Transformation of random variables and joint distributions

Given a variable $y_i$, normally distributed with 0 mean and $σ_y$ standard deviation

$y_i$ ~ NormalDistribution[0,$σ_y$ ]

I want to obtain with Mathematica:

The distribution of:
$x = bar{y} = frac {sum_{i=1}^ny_i}{n}$

The joint distribution of $ (x,y_i )$

Thank you for your helpful comments

edited 4 hours ago

mjw

9779

asked 8 hours ago

Andrea2810

162

New contributor

4

$begingroup$
What have you tried? For example, have you seen the documentation on TransformedDistribution and ProbabilityDistribution?
$endgroup$
– JimB
8 hours ago

$begingroup$
@JimB . I tried this TransformedDistribution[Sum[y, {i, n}]/n, y [Distributed] NormalDistribution[0, [Sigma]y]]. The result is NormalDistribution[0, [Sigma]y]. However, the correct result should be NormalDistribution[0, [Sigma]y / Sqrt[n]]
$endgroup$
– Andrea2810
8 hours ago

$begingroup$
You need to "index" the variable y or else Mathematica thinks it is a single variable.
$endgroup$
– JimB
3 hours ago

add a comment |

Given a variable $y_i$, normally distributed with 0 mean and $σ_y$ standard deviation

$y_i$ ~ NormalDistribution[0,$σ_y$ ]

I want to obtain with Mathematica:

The distribution of:
$x = bar{y} = frac {sum_{i=1}^ny_i}{n}$

The joint distribution of $ (x,y_i )$

Thank you for your helpful comments

edited 4 hours ago

mjw

9779

asked 8 hours ago

Andrea2810

162

New contributor

4

$begingroup$
What have you tried? For example, have you seen the documentation on TransformedDistribution and ProbabilityDistribution?
$endgroup$
– JimB
8 hours ago

$begingroup$
@JimB . I tried this TransformedDistribution[Sum[y, {i, n}]/n, y [Distributed] NormalDistribution[0, [Sigma]y]]. The result is NormalDistribution[0, [Sigma]y]. However, the correct result should be NormalDistribution[0, [Sigma]y / Sqrt[n]]
$endgroup$
– Andrea2810
8 hours ago

$begingroup$
You need to "index" the variable y or else Mathematica thinks it is a single variable.
$endgroup$
– JimB
3 hours ago

add a comment |

Given a variable $y_i$, normally distributed with 0 mean and $σ_y$ standard deviation

$y_i$ ~ NormalDistribution[0,$σ_y$ ]

I want to obtain with Mathematica:

The distribution of:
$x = bar{y} = frac {sum_{i=1}^ny_i}{n}$

The joint distribution of $ (x,y_i )$

Thank you for your helpful comments

edited 4 hours ago

mjw

9779

asked 8 hours ago

Andrea2810

162

New contributor

Given a variable $y_i$, normally distributed with 0 mean and $σ_y$ standard deviation

$y_i$ ~ NormalDistribution[0,$σ_y$ ]

I want to obtain with Mathematica:

The distribution of:
$x = bar{y} = frac {sum_{i=1}^ny_i}{n}$

The joint distribution of $ (x,y_i )$

Thank you for your helpful comments

probability-or-statistics

edited 4 hours ago

mjw

9779

asked 8 hours ago

Andrea2810

162

New contributor

edited 4 hours ago

mjw

9779

asked 8 hours ago

Andrea2810

162

New contributor

edited 4 hours ago

mjw

9779

edited 4 hours ago

mjw

9779

edited 4 hours ago

mjw

9779

asked 8 hours ago

Andrea2810

162

New contributor

asked 8 hours ago

Andrea2810

162

asked 8 hours ago

Andrea2810

162

New contributor

Andrea2810 is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
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4

$begingroup$
What have you tried? For example, have you seen the documentation on TransformedDistribution and ProbabilityDistribution?
$endgroup$
– JimB
8 hours ago

$begingroup$
@JimB . I tried this TransformedDistribution[Sum[y, {i, n}]/n, y [Distributed] NormalDistribution[0, [Sigma]y]]. The result is NormalDistribution[0, [Sigma]y]. However, the correct result should be NormalDistribution[0, [Sigma]y / Sqrt[n]]
$endgroup$
– Andrea2810
8 hours ago

$begingroup$
You need to "index" the variable y or else Mathematica thinks it is a single variable.
$endgroup$
– JimB
3 hours ago

add a comment |

4

$begingroup$
What have you tried? For example, have you seen the documentation on TransformedDistribution and ProbabilityDistribution?
$endgroup$
– JimB
8 hours ago

$begingroup$
@JimB . I tried this TransformedDistribution[Sum[y, {i, n}]/n, y [Distributed] NormalDistribution[0, [Sigma]y]]. The result is NormalDistribution[0, [Sigma]y]. However, the correct result should be NormalDistribution[0, [Sigma]y / Sqrt[n]]
$endgroup$
– Andrea2810
8 hours ago

$begingroup$
You need to "index" the variable y or else Mathematica thinks it is a single variable.
$endgroup$
– JimB
3 hours ago

What have you tried? For example, have you seen the documentation on TransformedDistribution and ProbabilityDistribution?

