dist.Normal.Variance: Normal Distribution: Variance Parameterization
In LaplacesDemonR/LaplacesDemon: Complete Environment for Bayesian Inference
dist.Normal.Variance R Documentation
Normal Distribution: Variance Parameterization
Description
These functions provide the density, distribution function, quantile
function, and random generation for the univariate normal distribution
with mean \mu and variance \sigma^2.
Usage
dnormv(x, mean=0, var=1, log=FALSE)
pnormv(q, mean=0, var=1, lower.tail=TRUE, log.p=FALSE)
qnormv(p, mean=0, var=1, lower.tail=TRUE, log.p=FALSE)
rnormv(n, mean=0, var=1)
Arguments
x, q
These are each a vector of quantiles.
p
This is a vector of probabilities.
n
This is the number of observations, which must be a positive
integer that has length 1.
mean
This is the mean parameter \mu.
var
This is the variance parameter \sigma^2, which
must be positive.
log, log.p
Logical. If TRUE, then probabilities p
are given as \log(p).
lower.tail
Logical. If TRUE (default), then probabilities
are Pr[X \le x], otherwise,
Pr[X > x].
Details
Application: Continuous Univariate
Density: p(\theta) = \frac{1}{\sqrt{2\pi\sigma^2}}
\exp(-\frac{(\theta-\mu)^2}{2\sigma^2})
Inventor: Carl Friedrich Gauss or Abraham De Moivre
Notation 1: \theta \sim \mathcal{N}(\mu, \sigma^2)
Notation 2: p(\theta) = \mathcal{N}(\theta | \mu,
\sigma^2)
Parameter 1: mean parameter \mu
Parameter 2: variance parameter \sigma^2 > 0
Mean: E(\theta) = \mu
Variance: var(\theta) = \sigma^2
Mode: mode(\theta) = \mu
The normal distribution, also called the Gaussian distribution and the
Second Law of Laplace, is usually parameterized with mean and variance.
Base R uses the mean and standard deviation. These functions
provide the variance parameterization for convenience and familiarity.
For example, it is easier to code dnormv(1,1,1000) than
dnorm(1,1,sqrt(1000)).
Some authors attribute credit for the normal distribution to Abraham
de Moivre in 1738. In 1809, Carl Friedrich Gauss published his
monograph “Theoria motus corporum coelestium in sectionibus conicis
solem ambientium”, in which he introduced the method of least squares,
method of maximum likelihood, and normal distribution, among many other
innovations.
Gauss, himself, characterized this distribution according to mean and
precision, though his definition of precision differed from the modern
one.
Although the normal distribution is very common, it often does not fit
data as well as more robust alternatives with fatter tails, such as the
Laplace or Student t distribution.
A flat distribution is obtained in the limit as
\sigma^2 \rightarrow \infty.
For models where the dependent variable, y, is specified to be
normally distributed given the model, the Jarque-Bera test (see
plot.demonoid.ppc or plot.laplace.ppc) may
be used to test the residuals.
These functions are similar to those in base R.
Value
dnormv gives the density,
pnormv gives the distribution function,
qnormv gives the quantile function, and
rnormv generates random deviates.
Author(s)
Statisticat, LLC. software@bayesian-inference.com
See Also
dlaplace,
dnorm,
dnormp,
dst,
dt,
plot.demonoid.ppc, and
plot.laplace.ppc.
Examples
library(LaplacesDemon)
x <- dnormv(1,0,1)
x <- pnormv(1,0,1)
x <- qnormv(0.5,0,1)
x <- rnormv(100,0,1)
#Plot Probability Functions
x <- seq(from=-5, to=5, by=0.1)
plot(x, dnormv(x,0,0.5), ylim=c(0,1), type="l", main="Probability Function",
ylab="density", col="red")
lines(x, dnormv(x,0,1), type="l", col="green")
lines(x, dnormv(x,0,5), type="l", col="blue")
legend(2, 0.9, expression(paste(mu==0, ", ", sigma^2==0.5),
paste(mu==0, ", ", sigma^2==1), paste(mu==0, ", ", sigma^2==5)),
lty=c(1,1,1), col=c("red","green","blue"))
LaplacesDemonR/LaplacesDemon documentation built on April 1, 2024, 7:22 a.m.
