Difference between revisions of "Mdm of the Poisson distribution"
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{{ProbMacro}}{{Todo|Link with [[Poisson distribution]] page}} | {{ProbMacro}}{{Todo|Link with [[Poisson distribution]] page}} | ||
==Statement== | ==Statement== | ||
| − | Let {{M|X | + | Let {{M|X\sim}}[[Poisson distribution|{{M|\text{Poi} }}]]{{M|(\lambda)}} for some {{M|\lambda\in\mathbb{R}_{>0} }}. {{M|X}} may take any value in {{M|\mathbb{N}_0}} |
| + | |||
| + | |||
| + | We will show that | ||
| + | * {{MM|\text{Mdm}(X)\eq 2\lambda e^{-\lambda}\frac{\lambda^u}{u!} }}<ref>Alec's own work, I actually kept muddling it up on paper so this page IS the reference!</ref> | ||
| + | ** Where {{M|u:\eq}}[[Floor (function)|{{M|\text{Floor}(\lambda)}}]] | ||
| + | |||
| + | I have confirmed this [[experimental confirmation|experimentally]] in ''[[Experimental evidence for the Mdm of the Poisson distribution]]'' | ||
Recall the [[Mdm]] is defined as: | Recall the [[Mdm]] is defined as: | ||
* {{MM|\text{Mdm}(X):\eq\mathbb{E}\Big[\ \big\vert X-\mathbb{E}[X]\big\vert\ \Big]}} | * {{MM|\text{Mdm}(X):\eq\mathbb{E}\Big[\ \big\vert X-\mathbb{E}[X]\big\vert\ \Big]}} | ||
| − | + | <!-- | |
I kept messing up on paper, so I write the calculations here | I kept messing up on paper, so I write the calculations here | ||
| − | + | ||
| + | |||
| + | NON STANDARD MACROS DEFINED HERE | ||
| + | |||
| + | |||
| + | --> | ||
{{M|\newcommand{\LHS}[0]{ {\text{Mdm}(X)} } }} | {{M|\newcommand{\LHS}[0]{ {\text{Mdm}(X)} } }} | ||
==Calculation== | ==Calculation== | ||
| Line 17: | Line 29: | ||
**# if {{M|k\le \lambda\ \implies\ k-\lambda\le 0\ \implies \lambda-k\ge 0\ \implies \vert k-\lambda\vert \eq \lambda-k}} | **# if {{M|k\le \lambda\ \implies\ k-\lambda\le 0\ \implies \lambda-k\ge 0\ \implies \vert k-\lambda\vert \eq \lambda-k}} | ||
** Define the following two values: | ** Define the following two values: | ||
| − | **# {{M|u:\eq\text{RoundDownToInt}(\lambda)}}<ref group="Note">Recall {{M|\lambda>0}}, this means {{M|u\ge 0}} and thus {{M|u\in\mathbb{N}_0}}</ref> and | + | **# {{M|u:\eq\text{RoundDownToInt}(\lambda)}}<ref group="Note">Recall {{M|\lambda>0}}, this means {{M|u\ge 0}} and thus {{M|u\in\mathbb{N}_0}}</ref> (also known as the [[floor function]]<ref group="Note">Which is sometimes written: |
| + | * {{XXX|It's {{C|[n]}} but with the bottom or top notches removed from the square brackets?}}</ref> and | ||
**# {{M|v:\eq u+1}}<ref group="Note">Notice: | **# {{M|v:\eq u+1}}<ref group="Note">Notice: | ||
* If {{M|\lambda}} is not {{M|\in\mathbb{N}_{\ge 0} }} then {{M|u+1\eq\text{RoundUpToInt}(\lambda)}}, so {{M|u+1\eq v\ge \lambda}} | * If {{M|\lambda}} is not {{M|\in\mathbb{N}_{\ge 0} }} then {{M|u+1\eq\text{RoundUpToInt}(\lambda)}}, so {{M|u+1\eq v\ge \lambda}} | ||
| Line 45: | Line 58: | ||
