1)=\log _{b}(1)=0}$.

but

${\displaystyle S(-2)=\log _{b}(0)~\mathrm {is~not~defined} }$.

For extension to non-integer values of the argument, superfunction should be defined in different way.

Definition

For complex numbers ${\displaystyle ~a~}$ and ${\displaystyle ~b~}$, such that ${\displaystyle ~a~}$ belongs to some domain ${\displaystyle D\subseteq \mathbb {C} }$,
superfunction (from ${\displaystyle a}$ to ${\displaystyle b}$) of holomorphic function ${\displaystyle ~f~}$ on domain ${\displaystyle D}$ is function ${\displaystyle S}$, holomorphic on domain ${\displaystyle D}$, such that

${\displaystyle S(z\!+\!1)=f(S(z))~\forall z\in D:z\!+\!1\in D}$

${\displaystyle S(a)=b}$.

Examples

Addition

Chose a complex number ${\displaystyle c}$ and define function ${\displaystyle \mathrm {add} _{c}}$ with relation ${\displaystyle \mathrm {add} _{c}(z)=c\!+\!z~\forall z\in \mathbb {C} }$ . Define function ${\displaystyle \mathrm {mul_{c}} }$ with relation ${\displaystyle \mathrm {mul_{c}} (z)=c\!\cdot \!z~\forall z\in \mathbb {C} }$.

Then, function ${\displaystyle ~\mathrm {mul_{c}} ~}$ is superfunction (${\displaystyle ~0}$ to ${\displaystyle ~c~}$) of function ${\displaystyle ~\mathrm {add_{c}} ~}$ on ${\displaystyle ~\mathbb {C} ~}$.

Multiplication

Exponentiation ${\displaystyle \exp _{c}}$ is superfunction (from 1 to ${\displaystyle c}$) of function ${\displaystyle \mathrm {mul} _{c}}$.

Abel function

Inverse of superfunction can be interpreted as the Abel function.

For some domain ${\displaystyle E\subseteq \mathbb {C} }$ and some ${\displaystyle u\in E}$,${\displaystyle v\in \mathbb {C} }$,
Abel function (from ${\displaystyle u}$ to ${\displaystyle v}$ ) of function ${\displaystyle F}$ with respect to superfunction ${\displaystyle S}$ on domain ${\displaystyle E\in \mathbb {C} }$ is holomorphic function ${\displaystyle A}$ from ${\displaystyle E}$ to ${\displaystyle D}$ such that

${\displaystyle S(A(z))=z~\forall z\in E}$

${\displaystyle A(u)=c}$

The definitionm above does not reuqire that ${\displaystyle A(S(z))=z~\forall z\in D}$; although, from properties of holomorphic functions, there should exost some subset ${\displaystyle {\mathcal {D}}\subseteq D}$ such that ${\displaystyle A(S(z))=z~\forall z\in {\mathcal {D}}}$. In this subset, the Abel function satisfies the Abel equation.

Abel equation

The Abel equation is some equivalent of the recurrent equation

${\displaystyle F(S(z))=S(z\!+\!1)}$

in the definition of the superfunction. However, it may hold for ${\displaystyle x}$ from the reduced domain ${\displaystyle {\mathcal {D}}}$.

Applications of superfunctions and Abel functions

References