– JimB
8 hours ago

@JimB . I tried this TransformedDistribution[Sum[y, {i, n}]/n, y [Distributed] NormalDistribution[0, [Sigma]y]]. The result is NormalDistribution[0, [Sigma]y]. However, the correct result should be NormalDistribution[0, [Sigma]y / Sqrt[n]]

– Andrea2810
8 hours ago

You need to "index" the variable y or else Mathematica thinks it is a single variable.

– JimB
3 hours ago

add a comment |

3 Answers
3

active

oldest

votes

I don't know how to get Mathematica to get the joint distribution explicitly for a general value of $n$ but here is how one can easily see the pattern to figure out the general solution.

First the distribution of the mean:

marginalDistribution = TransformedDistribution[Sum[y[i], {i, n}]/n, 

  Table[y[i] [Distributed] NormalDistribution[0, [Sigma]], {i, n}], 

  Assumptions -> [Sigma] > 0]

{#, marginalDistribution/.n->#} &/@Range[2,10]

$$
begin{array}{cc}
2 & text{NormalDistribution}left[0,frac{sigma }{sqrt{2}}right] \
3 & text{NormalDistribution}left[0,frac{sigma }{sqrt{3}}right] \
4 & text{NormalDistribution}left[0,frac{sigma }{2}right] \
5 & text{NormalDistribution}left[0,frac{sigma }{sqrt{5}}right] \
6 & text{NormalDistribution}left[0,frac{sigma }{sqrt{6}}right] \
7 & text{NormalDistribution}left[0,frac{sigma }{sqrt{7}}right] \
8 & text{NormalDistribution}left[0,frac{sigma }{2 sqrt{2}}right] \
9 & text{NormalDistribution}left[0,frac{sigma }{3}right] \
10 & text{NormalDistribution}left[0,frac{sigma }{sqrt{10}}right] \
end{array}
$$

So we see that the marginal distribution of $bar{y}$ is

NormalDistribution[0, σ/Sqrt[n]]

The joint distribution of $bar{y}$ and, say, $y_1$ is given by

jointDistribution = TransformedDistribution[{y[1], Sum[y[i], {i, n}]/n}, 

  Table[y[i] [Distributed] NormalDistribution[0, [Sigma]], {i, n}]]

{#, jointDistribution /. n -> #} & /@ Range[2, 10] // TableForm

$$
begin{array}{cc}
2 & text{MultinormalDistribution}left[{0,0},left(
begin{array}{cc}
sigma ^2 & frac{sigma ^2}{2} \
frac{sigma ^2}{2} & frac{sigma ^2}{2} \
end{array}
right)right] \
3 & text{MultinormalDistribution}left[{0,0},left(
begin{array}{cc}
sigma ^2 & frac{sigma ^2}{3} \
frac{sigma ^2}{3} & frac{sigma ^2}{3} \
end{array}
right)right] \
4 & text{MultinormalDistribution}left[{0,0},left(
begin{array}{cc}
sigma ^2 & frac{sigma ^2}{4} \
frac{sigma ^2}{4} & frac{sigma ^2}{4} \
end{array}
right)right] \
5 & text{MultinormalDistribution}left[{0,0},left(
begin{array}{cc}
sigma ^2 & frac{sigma ^2}{5} \
frac{sigma ^2}{5} & frac{sigma ^2}{5} \
end{array}
right)right] \
6 & text{MultinormalDistribution}left[{0,0},left(
begin{array}{cc}
sigma ^2 & frac{sigma ^2}{6} \
frac{sigma ^2}{6} & frac{sigma ^2}{6} \
end{array}
right)right] \
7 & text{MultinormalDistribution}left[{0,0},left(
begin{array}{cc}
sigma ^2 & frac{sigma ^2}{7} \
frac{sigma ^2}{7} & frac{sigma ^2}{7} \
end{array}
right)right] \
8 & text{MultinormalDistribution}left[{0,0},left(
begin{array}{cc}
sigma ^2 & frac{sigma ^2}{8} \
frac{sigma ^2}{8} & frac{sigma ^2}{8} \
end{array}
right)right] \
9 & text{MultinormalDistribution}left[{0,0},left(
begin{array}{cc}
sigma ^2 & frac{sigma ^2}{9} \
frac{sigma ^2}{9} & frac{sigma ^2}{9} \
end{array}
right)right] \
10 & text{MultinormalDistribution}left[{0,0},left(
begin{array}{cc}
sigma ^2 & frac{sigma ^2}{10} \
frac{sigma ^2}{10} & frac{sigma ^2}{10} \
end{array}
right)right] \
end{array}
$$