**: {{MM|\eq e^{-\lambda}{\left[\lambda\ +\ \lambda{\left(\sum^u_{k\eq 1}\frac{\lambda^k}{k!}\ -\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!}\right)}\ +\ \lambda{\left( \sum^\infty_{k\eq v-1}\frac{\lambda^{k} }{k!}\ -\ \sum^{u-1}_{k\eq 0}\frac{\lambda^{k} }{k!}\right)}\right]} }} | **: {{MM|\eq e^{-\lambda}{\left[\lambda\ +\ \lambda{\left(\sum^u_{k\eq 1}\frac{\lambda^k}{k!}\ -\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!}\right)}\ +\ \lambda{\left( \sum^\infty_{k\eq v-1}\frac{\lambda^{k} }{k!}\ -\ \sum^{u-1}_{k\eq 0}\frac{\lambda^{k} }{k!}\right)}\right]} }} | ||
**: {{MM|\eq \lambda e^{-\lambda}{\left[1\ +\ {\left(\sum^u_{k\eq 1}\frac{\lambda^k}{k!}\ -\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!}\right)}\ +\ {\left( \sum^\infty_{k\eq v-1}\frac{\lambda^{k} }{k!}\ -\ \sum^{u-1}_{k\eq 0}\frac{\lambda^{k} }{k!}\right)}\right]} }} | **: {{MM|\eq \lambda e^{-\lambda}{\left[1\ +\ {\left(\sum^u_{k\eq 1}\frac{\lambda^k}{k!}\ -\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!}\right)}\ +\ {\left( \sum^\infty_{k\eq v-1}\frac{\lambda^{k} }{k!}\ -\ \sum^{u-1}_{k\eq 0}\frac{\lambda^{k} }{k!}\right)}\right]} }} | ||
| + | ** For convienence let us assign the sums letters: | ||
| + | *** {{MM|\eq \lambda e^{-\lambda}{\Bigg[1\ +\ \underbrace{\sum^u_{k\eq 1}\frac{\lambda^k}{k!} }_\text{A}\ -\ \underbrace{\sum^\infty_{k\eq v}\frac{\lambda^k}{k!} }_\text{B}\ +\ \underbrace{\sum^\infty_{k\eq v-1}\frac{\lambda^{k} }{k!} }_\text{C}\ -\ \underbrace{\sum^{u-1}_{k\eq 0}\frac{\lambda^{k} }{k!} }_\text{D} \Bigg]} }} | ||
| + | ** Now we combine the sums: | ||
| + | *** {{MM|\LHS{}\eq\lambda e^{-\lambda}{\Bigg[1+\underbrace{\sum^{u-1}_{k\eq 1}\frac{\lambda^k}{k!}+\frac{\lambda^u}{u!} }_\text{A}\ -\ \underbrace{\sum_{k\eq v}^\infty \frac{\lambda^k}{k!} }_\text{B}\ +\ \underbrace{ \frac{\lambda^{v-1} }{(v-1)!}\ +\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!} }_\text{C}\ -\ \underbrace{ \frac{\lambda^0}{0!}\ -\ \sum^{u-1}_{k\eq 1}\frac{\lambda^k}{k!} }_\text{D} \Bigg]} }} | ||
| + | ***: {{MM|\eq \lambda e^{-\lambda}{\Bigg[ 1\ -\ \frac{\lambda^0}{0!} \ +\ \frac{\lambda^u }{u!} \ +\ \frac{\lambda^{v-1} }{(v-1)!} \Bigg]} }} - as the sum above in {{Mtxt|A}} cancels with the sum part of {{Mtxt|D}}, and {{Mtxt|B}} cancels with the sum part of {{Mtxt|C}} | ||
| + | ***: {{MM|\eq \lambda e^{-\lambda}{\left[ 1-1+2\frac{\lambda^u}{u!} \right]} }} - using that {{M|v-1\eq u}} and tidying up | ||
| + | ***: {{MM|\eq 2\lambda e^{-\lambda}\frac{\lambda^u}{u!} }} | ||
| + | * '''Thus we see''' <span style="font-size:1.5em;">{{MM|\text{Mdm}(X)\eq 2\lambda e^{-\lambda}\frac{\lambda^u}{u!} }}</span> | ||
| − | |||
==Notes== | ==Notes== | ||
| − | |||
<references group="Note"/> | <references group="Note"/> | ||
| − | </ | + | ==References== |
| + | <references/> | ||
{{Theorem Of|Probability|Statistics|Elementary Probability}} | {{Theorem Of|Probability|Statistics|Elementary Probability}} | ||
