Conditional Normal Random Distribution

Question

Vinit Nagda el 19 de Ag. de 2021

0
Enlazar

Enlace directo a esta pregunta

https://la.mathworks.com/matlabcentral/answers/1436894-conditional-normal-random-distribution

Comentada: Paul el 23 de Ag. de 2021

I want to generate a random vector (a) from a normal distribution N(mu,sigma) (mu,sigma:known) with a condition that the first n values of vector 'a' are known and fixed (basically its fulfilling boundary conditions).

Is there any way I can use Multivariate normal random numbers function: R = mvnrnd(mu,Sigma) or any other method?

0 comentarios
Mostrar -2 comentarios más antiguosOcultar -2 comentarios más antiguos

Iniciar sesión para comentar.

Iniciar sesión para responder a esta pregunta.

Answer 1

Paul el 19 de Ag. de 2021

0
Enlazar

Enlace directo a esta respuesta

https://la.mathworks.com/matlabcentral/answers/1436894-conditional-normal-random-distribution#answer_770809

Yes. If you know mu and Sigma of the vector x and the first n values of x are given, then the density of x(n+1:end) is also normal and can be derived from mu, Sigma, and x(1:n). See this link for the math to get the mean and covariance of x(n+1:end) condtioned on x(1:n), then you can use mvnrnd to generate random numbers of x(n+1:end)

10 comentarios
Mostrar 8 comentarios más antiguosOcultar 8 comentarios más antiguos

Paul el 19 de Ag. de 2021

Abrir en MATLAB Online

My interpretation of the question is as follows:

Let X be a random vector (numel(X) = n + m) where the elements of X have a joint normal density function with mean mu and covariance Sigma. p random vectors of X can be generated with

X = mvnrnd(mu,Sigma,p);

The question implies that the need is to generate random values of X(n+1:n+m) (let's call it Xsub), becaue the first n values of X are given. If we didn't have any information about the known values of X, then the elements of Xsub also have a joint normal density with musub = mu(n+1:n+m) and Sigmasub = Sigma(n+1:n+m,n+1:n+m).

However, the question states that first n values of X are known. With that additional information, the joint denity of the elements of Xsub is still normal, but the mean and covariance of Xsub conditioned on the known values of x(1:n), called mubar and Sigmabar, can be quite different than musub and Sigmasub. The link shows how to compute mubar and Sigmabar based on mu, Sigma, and the given elements of X, which the link calls 'a'.

Note that the link partitions X the opposite of the problem here, i.e., the link shows what to do when the lower part of X is known, but that's easily handled by, for example, reindexing X and changing mu and Sigma appropriately.

Once mubar and Sigmabar are computed, then random vectors of Xsub can be realized by

Xsub = mvnrnd(mubar,Sigmabar,p);

and p realizations of the full vector X would then then be

X = [repmat(a(:).' , p , 1) Xsub];

Paul el 23 de Ag. de 2021

Editada: Paul el 23 de Ag. de 2021

Abrir en MATLAB Online

Hi @Vinit Nagda

Offhand I don't see anything wrong with your code, but there may be a few things you can do to improve it for clarity.

Basically, it would be clearer to define variables in accordance with the equations you're going to implement, instead of using the explicit indexing in those equations. That is, define the variables mu1, mu2, Sigma11, Sigma12, Sigma21 and Sigma22 based on mu, sigma, and ind, and then use the mu* and Sigma* variables as needed. Sacrifice a very small amount of efficiency (at leadt for this example) for a lot of clarity.

Perhaps rename the variable s12s22 to s12s22inv.

Instead of hardcoding ind to a value, compute it based on numel(v) and numel(values).

Finally the use of ^(-1) is disouraged for a matrix inverse. In this instance, use the / operator, i.e.,

s12s22inv = Sigma12/Sigma22;

Having said all of that, this example data might not be useful for illustrating the concept of conditional probability density. The reason is that sigma (which I would call Sigma) is diagonal, which means that all 10 of the random variables in X are jointly independent. Joint independence means that knowledge of the values of any subset of the random variables does not give any additional information about the others that will change their probability densities. Hence, the probability density of the unknown variables is the same as what you started with, which is exactly what your code shows, i.e. mubar = mu(1:8) and Sigmabar = Sigma11).

What different result were you expecting?

Vinit Nagda el 23 de Ag. de 2021

@Paul Thank you very much for your response.

Actually, I didn't know what result to expect and I just compared your example with my code and thought something was wrong. But, I now understand the joint independence concept and thanks a lot for sharing that.

Also, thanks for your suggestions, I will try to make my code look more code-like with simplifications and clarity.

Just, one last final thing (I will then close this thread and not disturb you more). As in the link you shared, lower part of x(x2) is known and in my case x_1 is known so I have to do reindexing.

The order of elements in random normal vector and mu vector can be easily reversed, I just want to confirm the reindexing of Sigma matrix. Flipping the elements of matrix across diagonal and reversing the diagonal elements should work right?

Thank you. I very much appreciate your time and help.

Paul el 23 de Ag. de 2021

Abrir en MATLAB Online

@Vinit Nagda

I didn't provide an example, so I'm still not sure what you've compared to your code.

Instead of reindexing your problem to fit the formula, it's probably easier to modfiy the formula to fit your problem. Just reverse the 1's and 2's.

mubar    = mu2 + Sigma21/Sigma11*(a - mu1);
Sigmabar = Sigma22 - Sigma21/Sigma11*Sigma12;

Feel free to come back if you have any more questions, particularly if you want to post your code with an example. However, if you do, don't use a 10-element vector in the example. Maybe use a 3-element vector X and show the mubar and Sigmabar of X(3) given known values of X(1) and X(2).

Iniciar sesión para comentar.

Conditional Normal Random Distribution

0 comentarios
Mostrar -2 comentarios más antiguosOcultar -2 comentarios más antiguos

Respuesta aceptada

10 comentarios
Mostrar 8 comentarios más antiguosOcultar 8 comentarios más antiguos

Más respuestas (0)

Ver también

Categorías

Etiquetas

Productos

Versión

Community Treasure Hunt

Conditional Normal Random Distribution

0 comentarios Mostrar -2 comentarios más antiguosOcultar -2 comentarios más antiguos

Respuesta aceptada

10 comentarios Mostrar 8 comentarios más antiguosOcultar 8 comentarios más antiguos

Más respuestas (0)

Ver también

Categorías

Etiquetas

Productos

Versión

Community Treasure Hunt

0 comentarios
Mostrar -2 comentarios más antiguosOcultar -2 comentarios más antiguos

10 comentarios
Mostrar 8 comentarios más antiguosOcultar 8 comentarios más antiguos