So the general distribution is a multivariate normal

MultinormalDistribution[{0, 0}, {{σ^2, σ^2/n}, {σ^2/n, σ^2/n}}]

The general form of the joint density function can then be found with

FullSimplify[PDF[MultinormalDistribution[{0, 0}, {{σ^2, σ^2/n}, {σ^2/n, σ^2/n}}], {y, ybar}],

  Assumptions -> {σ > 0, n > 1}]

$$frac{n e^{-frac{n left(n text{ybar}^2+y^2-2 y text{ybar}right)}{2 (n-1) sigma ^2}}}{2 pi sqrt{n-1} sigma ^2}$$

edited 3 hours ago

answered 3 hours ago

JimB

18k12863

$begingroup$
Anyway, I like your answer! I'll have to look at it to understand (not obvious (to me) that this would be the solution).
$endgroup$
– mjw
3 hours ago

$begingroup$
@mjw Good. Answers should always be scrutinized and challenged if desired.
$endgroup$
– JimB
3 hours ago

$begingroup$
Nice! In addition to trying to understand the technique, I checked the marginal integrals. Looks great!
$endgroup$
– mjw
29 mins ago

add a comment |

just modified @mjw's answer,

n = 100;(*for example*)ClearAll[y]; 

a = Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}];

meanDist = TransformedDistribution[Sum[y[k]/100, {k, 100}], a]

JointDistribution can be composed by ProductDistribution,
if these random variables are independent.

if not,you have to use Copula

joint = ProductDistribution[meanDist, 

    Last@*List @@ Part[a, 1]] /. [Sigma] -> 1;

RandomVariate[joint, 100] // Histogram3D

enter image description here

joint = ProductDistribution[meanDist, 

    Last@*List @@ Part[a, 1]] /. [Sigma] -> 1;

m1 = RandomVariate[meanDist /. [Sigma] -> 1, {100000}];

m2 = RandomVariate[

   Last@*List @@ Part[a, 1] /. [Sigma] -> 1, {100000}];

Correlation[Thread[List[m1, m2]]]

ListPlot[Thread[List[m1, m2]]]

{{1., -0.00256777}, {-0.00256777, 1.}}

enter image description here

I'm not sure about correlation,but it's okay.

edited 3 hours ago

answered 5 hours ago

Xminer

30918

$begingroup$
I believe that the distributions are not independent. Since $overline{x}$ is computed from $y_i$ and other $y_j$'s, it would seem to be dependent. We could compute whether or not the distributions are dependent ...
$endgroup$
– mjw
4 hours ago

$begingroup$
I would also recommend using 10^6 rather than 100, you'll get a sharper plot!
$endgroup$
– mjw
4 hours ago

$begingroup$
Exactly, the two variables are not independent unfortunately
$endgroup$
– Andrea2810
4 hours ago

add a comment |

Here is the distribution of $x=overline{y}$ (Part I of your question):

a[n_] := Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}]; 

p[n_] := TransformedDistribution[Sum[y[k]/n, {k, n}], a[n]];

Now

x [Distributed] p[5] (* n=5, for example *)

The result is

x [Distributed] NormalDistribution[0, Abs[[Sigma]]/Sqrt[5]]

edited 28 mins ago

answered 5 hours ago

mjw

9779

$begingroup$
I am not sure, but shouldn't be n instead of 5 here TransformedDistribution[Sum[y[k]/n, {k, 5}], a] ? And what if I want to leave n, without assigning a value to n? Thanks @mjw
$endgroup$
– Andrea2810
4 hours ago

$begingroup$
Oh yes, you are right! I started with 10 and changed to five as I was trying it out. I'll fix it ... Thanks!
$endgroup$
– mjw
4 hours ago

$begingroup$
Let's go with five because it is clearer. The result is NormalDistribution[0,[Sigma]/Sqrt[5]]. Not sure why Mathematica puts Abs around $sigma$. Obviously, $sigma>0$.
$endgroup$
– mjw
4 hours ago

$begingroup$
Yes, sure it is clearer. Do you have any idea of how can I use n as a parameter, without assigning a value to n?
$endgroup$
– Andrea2810
4 hours ago

$begingroup$
a[n_] = Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}];
$endgroup$
– mjw
4 hours ago

|
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3 Answers
3

active

oldest

votes

3 Answers
3

active

oldest

votes

I don't know how to get Mathematica to get the joint distribution explicitly for a general value of $n$ but here is how one can easily see the pattern to figure out the general solution.