Latest revision as of 00:27, 8 November 2017
[ilmath]\newcommand{\P}[2][]{\mathbb{P}#1{\left[{#2}\right]} } \newcommand{\Pcond}[3][]{\mathbb{P}#1{\left[{#2}\!\ \middle\vert\!\ {#3}\right]} } \newcommand{\Plcond}[3][]{\Pcond[#1]{#2}{#3} } \newcommand{\Prcond}[3][]{\Pcond[#1]{#2}{#3} }[/ilmath]
TODO: Link with Poisson distribution page
Contents
Statement
Let [ilmath]X\sim[/ilmath][ilmath]\text{Poi} [/ilmath][ilmath](\lambda)[/ilmath] for some [ilmath]\lambda\in\mathbb{R}_{>0} [/ilmath]. [ilmath]X[/ilmath] may take any value in [ilmath]\mathbb{N}_0[/ilmath]
We will show that
- [math]\text{Mdm}(X)\eq 2\lambda e^{-\lambda}\frac{\lambda^u}{u!} [/math][1]
- Where [ilmath]u:\eq[/ilmath][ilmath]\text{Floor}(\lambda)[/ilmath]
I have confirmed this experimentally in Experimental evidence for the Mdm of the Poisson distribution
Recall the Mdm is defined as:
- [math]\text{Mdm}(X):\eq\mathbb{E}\Big[\ \big\vert X-\mathbb{E}[X]\big\vert\ \Big][/math]
[ilmath]\newcommand{\LHS}[0]{ {\text{Mdm}(X)} } [/ilmath]
Calculation
- [math]\text{Mdm}(X):\eq\mathbb{E}\Big[\ \big\vert X-\mathbb{E}[X]\big\vert\ \Big][/math][math]:\eq\sum^\infty_{k\eq 0}\big\vert X-\mathbb{E}[X]\big\vert\cdot\P{X\eq k} [/math]
- [math]\eq e^{-\lambda}\ \sum^\infty_{k\eq 0}\frac{\lambda^k}{k!}\big\vert k-\mathbb{E}[X]\big\vert[/math] [math]\eq e^{-\lambda}\ \sum^\infty_{k\eq 0}\frac{\lambda^k}{k!}\big\vert k-\lambda\big\vert[/math]
- Note that:
- if [ilmath]k\ge \lambda\ \implies\ k-\lambda\ge 0\ \implies\ \vert k-\lambda\vert \eq k-\lambda[/ilmath]
- if [ilmath]k\le \lambda\ \implies\ k-\lambda\le 0\ \implies \lambda-k\ge 0\ \implies \vert k-\lambda\vert \eq \lambda-k[/ilmath]
- Define the following two values:
- [ilmath]u:\eq\text{RoundDownToInt}(\lambda)[/ilmath][Note 1] (also known as the floor function[Note 2] and
- [ilmath]v:\eq u+1[/ilmath][Note 3]
- This means we have [ilmath]u\le \lambda[/ilmath] and [ilmath]v\ge \lambda[/ilmath], specifically, we have the following two cases:
- if [ilmath]k\le u[/ilmath] and as [ilmath]u\le \lambda[/ilmath] we see [ilmath]k\le \lambda[/ilmath] and
- if [ilmath]k> u[/ilmath] then [ilmath]k \ge u+1\eq v \ge\lambda[/ilmath] so [ilmath]k\ge \lambda[/ilmath]
- Now, from above: [math]\LHS{}\eq e^{-\lambda}\ \sum^\infty_{k\eq 0}\frac{\lambda^k}{k!}\big\vert k-\lambda\big\vert[/math]
- [math]\eq e^{-\lambda}{\left[\frac{\lambda^0}{0!}\big\vert 0-\lambda\vert \ +\ \sum^\infty_{k\eq 1}\frac{\lambda^k}{k!}\big\vert k-\lambda\big\vert\right]} [/math]
- [math]\eq e^{-\lambda}{\left[\lambda\ +\ \sum^u_{k\eq 1}\frac{\lambda^k}{k!}\big\vert k-\lambda\big\vert\ +\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!}\big\vert k-\lambda\big\vert \right]} [/math] with the understanding that if [ilmath]u\eq 0[/ilmath] that the sum from [ilmath]k\eq 1[/ilmath] to [ilmath]u[/ilmath] evaluates to [ilmath]0[/ilmath], obviously
- Notice now that:
