Timeline for Integral involving legendre (as Beukers integral) [duplicate]
Current License: CC BY-SA 4.0
8 events
| when toggle format | what | by | license | comment | |
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| May 14, 2019 at 11:27 | history | closed |
fedja Carlo Beenakker user44191 Yemon Choi LSpice |
Duplicate of Looking for bound in integral involving Legendre polynomial | |
| S May 13, 2019 at 7:19 | history | suggested | user64494 | CC BY-SA 4.0 |
The title is improved.
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| May 13, 2019 at 7:00 | review | Suggested edits | |||
| S May 13, 2019 at 7:19 | |||||
| May 13, 2019 at 4:56 | comment | added | fedja | Yes, the question is clear. It amounts to "I was shown that the decay is polynomial (Fedor Petrov gave you both the upper and the lower bound) but I don't like it, so, could someone, please find an exponential bound for me?". That is not how mathematics works. We are neither law, nor religion: another lawyer or priest won't tell you anything different. Fedor's answer was final. | |
| May 13, 2019 at 4:45 | review | Close votes | |||
| May 14, 2019 at 11:27 | |||||
| May 13, 2019 at 4:34 | comment | added | mamiladi | i'm sorry for mr Fedor Petrov, he doesn't gave the answer that i was expecting ( i thought that my old question was understable because i said as beukers integral), and upper bound or equivalent to beukers integral are given by $c^n$ and not $O(1/n^2)$), so i'm looking another answer and this time i think that the question is clear.. | |
| May 13, 2019 at 4:23 | comment | added | fedja | Hasn't Fedor Petrov convinced you that the decay is merely polynomial? Or are you just ignoring the answers unless they confirm your conjectures? Voting to close. | |
| May 13, 2019 at 2:48 | history | asked | mamiladi | CC BY-SA 4.0 |