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cumulative_distribution_function [2015/04/09 16:14] nikolaj |
cumulative_distribution_function [2015/04/09 16:16] nikolaj |
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| >So we can use such $S$ to normalize functions. | >So we can use such $S$ to normalize functions. | ||
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| - | >Any linear function of evaluated points are examples for $S$. | + | >For ${\mathbb D}={\mathbb N}$ the general case is $Sf:=\sum_{n=0}^\infty (L_nf)(n)$, where $(L_n)$ is a suitable sequence of linear operations (e.g. differential operators). For $L_n={\mathrm{id}}$ we get the standard sum (see below). |
| - | >So for ${\mathbb D}={\mathbb N}$ the general case is $Sf:=\sum_{n=0}^\infty (L_nf)(n)$, where $(L_n)$ is a suitable sequence of linear operations (e.g. differential operators). | + | |
| >For ${\mathbb D}\subseteq{\mathbb R}^m$ we have integrals. | >For ${\mathbb D}\subseteq{\mathbb R}^m$ we have integrals. | ||
| > | > | ||
