public class BetaDistribution extends AbstractRealDistribution
DEFAULT_SOLVER_ABSOLUTE_ACCURACY
Constructor and Description |
---|
BetaDistribution(double alpha,
double beta)
Build a new instance.
|
BetaDistribution(double alpha,
double beta,
double inverseCumAccuracy)
Build a new instance.
|
Modifier and Type | Method and Description |
---|---|
double |
cumulativeProbability(double x)
For a random variable
X whose values are distributed according
to this distribution, this method returns P(X <= x) . |
double |
density(double x)
Returns the probability density function (PDF) of this distribution
evaluated at the specified point
x . |
double |
getAlpha()
Access the first shape parameter,
alpha . |
double |
getBeta()
Access the second shape parameter,
beta . |
double |
getNumericalMean()
Use this method to get the numerical value of the mean of this
distribution.
|
double |
getNumericalVariance()
Use this method to get the numerical value of the variance of this
distribution.
|
double |
getSupportLowerBound()
Access the lower bound of the support.
|
double |
getSupportUpperBound()
Access the upper bound of the support.
|
boolean |
isSupportConnected()
Use this method to get information about whether the support is connected,
i.e.
|
double |
logDensity(double x)
Returns the natural logarithm of the probability density function
(PDF) of this distribution evaluated at the specified point
x . |
getSolverAbsoluteAccuracy, inverseCumulativeProbability, probability
public BetaDistribution(double alpha, double beta)
alpha
- First shape parameter (must be positive).beta
- Second shape parameter (must be positive).public BetaDistribution(double alpha, double beta, double inverseCumAccuracy)
alpha
- First shape parameter (must be positive).beta
- Second shape parameter (must be positive).inverseCumAccuracy
- Maximum absolute error in inverse
cumulative probability estimates (defaults to
AbstractRealDistribution.DEFAULT_SOLVER_ABSOLUTE_ACCURACY
).public double getAlpha()
alpha
.public double getBeta()
beta
.public double density(double x)
x
. In general, the PDF is
the derivative of the CDF
.
If the derivative does not exist at x
, then an appropriate
replacement should be returned, e.g. Double.POSITIVE_INFINITY
,
Double.NaN
, or the limit inferior or limit superior of the
difference quotient.x
- the point at which the PDF is evaluatedx
public double logDensity(double x)
x
.
In general, the PDF is the derivative of the CDF
.
If the derivative does not exist at x
, then an appropriate replacement
should be returned, e.g. Double.POSITIVE_INFINITY
, Double.NaN
,
or the limit inferior or limit superior of the difference quotient. Note that
due to the floating point precision and under/overflow issues, this method will
for some distributions be more precise and faster than computing the logarithm of
RealDistribution.density(double)
.
The default implementation simply computes the logarithm of density(x)
.
logDensity
in interface RealDistribution
logDensity
in class AbstractRealDistribution
x
- the point at which the PDF is evaluatedx
public double cumulativeProbability(double x)
X
whose values are distributed according
to this distribution, this method returns P(X <= x)
. In other
words, this method represents the (cumulative) distribution function
(CDF) for this distribution.x
- the point at which the CDF is evaluatedx
public double getNumericalMean()
alpha
and second shape parameter
beta
, the mean is alpha / (alpha + beta)
.Double.NaN
if it is not definedpublic double getNumericalVariance()
alpha
and second shape parameter
beta
, the variance is
(alpha * beta) / [(alpha + beta)^2 * (alpha + beta + 1)]
.Double.POSITIVE_INFINITY
as
for certain cases in TDistribution
)
or Double.NaN
if it is not definedpublic double getSupportLowerBound()
inverseCumulativeProbability(0)
. In other words, this
method must return
inf {x in R | P(X <= x) > 0}
.
public double getSupportUpperBound()
inverseCumulativeProbability(1)
. In other words, this
method must return
inf {x in R | P(X <= x) = 1}
.
public boolean isSupportConnected()
true
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