Difference between revisions of "Fractional iterate"

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[[Fractional iterate]] is concept used to construct non-integer iterates of functions.
 
[[Fractional iterate]] is concept used to construct non-integer iterates of functions.
   
For a given function $~T~$, [[holomorphic function|holomorphic]] in vicinity of its [[fixed point]] $~L~$, the function
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For a given function \(~T~\), [[holomorphic function|holomorphic]] in vicinity of its [[fixed point]] \(~L~\), the function
$t_r=T^r$ is called as $~r$th [[fractional iterate]], iff $~r\!=\!m/n~$ for some integer numbers $~m, n~$ and
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\(t_r=T^r\) is called as \(~r\)th [[fractional iterate]], iff \(~r\!=\!m/n~\) for some integer numbers \(~m, n~\) and
   
(1) $~ ~ ~ t_r^m(z)=T^n(z)~$
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(1) \(~ ~ ~ t_r^m(z)=T^n(z)~\)
   
for all $~z~$ in some vicinity of $~L~$.
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for all \(~z~\) in some vicinity of \(~L~\).
   
If such a function $t_r$ is also regular in vicinity of $~L~$, then such a fractional iterate is called [[regular iterate]] of function $~T~$ with number of iteration $~r~$ at fixed point $~L~$.
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If such a function \(t_r\) is also regular in vicinity of \(~L~\), then such a fractional iterate is called [[regular iterate]] of function \(~T~\) with number of iteration \(~r~\) at fixed point \(~L~\).
   
 
==Specification of fractional iterate==
 
==Specification of fractional iterate==
In general, specifying non–integer iterate of some function $~T~$, one should provide some additional information that provides the uniqueness. Such a condition can be indication of the fixed point $~T~$, at which the iterate is regular.
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In general, specifying non–integer iterate of some function \(~T~\), one should provide some additional information that provides the uniqueness. Such a condition can be indication of the fixed point \(~T~\), at which the iterate is regular.
   
An alternative could be specification of behavior at infinity, or specification of the [[superfunction]] $F$ and the [[Abel function]] $G=F^{-1}$, used to construct the fractional iterate $T^r$ with
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An alternative could be specification of behavior at infinity, or specification of the [[superfunction]] \(F\) and the [[Abel function]] \(G=F^{-1}\), used to construct the fractional iterate \(T^r\) with
   
(2) $~ ~ ~ R^r=F\big(r+G(z)\big)~$
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(2) \(~ ~ ~ R^r=F\big(r+G(z)\big)~\)
   
If the only one way of the construction of non-integer iterate is indicated, then the simple writing $T^r$ is sufficient to indicate the $r$th iterate of function $T$.
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If the only one way of the construction of non-integer iterate is indicated, then the simple writing \(T^r\) is sufficient to indicate the \(r\)th iterate of function \(T\).
   
 
==References==
 
==References==

Latest revision as of 18:25, 30 July 2019

Fractional iterate is concept used to construct non-integer iterates of functions.

For a given function \(~T~\), holomorphic in vicinity of its fixed point \(~L~\), the function \(t_r=T^r\) is called as \(~r\)th fractional iterate, iff \(~r\!=\!m/n~\) for some integer numbers \(~m, n~\) and

(1) \(~ ~ ~ t_r^m(z)=T^n(z)~\)

for all \(~z~\) in some vicinity of \(~L~\).

If such a function \(t_r\) is also regular in vicinity of \(~L~\), then such a fractional iterate is called regular iterate of function \(~T~\) with number of iteration \(~r~\) at fixed point \(~L~\).

Specification of fractional iterate

In general, specifying non–integer iterate of some function \(~T~\), one should provide some additional information that provides the uniqueness. Such a condition can be indication of the fixed point \(~T~\), at which the iterate is regular.

An alternative could be specification of behavior at infinity, or specification of the superfunction \(F\) and the Abel function \(G=F^{-1}\), used to construct the fractional iterate \(T^r\) with

(2) \(~ ~ ~ R^r=F\big(r+G(z)\big)~\)

If the only one way of the construction of non-integer iterate is indicated, then the simple writing \(T^r\) is sufficient to indicate the \(r\)th iterate of function \(T\).

References

http://eretrandre.org/rb/files/Baker1962_53.pdf I.N.Baker. Permutable power series and regular iteration. Imperial College of Science and Technology, London (1960).

http://math.eretrandre.org/hyperops_wiki/index.php?title=Regular_iteration

Keywords

Iteration, Transfer function, Superfunction, Abel function