First the distribution of the mean:

marginalDistribution = TransformedDistribution[Sum[y[i], {i, n}]/n, 

  Table[y[i] [Distributed] NormalDistribution[0, [Sigma]], {i, n}], 

  Assumptions -> [Sigma] > 0]

{#, marginalDistribution/.n->#} &/@Range[2,10]

So we see that the marginal distribution of $bar{y}$ is

NormalDistribution[0, σ/Sqrt[n]]

The joint distribution of $bar{y}$ and, say, $y_1$ is given by

jointDistribution = TransformedDistribution[{y[1], Sum[y[i], {i, n}]/n}, 

  Table[y[i] [Distributed] NormalDistribution[0, [Sigma]], {i, n}]]

{#, jointDistribution /. n -> #} & /@ Range[2, 10] // TableForm

So the general distribution is a multivariate normal

MultinormalDistribution[{0, 0}, {{σ^2, σ^2/n}, {σ^2/n, σ^2/n}}]

The general form of the joint density function can then be found with

FullSimplify[PDF[MultinormalDistribution[{0, 0}, {{σ^2, σ^2/n}, {σ^2/n, σ^2/n}}], {y, ybar}],

  Assumptions -> {σ > 0, n > 1}]

$$frac{n e^{-frac{n left(n text{ybar}^2+y^2-2 y text{ybar}right)}{2 (n-1) sigma ^2}}}{2 pi sqrt{n-1} sigma ^2}$$

edited 3 hours ago

answered 3 hours ago

JimB

18k12863

$begingroup$
Anyway, I like your answer! I'll have to look at it to understand (not obvious (to me) that this would be the solution).
$endgroup$
– mjw
3 hours ago

$begingroup$
@mjw Good. Answers should always be scrutinized and challenged if desired.
$endgroup$
– JimB
3 hours ago

$begingroup$
Nice! In addition to trying to understand the technique, I checked the marginal integrals. Looks great!
$endgroup$
– mjw
29 mins ago

add a comment |

I don't know how to get Mathematica to get the joint distribution explicitly for a general value of $n$ but here is how one can easily see the pattern to figure out the general solution.

First the distribution of the mean:

marginalDistribution = TransformedDistribution[Sum[y[i], {i, n}]/n, 

  Table[y[i] [Distributed] NormalDistribution[0, [Sigma]], {i, n}], 

  Assumptions -> [Sigma] > 0]

{#, marginalDistribution/.n->#} &/@Range[2,10]

So we see that the marginal distribution of $bar{y}$ is

NormalDistribution[0, σ/Sqrt[n]]

The joint distribution of $bar{y}$ and, say, $y_1$ is given by

jointDistribution = TransformedDistribution[{y[1], Sum[y[i], {i, n}]/n}, 

  Table[y[i] [Distributed] NormalDistribution[0, [Sigma]], {i, n}]]

{#, jointDistribution /. n -> #} & /@ Range[2, 10] // TableForm

So the general distribution is a multivariate normal

MultinormalDistribution[{0, 0}, {{σ^2, σ^2/n}, {σ^2/n, σ^2/n}}]

The general form of the joint density function can then be found with

FullSimplify[PDF[MultinormalDistribution[{0, 0}, {{σ^2, σ^2/n}, {σ^2/n, σ^2/n}}], {y, ybar}],

  Assumptions -> {σ > 0, n > 1}]

$$frac{n e^{-frac{n left(n text{ybar}^2+y^2-2 y text{ybar}right)}{2 (n-1) sigma ^2}}}{2 pi sqrt{n-1} sigma ^2}$$

edited 3 hours ago

answered 3 hours ago

JimB

18k12863

$begingroup$
Anyway, I like your answer! I'll have to look at it to understand (not obvious (to me) that this would be the solution).
$endgroup$
– mjw
3 hours ago

$begingroup$
@mjw Good. Answers should always be scrutinized and challenged if desired.
$endgroup$
– JimB
3 hours ago

$begingroup$
Nice! In addition to trying to understand the technique, I checked the marginal integrals. Looks great!
$endgroup$
– mjw
29 mins ago

add a comment |

I don't know how to get Mathematica to get the joint distribution explicitly for a general value of $n$ but here is how one can easily see the pattern to figure out the general solution.

