dist.Multivariate.Cauchy: Multivariate Cauchy Distribution
In ecbrown/LaplacesDemon: Complete Environment for Bayesian Inference
Description
Usage
Arguments
Details
Value
Author(s)
See Also
Examples
Description
These functions provide the density and random number generation for
the multivariate Cauchy distribution.
Usage
1
2
Arguments
x
This is either a vector of length k or a matrix with
a number of columns, k, equal to the number of columns in
scale matrix S.
n
This is the number of random draws.
mu
This is a numeric vector representing the location parameter,
mu (the mean vector), of the multivariate distribution
It must be of length k, as defined above.
S
This is a k x k positive-definite scale
matrix S.
log
Logical. If log=TRUE, then the logarithm of the
density is returned.
Details
Application: Continuous Multivariate
Density:
p(theta)
= Gamma[(1+k)/2] /
{Gamma(1/2)1^(k/2)pi^(k/2)|Sigma|^(1/2)[1+(theta-mu)^T*Sigma^(-1)(theta-mu)]^[(1+k)/2]}
Inventor: Unknown (to me, anyway)
Notation 1: theta ~
MC[k](mu, Sigma)
Notation 2: p(theta) = MC[k](theta | mu, Sigma)
Parameter 1: location vector mu
Parameter 2: positive-definite k x k scale
matrix Sigma
Mean: E(theta) = mu
Variance: var(theta) = undefined
Mode: mode(theta) = mu
The multivariate Cauchy distribution is a multidimensional extension of the
one-dimensional or univariate Cauchy distribution. The multivariate
Cauchy distribution is equivalent to a multivariate t distribution with
1 degree of freedom. A random vector is considered to be multivariate
Cauchy-distributed if every linear combination of its components has a
univariate Cauchy distribution.
The Cauchy distribution is known as a pathological distribution because
its mean and variance are undefined, and it does not satisfy the central
limit theorem.
Value
dmvc gives the density and
rmvc generates random deviates.
Author(s)
Statisticat, LLC. software@bayesian-inference.com
See Also
dcauchy,
dinvwishart,
dmvcp,
dmvt, and
dmvtp.
Examples
1
2
3
4
5
6
7
8
9
10
11
12
library(LaplacesDemon)
x <- seq(-2,4,length=21)
y <- 2*x+10
z <- x+cos(y)
mu <- c(1,12,2)
Sigma <- matrix(c(1,2,0,2,5,0.5,0,0.5,3), 3, 3)
f <- dmvc(cbind(x,y,z), mu, Sigma)
X <- rmvc(1000, rep(0,2), diag(2))
X <- X[rowSums((X >= quantile(X, probs=0.025)) &
(X <= quantile(X, probs=0.975)))==2,]
joint.density.plot(X[,1], X[,2], color=TRUE)
ecbrown/LaplacesDemon documentation built on May 15, 2019, 7:48 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Description Usage Arguments Details Value Author(s) See Also Examples
Description
These functions provide the density and random number generation for the multivariate Cauchy distribution.
Usage
1 2 |
Arguments
x |
This is either a vector of length k or a matrix with a number of columns, k, equal to the number of columns in scale matrix S. |
n |
This is the number of random draws. |
mu |
This is a numeric vector representing the location parameter, mu (the mean vector), of the multivariate distribution It must be of length k, as defined above. |
S |
This is a k x k positive-definite scale matrix S. |
log |
Logical. If |
Details
Application: Continuous Multivariate
Density:
p(theta) = Gamma[(1+k)/2] / {Gamma(1/2)1^(k/2)pi^(k/2)|Sigma|^(1/2)[1+(theta-mu)^T*Sigma^(-1)(theta-mu)]^[(1+k)/2]}
Inventor: Unknown (to me, anyway)
Notation 1: theta ~ MC[k](mu, Sigma)
Notation 2: p(theta) = MC[k](theta | mu, Sigma)
Parameter 1: location vector mu
Parameter 2: positive-definite k x k scale matrix Sigma
Mean: E(theta) = mu
Variance: var(theta) = undefined
Mode: mode(theta) = mu
The multivariate Cauchy distribution is a multidimensional extension of the one-dimensional or univariate Cauchy distribution. The multivariate Cauchy distribution is equivalent to a multivariate t distribution with 1 degree of freedom. A random vector is considered to be multivariate Cauchy-distributed if every linear combination of its components has a univariate Cauchy distribution.
The Cauchy distribution is known as a pathological distribution because its mean and variance are undefined, and it does not satisfy the central limit theorem.
Value
dmvc gives the density and
rmvc generates random deviates.
Author(s)
Statisticat, LLC. software@bayesian-inference.com
See Also
dcauchy,
dinvwishart,
dmvcp,
dmvt, and
dmvtp.
Examples
1 2 3 4 5 6 7 8 9 10 11 12 | library(LaplacesDemon)
x <- seq(-2,4,length=21)
y <- 2*x+10
z <- x+cos(y)
mu <- c(1,12,2)
Sigma <- matrix(c(1,2,0,2,5,0.5,0,0.5,3), 3, 3)
f <- dmvc(cbind(x,y,z), mu, Sigma)
X <- rmvc(1000, rep(0,2), diag(2))
X <- X[rowSums((X >= quantile(X, probs=0.025)) &
(X <= quantile(X, probs=0.975)))==2,]
joint.density.plot(X[,1], X[,2], color=TRUE)
|
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.