Package | Description |
---|---|
fr.cnes.sirius.patrius.attitudes | |
fr.cnes.sirius.patrius.math.analysis.integration.gauss | |
fr.cnes.sirius.patrius.math.distribution | |
fr.cnes.sirius.patrius.math.optim |
Generally, optimizers are algorithms that will either
minimize or
maximize
a scalar function, called the
objective
function . |
fr.cnes.sirius.patrius.math.util |
Constructor and Description |
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RelativeTabulatedAttitudeLaw(AbsoluteDate refDate,
List<Pair<Double,AngularCoordinates>> angularCoordinates,
Frame frame,
RelativeTabulatedAttitudeLaw.AroundAttitudeType lawBefore,
RelativeTabulatedAttitudeLaw.AroundAttitudeType lawAfter)
Create a RelativeTabulatedAttitudeLaw object with list of Angular Coordinates (during the interval of validity),
a law before the interval and a law after the interval.
|
RelativeTabulatedAttitudeLaw(Frame frame,
AbsoluteDate refDate,
List<Pair<Double,Rotation>> orientations,
RelativeTabulatedAttitudeLaw.AroundAttitudeType lawBefore,
RelativeTabulatedAttitudeLaw.AroundAttitudeType lawAfter)
Create a RelativeTabulatedAttitudeLaw object with list of rotations (during the interval of validity),
a law before the interval and a law after the interval.
|
RelativeTabulatedAttitudeLeg(AbsoluteDate referenceDate,
Frame frame,
List<Pair<Double,AngularCoordinates>> angularCoordinates)
Build a RelativeTabulatedAttitudeLeg with a reference date, a list of angular coordinates
associated with a double representing the time elapsed since the reference date.
|
RelativeTabulatedAttitudeLeg(AbsoluteDate referenceDate,
Frame frame,
List<Pair<Double,AngularCoordinates>> angularCoordinates,
String natureIn)
Build a RelativeTabulatedAttitudeLeg with a reference date, a list of angular coordinates
associated with a double representing the time elapsed since the reference date.
|
RelativeTabulatedAttitudeLeg(AbsoluteDate referenceDate,
List<Pair<Double,AngularCoordinates>> angularCoordinates,
int nbInterpolationPoints,
Frame frame)
Build a RelativeTabulatedAttitudeLeg with a reference date, a list of angular coordinates
associated with a double representing the time elapsed since the reference date
and a number of points used for interpolation.
|
RelativeTabulatedAttitudeLeg(AbsoluteDate referenceDate,
List<Pair<Double,AngularCoordinates>> angularCoordinates,
int nbInterpolationPoints,
Frame frame,
String natureIn)
Build a RelativeTabulatedAttitudeLeg with a reference date, a list of angular coordinates
associated with a double representing the time elapsed since the reference date and a number
of points used for interpolation.
|
RelativeTabulatedAttitudeLeg(AbsoluteDate referenceDate,
List<Pair<Double,Rotation>> orientations,
Frame frame)
Build a RelativeTabulatedAttitudeLeg with a reference date, a list of Rotations
associated with a double representing the time elapsed since the reference date.
|
RelativeTabulatedAttitudeLeg(AbsoluteDate referenceDate,
List<Pair<Double,Rotation>> orientations,
Frame frame,
int nbInterpolationPoints)
Build a RelativeTabulatedAttitudeLeg with a reference date, a list of Rotations
associated with a double representing the time elapsed since the reference date
and a number of points used for interpolation.
|
RelativeTabulatedAttitudeLeg(AbsoluteDate referenceDate,
List<Pair<Double,Rotation>> orientations,
Frame frame,
int nbInterpolationPoints,
String natureIn)
Build a RelativeTabulatedAttitudeLeg with a reference date, a list of Rotations associated
with a double representing the time elapsed since the reference date and a number of points
used for interpolation.
|
RelativeTabulatedAttitudeLeg(AbsoluteDate referenceDate,
List<Pair<Double,Rotation>> orientations,
Frame frame,
String natureIn)
Build a RelativeTabulatedAttitudeLeg with a reference date, a list of Rotations associated
with a double representing the time elapsed since the reference date.
|
Modifier and Type | Method and Description |
---|---|
protected Pair<Double[],Double[]> |
LegendreRuleFactory.computeRule(int numberOfPoints)
Computes the rule for the given order.
|
protected abstract Pair<T[],T[]> |
BaseRuleFactory.computeRule(int numberOfPoints)
Computes the rule for the given order.
|
protected Pair<BigDecimal[],BigDecimal[]> |
LegendreHighPrecisionRuleFactory.computeRule(int numberOfPoints)
Computes the rule for the given order.
|
Pair<double[],double[]> |
BaseRuleFactory.getRule(int numberOfPoints)
Gets a copy of the quadrature rule with the given number of integration
points.
|
protected Pair<T[],T[]> |
BaseRuleFactory.getRuleInternal(int numberOfPoints)
Gets a rule.
|
Modifier and Type | Method and Description |
---|---|
protected void |
BaseRuleFactory.addRule(Pair<T[],T[]> rule)
Stores a rule.
|
Constructor and Description |
---|
GaussIntegrator(Pair<double[],double[]> pointsAndWeights)
Creates an integrator from the given pair of points (first element of
the pair) and weights (second element of the pair.
|
Modifier and Type | Method and Description |
---|---|
static List<Pair<Double,MultivariateNormalDistribution>> |
MixtureMultivariateNormalDistribution.createComponents(double[] weights,
double[][] means,
double[][][] covariances)
Creates a mixture of Gaussian distributions.
|
List<Pair<Double,T>> |
MixtureMultivariateRealDistribution.getComponents()
Gets the distributions that make up the mixture model.
|
Constructor and Description |
---|
MixtureMultivariateNormalDistribution(List<Pair<Double,MultivariateNormalDistribution>> components)
Creates a mixture model from a list of distributions and their
associated weights.
|
MixtureMultivariateNormalDistribution(RandomGenerator rng,
List<Pair<Double,MultivariateNormalDistribution>> components)
Creates a mixture model from a list of distributions and their
associated weights.
|
MixtureMultivariateRealDistribution(List<Pair<Double,T>> components)
Creates a mixture model from a list of distributions and their
associated weights.
|
MixtureMultivariateRealDistribution(RandomGenerator rng,
List<Pair<Double,T>> components)
Creates a mixture model from a list of distributions and their
associated weights.
|
Modifier and Type | Class and Description |
---|---|
class |
SimplePointChecker<T extends Pair<double[],? extends Object>>
Simple implementation of the
ConvergenceChecker interface using
only point coordinates. |
Modifier and Type | Class and Description |
---|---|
class |
PointValuePair
This class holds a point and the value of an objective function at
that point.
|
class |
PointVectorValuePair
This class holds a point and the vectorial value of an objective function at
that point.
|
Constructor and Description |
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Pair(Pair<? extends K,? extends V> entry)
Create an entry representing the same mapping as the specified entry.
|
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