First the distribution of the mean:

marginalDistribution = TransformedDistribution[Sum[y[i], {i, n}]/n, 

  Table[y[i] [Distributed] NormalDistribution[0, [Sigma]], {i, n}], 

  Assumptions -> [Sigma] > 0]

{#, marginalDistribution/.n->#} &/@Range[2,10]

So we see that the marginal distribution of $bar{y}$ is

NormalDistribution[0, σ/Sqrt[n]]

The joint distribution of $bar{y}$ and, say, $y_1$ is given by

jointDistribution = TransformedDistribution[{y[1], Sum[y[i], {i, n}]/n}, 

  Table[y[i] [Distributed] NormalDistribution[0, [Sigma]], {i, n}]]

{#, jointDistribution /. n -> #} & /@ Range[2, 10] // TableForm

So the general distribution is a multivariate normal

MultinormalDistribution[{0, 0}, {{σ^2, σ^2/n}, {σ^2/n, σ^2/n}}]

The general form of the joint density function can then be found with

FullSimplify[PDF[MultinormalDistribution[{0, 0}, {{σ^2, σ^2/n}, {σ^2/n, σ^2/n}}], {y, ybar}],

  Assumptions -> {σ > 0, n > 1}]

$$frac{n e^{-frac{n left(n text{ybar}^2+y^2-2 y text{ybar}right)}{2 (n-1) sigma ^2}}}{2 pi sqrt{n-1} sigma ^2}$$

edited 3 hours ago

answered 3 hours ago

JimB

18k12863

I don't know how to get Mathematica to get the joint distribution explicitly for a general value of $n$ but here is how one can easily see the pattern to figure out the general solution.

First the distribution of the mean:

marginalDistribution = TransformedDistribution[Sum[y[i], {i, n}]/n, 

  Table[y[i] [Distributed] NormalDistribution[0, [Sigma]], {i, n}], 

  Assumptions -> [Sigma] > 0]

{#, marginalDistribution/.n->#} &/@Range[2,10]

So we see that the marginal distribution of $bar{y}$ is

NormalDistribution[0, σ/Sqrt[n]]

The joint distribution of $bar{y}$ and, say, $y_1$ is given by

jointDistribution = TransformedDistribution[{y[1], Sum[y[i], {i, n}]/n}, 

  Table[y[i] [Distributed] NormalDistribution[0, [Sigma]], {i, n}]]

{#, jointDistribution /. n -> #} & /@ Range[2, 10] // TableForm

So the general distribution is a multivariate normal

MultinormalDistribution[{0, 0}, {{σ^2, σ^2/n}, {σ^2/n, σ^2/n}}]

The general form of the joint density function can then be found with

FullSimplify[PDF[MultinormalDistribution[{0, 0}, {{σ^2, σ^2/n}, {σ^2/n, σ^2/n}}], {y, ybar}],

  Assumptions -> {σ > 0, n > 1}]

$$frac{n e^{-frac{n left(n text{ybar}^2+y^2-2 y text{ybar}right)}{2 (n-1) sigma ^2}}}{2 pi sqrt{n-1} sigma ^2}$$

edited 3 hours ago

answered 3 hours ago

JimB

18k12863

edited 3 hours ago

answered 3 hours ago

JimB

18k12863

answered 3 hours ago

JimB

18k12863

answered 3 hours ago

JimB

18k12863

$begingroup$
Anyway, I like your answer! I'll have to look at it to understand (not obvious (to me) that this would be the solution).
$endgroup$
– mjw
3 hours ago

$begingroup$
@mjw Good. Answers should always be scrutinized and challenged if desired.
$endgroup$
– JimB
3 hours ago

$begingroup$
Nice! In addition to trying to understand the technique, I checked the marginal integrals. Looks great!
$endgroup$
– mjw
29 mins ago

add a comment |

$begingroup$
Anyway, I like your answer! I'll have to look at it to understand (not obvious (to me) that this would be the solution).
$endgroup$
– mjw
3 hours ago

$begingroup$
@mjw Good. Answers should always be scrutinized and challenged if desired.
$endgroup$
– JimB
3 hours ago

$begingroup$
Nice! In addition to trying to understand the technique, I checked the marginal integrals. Looks great!
$endgroup$
– mjw
29 mins ago

Anyway, I like your answer! I'll have to look at it to understand (not obvious (to me) that this would be the solution).

– mjw
3 hours ago

@mjw Good. Answers should always be scrutinized and challenged if desired.

– JimB
3 hours ago

Nice! In addition to trying to understand the technique, I checked the marginal integrals. Looks great!