- For the first sum, where [ilmath]1\le k\le u[/ilmath] (specifically that [ilmath]k\le u[/ilmath]) we have [ilmath]k\le \lambda[/ilmath]
- and that from further above we noticed if [ilmath]k\le \lambda[/ilmath] then [ilmath]\big\vert k-\lambda\big\vert \eq \lambda-k[/ilmath]
- For the second sum, where [ilmath]k > u [/ilmath] that this meant [ilmath]k\ge \lambda[/ilmath]
- and that from further above we noticed if [ilmath]k\ge\lambda[/ilmath] then [ilmath]\big\vert k-\lambda\big\vert\eq k-\lambda[/ilmath], so
- For the first sum, where [ilmath]1\le k\le u[/ilmath] (specifically that [ilmath]k\le u[/ilmath]) we have [ilmath]k\le \lambda[/ilmath]
- [math]\LHS{}\eq e^{-\lambda}{\left[\lambda\ +\ \sum^u_{k\eq 1}\frac{\lambda^k}{k!}\big\vert k-\lambda\big\vert\ +\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!}\big\vert k-\lambda\big\vert \right]} [/math]
- [math]\eq e^{-\lambda}{\left[\lambda\ +\ \sum^u_{k\eq 1}\frac{\lambda^k}{k!}(\lambda-k)\ +\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!}( k-\lambda)\right]} [/math]
- we now expand these sums:
- [math]\eq e^{-\lambda}{\Bigg[\lambda\ +\ \overbrace{\sum^u_{k\eq 1}\frac{\lambda^{k+1} }{k!}\ -\ \sum^u_{k\eq 1}\frac{k\lambda^k}{k!} }^\text{first sum}\ +\ \overbrace{\sum^\infty_{k\eq v}\frac{k\lambda^k}{k!}-\sum^\infty_{k\eq v}\frac{\lambda^{k+1} }{k!} }^\text{second sum}\ \Bigg]} [/math]
- [math]\eq e^{-\lambda}{\left[\lambda\ +\ \lambda{\left(\sum^u_{k\eq 1}\frac{\lambda^k}{k!}\ -\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!}\right)}\ +\ {\left( \sum^\infty_{k\eq v}\frac{\lambda^k}{(k-1)!}\ -\ \sum^u_{k\eq 1}\frac{\lambda^k}{(k-1)!}\right)}\right]} [/math], by grouping the terms and factorising where we can
- [math]\eq e^{-\lambda}{\left[\lambda\ +\ \lambda{\left(\sum^u_{k\eq 1}\frac{\lambda^k}{k!}\ -\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!}\right)}\ +\ {\left( \sum^\infty_{k\eq v-1}\frac{\lambda^{k+1} }{k!}\ -\ \sum^{u-1}_{k\eq 0}\frac{\lambda^{k+1} }{k!}\right)}\right]} [/math][Note 4] by reindexing the latter two sums
- [math]\eq e^{-\lambda}{\left[\lambda\ +\ \lambda{\left(\sum^u_{k\eq 1}\frac{\lambda^k}{k!}\ -\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!}\right)}\ +\ \lambda{\left( \sum^\infty_{k\eq v-1}\frac{\lambda^{k} }{k!}\ -\ \sum^{u-1}_{k\eq 0}\frac{\lambda^{k} }{k!}\right)}\right]} [/math]
- [math]\eq \lambda e^{-\lambda}{\left[1\ +\ {\left(\sum^u_{k\eq 1}\frac{\lambda^k}{k!}\ -\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!}\right)}\ +\ {\left( \sum^\infty_{k\eq v-1}\frac{\lambda^{k} }{k!}\ -\ \sum^{u-1}_{k\eq 0}\frac{\lambda^{k} }{k!}\right)}\right]} [/math]
- [math]\eq e^{-\lambda}{\left[\lambda\ +\ \sum^u_{k\eq 1}\frac{\lambda^k}{k!}(\lambda-k)\ +\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!}( k-\lambda)\right]} [/math]
- For convienence let us assign the sums letters:
