Difference between revisions of "File:ShellThronRegionPaulsen2.png"
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| + | [[Shell-Thron region]] in the complex plane (inside the loop). |
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| + | Figure 1 from publication by [[William Harold Paulsen]], 2019 |
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| + | <ref> |
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| + | https://www.researchgate.net/publication/325532999_Tetration_for_complex_bases <br> |
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| + | https://link.springer.com/article/10.1007/s10444-018-9615-7 |
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| + | [[William Harold Paulsen]]. Tetration for complex bases. |
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| + | Advances in Computational Mathematics, volume 45, pages 243–267(2019) |
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| + | Abstract |
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| + | In this paper we will consider the tetration, defined by the equation \( F(z+1)= b^F(z)\) in the complex plane with \( F(0)=1\), for the case where \(b\) is complex. A previous paper determined conditions for a unique solution the case where \( b \) is real and \(b>e^{1/e}\). |
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| + | In this paper we extend these results to find conditions which determine a unique solution for complex bases. We also develop iteration methods for numerically approximating the function F(z), both for bases inside and outside the Shell-Thron region. .. |
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| + | We say that the base \(b\) is in the [[Shell-Thron region]] if the sequence of values |
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| + | \( \{ b, b^b, b^{b^b}, b^{b^{b^b}}, ... \}\) converge to a finite [[fixed point]]. |
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| + | .. |
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| + | </ref>: |
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| + | |||
| + | We say that the base \(b\) is in the [[Shell-Thron region]] if the sequence of values |
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| + | |||
| + | \( \{ b, b^b, b^{b^b}, b^{b^{b^b}}, ... \}\) |
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| + | |||
| + | converge to a finite [[fixed point]]. |
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| + | |||
| + | ==References== |
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| + | <references/> |
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| + | |||
| + | [[Category:Exp]] |
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| + | [[Category:Iterate]] |
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| + | [[Category:Shell-Thron region]] |
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| + | [[Category:Tetration]] |
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| + | [[Category:William Paulsen]] |
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Latest revision as of 06:51, 13 July 2020
Shell-Thron region in the complex plane (inside the loop).
Figure 1 from publication by William Harold Paulsen, 2019 [1]:
We say that the base \(b\) is in the Shell-Thron region if the sequence of values
\( \{ b, b^b, b^{b^b}, b^{b^{b^b}}, ... \}\)
converge to a finite fixed point.
References
- ↑
https://www.researchgate.net/publication/325532999_Tetration_for_complex_bases
https://link.springer.com/article/10.1007/s10444-018-9615-7 William Harold Paulsen. Tetration for complex bases. Advances in Computational Mathematics, volume 45, pages 243–267(2019) Abstract In this paper we will consider the tetration, defined by the equation \( F(z+1)= b^F(z)\) in the complex plane with \( F(0)=1\), for the case where \(b\) is complex. A previous paper determined conditions for a unique solution the case where \( b \) is real and \(b>e^{1/e}\). In this paper we extend these results to find conditions which determine a unique solution for complex bases. We also develop iteration methods for numerically approximating the function F(z), both for bases inside and outside the Shell-Thron region. .. We say that the base \(b\) is in the Shell-Thron region if the sequence of values \( \{ b, b^b, b^{b^b}, b^{b^{b^b}}, ... \}\) converge to a finite fixed point. ..
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