– mjw
29 mins ago

add a comment |

just modified @mjw's answer,

n = 100;(*for example*)ClearAll[y]; 

a = Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}];

meanDist = TransformedDistribution[Sum[y[k]/100, {k, 100}], a]

JointDistribution can be composed by ProductDistribution,
if these random variables are independent.

if not,you have to use Copula

joint = ProductDistribution[meanDist, 

    Last@*List @@ Part[a, 1]] /. [Sigma] -> 1;

RandomVariate[joint, 100] // Histogram3D

enter image description here

joint = ProductDistribution[meanDist, 

    Last@*List @@ Part[a, 1]] /. [Sigma] -> 1;

m1 = RandomVariate[meanDist /. [Sigma] -> 1, {100000}];

m2 = RandomVariate[

   Last@*List @@ Part[a, 1] /. [Sigma] -> 1, {100000}];

Correlation[Thread[List[m1, m2]]]

ListPlot[Thread[List[m1, m2]]]

{{1., -0.00256777}, {-0.00256777, 1.}}

enter image description here

I'm not sure about correlation,but it's okay.

edited 3 hours ago

answered 5 hours ago

Xminer

30918

$begingroup$
I believe that the distributions are not independent. Since $overline{x}$ is computed from $y_i$ and other $y_j$'s, it would seem to be dependent. We could compute whether or not the distributions are dependent ...
$endgroup$
– mjw
4 hours ago

$begingroup$
I would also recommend using 10^6 rather than 100, you'll get a sharper plot!
$endgroup$
– mjw
4 hours ago

$begingroup$
Exactly, the two variables are not independent unfortunately
$endgroup$
– Andrea2810
4 hours ago

add a comment |

just modified @mjw's answer,

n = 100;(*for example*)ClearAll[y]; 

a = Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}];

meanDist = TransformedDistribution[Sum[y[k]/100, {k, 100}], a]

JointDistribution can be composed by ProductDistribution,
if these random variables are independent.

if not,you have to use Copula

joint = ProductDistribution[meanDist, 

    Last@*List @@ Part[a, 1]] /. [Sigma] -> 1;

RandomVariate[joint, 100] // Histogram3D

enter image description here

joint = ProductDistribution[meanDist, 

    Last@*List @@ Part[a, 1]] /. [Sigma] -> 1;

m1 = RandomVariate[meanDist /. [Sigma] -> 1, {100000}];

m2 = RandomVariate[

   Last@*List @@ Part[a, 1] /. [Sigma] -> 1, {100000}];

Correlation[Thread[List[m1, m2]]]

ListPlot[Thread[List[m1, m2]]]

{{1., -0.00256777}, {-0.00256777, 1.}}

enter image description here

I'm not sure about correlation,but it's okay.

edited 3 hours ago

answered 5 hours ago

Xminer

30918

$begingroup$
I believe that the distributions are not independent. Since $overline{x}$ is computed from $y_i$ and other $y_j$'s, it would seem to be dependent. We could compute whether or not the distributions are dependent ...
$endgroup$
– mjw
4 hours ago

$begingroup$
I would also recommend using 10^6 rather than 100, you'll get a sharper plot!
$endgroup$
– mjw
4 hours ago

$begingroup$
Exactly, the two variables are not independent unfortunately
$endgroup$
– Andrea2810
4 hours ago

add a comment |

just modified @mjw's answer,

n = 100;(*for example*)ClearAll[y]; 

a = Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}];

meanDist = TransformedDistribution[Sum[y[k]/100, {k, 100}], a]

JointDistribution can be composed by ProductDistribution,
if these random variables are independent.

if not,you have to use Copula

joint = ProductDistribution[meanDist, 

    Last@*List @@ Part[a, 1]] /. [Sigma] -> 1;

RandomVariate[joint, 100] // Histogram3D

enter image description here

joint = ProductDistribution[meanDist, 

    Last@*List @@ Part[a, 1]] /. [Sigma] -> 1;

m1 = RandomVariate[meanDist /. [Sigma] -> 1, {100000}];

m2 = RandomVariate[

   Last@*List @@ Part[a, 1] /. [Sigma] -> 1, {100000}];

Correlation[Thread[List[m1, m2]]]

ListPlot[Thread[List[m1, m2]]]

{{1., -0.00256777}, {-0.00256777, 1.}}

enter image description here

I'm not sure about correlation,but it's okay.

edited 3 hours ago

answered 5 hours ago

Xminer

30918

just modified @mjw's answer,

n = 100;(*for example*)ClearAll[y]; 

a = Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}];

meanDist = TransformedDistribution[Sum[y[k]/100, {k, 100}], a]

JointDistribution can be composed by ProductDistribution,
if these random variables are independent.

