Timeline for Binomial series
Current License: CC BY-SA 4.0
14 events
| when toggle format | what | by | license | comment | |
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| Jan 11 at 12:18 | vote | accept | Morteza | ||
| Jan 11 at 5:33 | answer | added | Claude Leibovici | timeline score: 1 | |
| Jan 10 at 23:07 | history | became hot network question | |||
| Jan 10 at 21:08 | answer | added | Pietro Majer | timeline score: 4 | |
| Jan 10 at 21:06 | answer | added | Giorgio Metafune | timeline score: 3 | |
| S Jan 10 at 19:41 | history | suggested | J. W. Tanner |
Added reference-request tag
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| Jan 10 at 17:19 | review | Suggested edits | |||
| S Jan 10 at 19:41 | |||||
| Jan 10 at 16:00 | answer | added | Iosif Pinelis | timeline score: 10 | |
| Jan 10 at 15:41 | comment | added | LSpice |
TeX note: please use \sum, not \Sigma, for sums. Compare, for example, $\displaystyle\sum_{k = 0}^n \sqrt k\binom n k$ \displaystyle\sum_{k = 0}^n \sqrt k\binom n k to $\displaystyle\Sigma_{k = 0}^n \sqrt k\binom n k$ \displaystyle\Sigma_{k = 0}^n \sqrt k\binom n k. I edited accordingly.
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| Jan 10 at 15:40 | history | edited | LSpice | CC BY-SA 4.0 |
Capitalise title; `\Sigma` -> `\sum`
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| Jan 10 at 15:34 | answer | added | Carlo Beenakker | timeline score: 5 | |
| Jan 10 at 15:34 | comment | added | Aleksei Kulikov | Almost all of the mass of the sum is concentrated at $k$ near $\frac{n}{2}$, so the limit is $\frac{1}{\sqrt{2}}$. But this question is better suited for Mathematics Stack Exchange and not MathOverflow. | |
| Jan 10 at 15:28 | comment | added | Jukka Kohonen | A similar sum (but with alternating signs) was considered in this Math.SE question. | |
| Jan 10 at 15:07 | history | asked | Morteza | CC BY-SA 4.0 |