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| dist.Normal.Variance | R Documentation |
Normal Distribution: Variance Parameterization
Description
These functions provide the density, distribution function, quantile
function, and random generation for the univariate normal distribution
with mean \mu and variance \sigma^2.
Usage
dnormv(x, mean=0, var=1, log=FALSE)
pnormv(q, mean=0, var=1, lower.tail=TRUE, log.p=FALSE)
qnormv(p, mean=0, var=1, lower.tail=TRUE, log.p=FALSE)
rnormv(n, mean=0, var=1)
Arguments
x, q |
These are each a vector of quantiles. |
p |
This is a vector of probabilities. |
n |
This is the number of observations, which must be a positive integer that has length 1. |
mean |
This is the mean parameter |
var |
This is the variance parameter |
log, log.p |
Logical. If |
lower.tail |
Logical. If |
Details
Application: Continuous Univariate
Density:
p(\theta) = \frac{1}{\sqrt{2\pi\sigma^2}} \exp(-\frac{(\theta-\mu)^2}{2\sigma^2})Inventor: Carl Friedrich Gauss or Abraham De Moivre
Notation 1:
\theta \sim \mathcal{N}(\mu, \sigma^2)Notation 2:
p(\theta) = \mathcal{N}(\theta | \mu, \sigma^2)Parameter 1: mean parameter
\muParameter 2: variance parameter
\sigma^2 > 0Mean:
E(\theta) = \muVariance:
var(\theta) = \sigma^2Mode:
mode(\theta) = \mu
The normal distribution, also called the Gaussian distribution and the
Second Law of Laplace, is usually parameterized with mean and variance.
Base R uses the mean and standard deviation. These functions
provide the variance parameterization for convenience and familiarity.
For example, it is easier to code dnormv(1,1,1000) than
dnorm(1,1,sqrt(1000)).
Some authors attribute credit for the normal distribution to Abraham de Moivre in 1738. In 1809, Carl Friedrich Gauss published his monograph “Theoria motus corporum coelestium in sectionibus conicis solem ambientium”, in which he introduced the method of least squares, method of maximum likelihood, and normal distribution, among many other innovations.
Gauss, himself, characterized this distribution according to mean and precision, though his definition of precision differed from the modern one.
Although the normal distribution is very common, it often does not fit data as well as more robust alternatives with fatter tails, such as the Laplace or Student t distribution.
A flat distribution is obtained in the limit as
\sigma^2 \rightarrow \infty.
For models where the dependent variable, y, is specified to be
normally distributed given the model, the Jarque-Bera test (see
plot.demonoid.ppc or plot.laplace.ppc) may
be used to test the residuals.
These functions are similar to those in base R.
Value
dnormv gives the density,
pnormv gives the distribution function,
qnormv gives the quantile function, and
rnormv generates random deviates.
Author(s)
Statisticat, LLC. software@bayesian-inference.com
See Also
dlaplace,
dnorm,
dnormp,
dst,
dt,
plot.demonoid.ppc, and
plot.laplace.ppc.
Examples
library(LaplacesDemon)
x <- dnormv(1,0,1)
x <- pnormv(1,0,1)
x <- qnormv(0.5,0,1)
x <- rnormv(100,0,1)
#Plot Probability Functions
x <- seq(from=-5, to=5, by=0.1)
plot(x, dnormv(x,0,0.5), ylim=c(0,1), type="l", main="Probability Function",
ylab="density", col="red")
lines(x, dnormv(x,0,1), type="l", col="green")
lines(x, dnormv(x,0,5), type="l", col="blue")
legend(2, 0.9, expression(paste(mu==0, ", ", sigma^2==0.5),
paste(mu==0, ", ", sigma^2==1), paste(mu==0, ", ", sigma^2==5)),
lty=c(1,1,1), col=c("red","green","blue"))
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