if not,you have to use Copula

joint = ProductDistribution[meanDist, 

    Last@*List @@ Part[a, 1]] /. [Sigma] -> 1;

RandomVariate[joint, 100] // Histogram3D

enter image description here

joint = ProductDistribution[meanDist, 

    Last@*List @@ Part[a, 1]] /. [Sigma] -> 1;

m1 = RandomVariate[meanDist /. [Sigma] -> 1, {100000}];

m2 = RandomVariate[

   Last@*List @@ Part[a, 1] /. [Sigma] -> 1, {100000}];

Correlation[Thread[List[m1, m2]]]

ListPlot[Thread[List[m1, m2]]]

{{1., -0.00256777}, {-0.00256777, 1.}}

enter image description here

I'm not sure about correlation,but it's okay.

edited 3 hours ago

answered 5 hours ago

Xminer

30918

edited 3 hours ago

answered 5 hours ago

Xminer

30918

answered 5 hours ago

Xminer

30918

answered 5 hours ago

Xminer

30918

$begingroup$
I believe that the distributions are not independent. Since $overline{x}$ is computed from $y_i$ and other $y_j$'s, it would seem to be dependent. We could compute whether or not the distributions are dependent ...
$endgroup$
– mjw
4 hours ago

$begingroup$
I would also recommend using 10^6 rather than 100, you'll get a sharper plot!
$endgroup$
– mjw
4 hours ago

$begingroup$
Exactly, the two variables are not independent unfortunately
$endgroup$
– Andrea2810
4 hours ago

add a comment |

$begingroup$
I believe that the distributions are not independent. Since $overline{x}$ is computed from $y_i$ and other $y_j$'s, it would seem to be dependent. We could compute whether or not the distributions are dependent ...
$endgroup$
– mjw
4 hours ago

$begingroup$
I would also recommend using 10^6 rather than 100, you'll get a sharper plot!
$endgroup$
– mjw
4 hours ago

$begingroup$
Exactly, the two variables are not independent unfortunately
$endgroup$
– Andrea2810
4 hours ago

I believe that the distributions are not independent. Since $overline{x}$ is computed from $y_i$ and other $y_j$'s, it would seem to be dependent. We could compute whether or not the distributions are dependent ...

– mjw
4 hours ago

I would also recommend using 10^6 rather than 100, you'll get a sharper plot!

– mjw
4 hours ago

Exactly, the two variables are not independent unfortunately

– Andrea2810
4 hours ago

add a comment |

Here is the distribution of $x=overline{y}$ (Part I of your question):

a[n_] := Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}]; 

p[n_] := TransformedDistribution[Sum[y[k]/n, {k, n}], a[n]];

Now

x [Distributed] p[5] (* n=5, for example *)

The result is

x [Distributed] NormalDistribution[0, Abs[[Sigma]]/Sqrt[5]]

edited 28 mins ago

answered 5 hours ago

mjw

9779

$begingroup$
I am not sure, but shouldn't be n instead of 5 here TransformedDistribution[Sum[y[k]/n, {k, 5}], a] ? And what if I want to leave n, without assigning a value to n? Thanks @mjw
$endgroup$
– Andrea2810
4 hours ago

$begingroup$
Oh yes, you are right! I started with 10 and changed to five as I was trying it out. I'll fix it ... Thanks!
$endgroup$
– mjw
4 hours ago

$begingroup$
Let's go with five because it is clearer. The result is NormalDistribution[0,[Sigma]/Sqrt[5]]. Not sure why Mathematica puts Abs around $sigma$. Obviously, $sigma>0$.
$endgroup$
– mjw
4 hours ago

$begingroup$
Yes, sure it is clearer. Do you have any idea of how can I use n as a parameter, without assigning a value to n?
$endgroup$
– Andrea2810
4 hours ago

$begingroup$
a[n_] = Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}];
$endgroup$
– mjw
4 hours ago

|
show 5 more comments

Here is the distribution of $x=overline{y}$ (Part I of your question):

a[n_] := Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}]; 

p[n_] := TransformedDistribution[Sum[y[k]/n, {k, n}], a[n]];

Now

x [Distributed] p[5] (* n=5, for example *)

The result is

x [Distributed] NormalDistribution[0, Abs[[Sigma]]/Sqrt[5]]

edited 28 mins ago

answered 5 hours ago

mjw

9779

$begingroup$
I am not sure, but shouldn't be n instead of 5 here TransformedDistribution[Sum[y[k]/n, {k, 5}], a] ? And what if I want to leave n, without assigning a value to n? Thanks @mjw
$endgroup$
– Andrea2810
4 hours ago