- [math]\eq \lambda e^{-\lambda}{\Bigg[1\ +\ \underbrace{\sum^u_{k\eq 1}\frac{\lambda^k}{k!} }_\text{A}\ -\ \underbrace{\sum^\infty_{k\eq v}\frac{\lambda^k}{k!} }_\text{B}\ +\ \underbrace{\sum^\infty_{k\eq v-1}\frac{\lambda^{k} }{k!} }_\text{C}\ -\ \underbrace{\sum^{u-1}_{k\eq 0}\frac{\lambda^{k} }{k!} }_\text{D} \Bigg]} [/math]
- Now we combine the sums:
- [math]\LHS{}\eq\lambda e^{-\lambda}{\Bigg[1+\underbrace{\sum^{u-1}_{k\eq 1}\frac{\lambda^k}{k!}+\frac{\lambda^u}{u!} }_\text{A}\ -\ \underbrace{\sum_{k\eq v}^\infty \frac{\lambda^k}{k!} }_\text{B}\ +\ \underbrace{ \frac{\lambda^{v-1} }{(v-1)!}\ +\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!} }_\text{C}\ -\ \underbrace{ \frac{\lambda^0}{0!}\ -\ \sum^{u-1}_{k\eq 1}\frac{\lambda^k}{k!} }_\text{D} \Bigg]} [/math]
- [math]\eq \lambda e^{-\lambda}{\Bigg[ 1\ -\ \frac{\lambda^0}{0!} \ +\ \frac{\lambda^u }{u!} \ +\ \frac{\lambda^{v-1} }{(v-1)!} \Bigg]} [/math] - as the sum above in [ilmath]\text{ A }[/ilmath] cancels with the sum part of [ilmath]\text{ D }[/ilmath], and [ilmath]\text{ B }[/ilmath] cancels with the sum part of [ilmath]\text{ C }[/ilmath]
- [math]\eq \lambda e^{-\lambda}{\left[ 1-1+2\frac{\lambda^u}{u!} \right]} [/math] - using that [ilmath]v-1\eq u[/ilmath] and tidying up
- [math]\eq 2\lambda e^{-\lambda}\frac{\lambda^u}{u!} [/math]
- [math]\LHS{}\eq\lambda e^{-\lambda}{\Bigg[1+\underbrace{\sum^{u-1}_{k\eq 1}\frac{\lambda^k}{k!}+\frac{\lambda^u}{u!} }_\text{A}\ -\ \underbrace{\sum_{k\eq v}^\infty \frac{\lambda^k}{k!} }_\text{B}\ +\ \underbrace{ \frac{\lambda^{v-1} }{(v-1)!}\ +\ \sum^\infty_{k\eq v}\frac{\lambda^k}{k!} }_\text{C}\ -\ \underbrace{ \frac{\lambda^0}{0!}\ -\ \sum^{u-1}_{k\eq 1}\frac{\lambda^k}{k!} }_\text{D} \Bigg]} [/math]
- Thus we see [math]\text{Mdm}(X)\eq 2\lambda e^{-\lambda}\frac{\lambda^u}{u!} [/math]
Notes
- ↑ Recall [ilmath]\lambda>0[/ilmath], this means [ilmath]u\ge 0[/ilmath] and thus [ilmath]u\in\mathbb{N}_0[/ilmath]
- ↑ Which is sometimes written:
- TODO: It's [n] but with the bottom or top notches removed from the square brackets?
-
- ↑ Notice:
- If [ilmath]\lambda[/ilmath] is not [ilmath]\in\mathbb{N}_{\ge 0} [/ilmath] then [ilmath]u+1\eq\text{RoundUpToInt}(\lambda)[/ilmath], so [ilmath]u+1\eq v\ge \lambda[/ilmath]
- If [ilmath]\lambda[/ilmath] is in [ilmath]\mathbb{N}_{\ge 0} [/ilmath] then [ilmath]u\eq\lambda[/ilmath] and [ilmath]v\eq u+1> u\eq \lambda[/ilmath] so [ilmath]v > \lambda[/ilmath]
- Notice [ilmath]\big(v > \lambda\big)\implies\big(v\ge \lambda\big)[/ilmath]
- ↑ Note that the third sum should have "[ilmath]\infty-1[/ilmath]" as its upper index, however remember that when a sum is to [ilmath]\infty[/ilmath] this is actually a limit, it was in this case:
- [math]\lim_{n\rightarrow\infty}\left(\sum^n_{k\eq v}\cdots\right)[/math]
- [math]\lim_{n\rightarrow\infty}\left(\sum^{n-1}_{k\eq v-1}\cdots\right)[/math]
References
- ↑ Alec's own work, I actually kept muddling it up on paper so this page IS the reference!
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