I was considering the following problem:

Suppose you are given a function $u: C \rightarrow C$, find a function $g$ such that $g(g) = u$ (Let's assume that such a function exists). And by "find", I mean give a series representation of $g$ in terms of known special functions as well as values of $u$.

You can chew on that directly, or read some of my work below

This is a special case of (the Inverse Operator Problem)

Suppose you are given a function $u: C \rightarrow C$, find a function $g$ such that for some metafunctional $L$ $L(g) = u$. Which is solved by giving a series representation of $L^{(-1)}$

Which is a generalization of (the Inverse Function Problem)

Suppose you are given a number $x \in C$, find a number $t$ such that for some function $f$ we have that $f(t) = C$. This is solved by giving a series representation of $f^{-1}$ which can be done by the lagrange inversion theorem given knowledge of the values of $f$ and it's derivatives.

Some notation:

functions will be of the form $\text{symbol}(x)$ example $f(x)$, $A(x)$, $e^x+2^x$

meta-functions will be of the form $\text{symbol}(f)$ example $L(f)$, $f'+\frac{1}{f^2 + f(x+1)} $

meta-meta-functionls will be of the form $\text{symbol}(L)$ example $O(L)$, $L(f(x+1)-f(x)) + L^2$

Binding notation: The expression $(U)_{\alpha \leftarrow \beta}$ indicates to evaluate the expression U and then substitute every instance of $\alpha$ with $\beta$. This will be used to avoid ambiguity on operators.

Furthermore it's null-space is the set of all functions, and its linear which gives rise to the following

etc... which is the naturally way a taylor series is generated. Thus we have that:

What has happened here is we have generated a meta-taylor series for the meta funciton $f(f)$ with radius of convergence 0.

I want another operator that actually gives me some non-zero radius of convergence. Because only once I have such a series representation, can I then progress ot create the machinery for a generalized lagrange inversion theorem.

P.S. i'm not sure how but my professor told me it looks like category theory would be helpful in the area i'm trying to invent so I added it as a tag.

I am considering the following problem:

Suppose you are given a function $u: C \rightarrow C$, find a function $g$ such that $g(g) = u$ (Let's assume that such a function exists). And by "find", I mean give a series representation of $g$ in terms of known special functions as well as values of $u$.

This is a special case of (the Inverse Operator Problem):

Suppose you are given a function $u: C \rightarrow C$, find a function $g$ such that for some metafunctional $L$ $L(g) = u$. Which is solved by giving a series representation of $L^{(-1)}$

Which is a generalization of (the Inverse Function Problem):

Suppose you are given a number $x \in C$, find a number $t$ such that for some function $f$ we have that $f(t) = C$. This is solved by giving a series representation of $f^{-1}$ which can be done by the Lagrange inversion theorem given knowledge of the values of $f$ and it's derivatives.

Some notation:

• functions will be of the form $\text{symbol}(x)$ example $f(x)$, $A(x)$, $e^x+2^x$

• meta-functions will be of the form $\text{symbol}(f)$ example $L(f)$, $f'+\frac{1}{f^2 + f(x+1)} $

• meta-meta-functionls will be of the form $\text{symbol}(L)$ example $O(L)$, $L(f(x+1)-f(x)) + L^2$

• Binding notation: The expression $(U)_{\alpha \leftarrow \beta}$ indicates to evaluate the expression U and then substitute every instance of $\alpha$ with $\beta$. This will be used to avoid ambiguity on operators.

Furthermore its null-space is the set of all functions, and its linear which gives rise to the following

etc... which is the naturally way a Taylor series is generated. Thus we have that:

What has happened here is we have generated a meta-taylor series for the meta function $f(f)$ with radius of convergence 0.

I want another operator that actually gives me some non-zero radius of convergence. Because only once I have such a series representation, can I then progress to create the machinery for a generalized Lagrange inversion theorem.