$begingroup$
Oh yes, you are right! I started with 10 and changed to five as I was trying it out. I'll fix it ... Thanks!
$endgroup$
– mjw
4 hours ago

$begingroup$
Let's go with five because it is clearer. The result is NormalDistribution[0,[Sigma]/Sqrt[5]]. Not sure why Mathematica puts Abs around $sigma$. Obviously, $sigma>0$.
$endgroup$
– mjw
4 hours ago

$begingroup$
Yes, sure it is clearer. Do you have any idea of how can I use n as a parameter, without assigning a value to n?
$endgroup$
– Andrea2810
4 hours ago

$begingroup$
a[n_] = Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}];
$endgroup$
– mjw
4 hours ago

|
show 5 more comments

Here is the distribution of $x=overline{y}$ (Part I of your question):

a[n_] := Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}]; 

p[n_] := TransformedDistribution[Sum[y[k]/n, {k, n}], a[n]];

Now

x [Distributed] p[5] (* n=5, for example *)

The result is

x [Distributed] NormalDistribution[0, Abs[[Sigma]]/Sqrt[5]]

edited 28 mins ago

answered 5 hours ago

mjw

9779

Here is the distribution of $x=overline{y}$ (Part I of your question):

a[n_] := Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}]; 

p[n_] := TransformedDistribution[Sum[y[k]/n, {k, n}], a[n]];

Now

x [Distributed] p[5] (* n=5, for example *)

The result is

x [Distributed] NormalDistribution[0, Abs[[Sigma]]/Sqrt[5]]

edited 28 mins ago

answered 5 hours ago

mjw

9779

edited 28 mins ago

answered 5 hours ago

mjw

9779

answered 5 hours ago

mjw

9779

answered 5 hours ago

mjw

9779

$begingroup$
I am not sure, but shouldn't be n instead of 5 here TransformedDistribution[Sum[y[k]/n, {k, 5}], a] ? And what if I want to leave n, without assigning a value to n? Thanks @mjw
$endgroup$
– Andrea2810
4 hours ago

$begingroup$
Oh yes, you are right! I started with 10 and changed to five as I was trying it out. I'll fix it ... Thanks!
$endgroup$
– mjw
4 hours ago

$begingroup$
Let's go with five because it is clearer. The result is NormalDistribution[0,[Sigma]/Sqrt[5]]. Not sure why Mathematica puts Abs around $sigma$. Obviously, $sigma>0$.
$endgroup$
– mjw
4 hours ago

$begingroup$
Yes, sure it is clearer. Do you have any idea of how can I use n as a parameter, without assigning a value to n?
$endgroup$
– Andrea2810
4 hours ago

$begingroup$
a[n_] = Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}];
$endgroup$
– mjw
4 hours ago

|
show 5 more comments

$begingroup$
I am not sure, but shouldn't be n instead of 5 here TransformedDistribution[Sum[y[k]/n, {k, 5}], a] ? And what if I want to leave n, without assigning a value to n? Thanks @mjw
$endgroup$
– Andrea2810
4 hours ago

$begingroup$
Oh yes, you are right! I started with 10 and changed to five as I was trying it out. I'll fix it ... Thanks!
$endgroup$
– mjw
4 hours ago

$begingroup$
Let's go with five because it is clearer. The result is NormalDistribution[0,[Sigma]/Sqrt[5]]. Not sure why Mathematica puts Abs around $sigma$. Obviously, $sigma>0$.
$endgroup$
– mjw
4 hours ago

$begingroup$
Yes, sure it is clearer. Do you have any idea of how can I use n as a parameter, without assigning a value to n?
$endgroup$
– Andrea2810
4 hours ago

$begingroup$
a[n_] = Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}];
$endgroup$
– mjw
4 hours ago

I am not sure, but shouldn't be n instead of 5 here TransformedDistribution[Sum[y[k]/n, {k, 5}], a] ? And what if I want to leave n, without assigning a value to n? Thanks @mjw

– Andrea2810
4 hours ago

Oh yes, you are right! I started with 10 and changed to five as I was trying it out. I'll fix it ... Thanks!

– mjw
4 hours ago

Let's go with five because it is clearer. The result is NormalDistribution[0,[Sigma]/Sqrt[5]]. Not sure why Mathematica puts Abs around $sigma$. Obviously, $sigma>0$.

– mjw
4 hours ago

Yes, sure it is clearer. Do you have any idea of how can I use n as a parameter, without assigning a value to n?

– Andrea2810
4 hours ago

a[n_] = Table[y[k] [Distributed] NormalDistribution[0, [Sigma]], {k, 1, n}];

– mjw
4 hours ago

|
show 5 more comments

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