| Package | Description |
|---|---|
| org.orekit.ssa.collision.shorttermencounter.probability.twod |
Package specific to calculus assuming a 2D short-term encounter model.
|
| Modifier and Type | Method and Description |
|---|---|
ProbabilityOfCollision |
AbstractShortTermEncounter2DPOCMethod.compute(Cdm cdm,
double combinedRadius)
Compute the probability of collision using a Conjunction Data Message (CDM).
|
ProbabilityOfCollision |
ShortTermEncounter2DPOCMethod.compute(Cdm cdm,
double combinedRadius)
Compute the probability of collision using a Conjunction Data Message (CDM).
|
default ProbabilityOfCollision |
ShortTermEncounter2DPOCMethod.compute(Cdm cdm,
double primaryRadius,
double secondaryRadius)
Compute the probability of collision using a Conjunction Data Message (CDM).
|
ProbabilityOfCollision |
AbstractShortTermEncounter1DNumerical2DPOCMethod.compute(Cdm cdm,
double primaryRadius,
double secondaryRadius,
org.hipparchus.analysis.integration.UnivariateIntegrator customIntegrator,
int customMaxNbOfEval,
double zeroThreshold)
Compute the probability of collision using an
Orekit Conjunction Data Message. |
ProbabilityOfCollision |
Alfano2005.compute(double xm,
double ym,
double sigmaX,
double sigmaY,
double radius)
Compute the probability of collision using arguments specific to the rotated encounter frame.
|
ProbabilityOfCollision |
Laas2015.compute(double xm,
double ym,
double sigmaX,
double sigmaY,
double radius)
Compute the probability of collision using arguments specific to the rotated encounter frame.
|
abstract ProbabilityOfCollision |
AbstractShortTermEncounter2DPOCMethod.compute(double xm,
double ym,
double sigmaX,
double sigmaY,
double radius)
Compute the probability of collision using arguments specific to the rotated encounter frame.
|
ProbabilityOfCollision |
Chan1997.compute(double xm,
double ym,
double sigmaX,
double sigmaY,
double radius)
Compute the probability of collision using arguments specific to the rotated encounter frame.
|
ProbabilityOfCollision |
ShortTermEncounter2DPOCMethod.compute(double xm,
double ym,
double sigmaX,
double sigmaY,
double radius)
Compute the probability of collision using arguments specific to the rotated encounter frame.
|
ProbabilityOfCollision |
AbstractShortTermEncounter1DNumerical2DPOCMethod.compute(double xm,
double ym,
double sigmaX,
double sigmaY,
double radius)
Compute the probability of collision using arguments specific to the rotated encounter frame.
|
ProbabilityOfCollision |
AbstractAlfriend1999.compute(double xm,
double ym,
double sigmaX,
double sigmaY,
double radius)
Compute the probability of collision using arguments specific to the rotated encounter frame.
|
abstract ProbabilityOfCollision |
AbstractShortTermEncounter1DNumerical2DPOCMethod.compute(double xm,
double ym,
double sigmaX,
double sigmaY,
double radius,
org.hipparchus.analysis.integration.UnivariateIntegrator customIntegrator,
int customMaxNbOfEval)
Compute the probability of collision using arguments specific to the rotated encounter frame and custom numerical
configuration.
|
ProbabilityOfCollision |
Patera2005.compute(double xm,
double ym,
double sigmaX,
double sigmaY,
double radius,
org.hipparchus.analysis.integration.UnivariateIntegrator integrator,
int customMaxNbOfEval)
Compute the probability of collision using arguments specific to the rotated encounter frame and custom numerical
configuration.
|
default ProbabilityOfCollision |
ShortTermEncounter2DPOCMethod.compute(Orbit primaryAtTCA,
StateCovariance primaryCovariance,
double primaryRadius,
Orbit secondaryAtTCA,
StateCovariance secondaryCovariance,
double secondaryRadius)
Compute the probability of collision using parameters necessary for creating a
collision definition instance. |
ProbabilityOfCollision |
AbstractShortTermEncounter1DNumerical2DPOCMethod.compute(Orbit primaryAtTCA,
StateCovariance primaryCovariance,
double primaryRadius,
Orbit secondaryAtTCA,
StateCovariance secondaryCovariance,
double secondaryRadius,
org.hipparchus.analysis.integration.UnivariateIntegrator customIntegrator,
int customMaxNbOfEval,
double zeroThreshold)
Compute the probability of collision using parameters necessary for creating a
collision definition instance. |
default ProbabilityOfCollision |
ShortTermEncounter2DPOCMethod.compute(Orbit primaryAtTCA,
StateCovariance primaryCovariance,
Orbit secondaryAtTCA,
StateCovariance secondaryCovariance,
double combinedRadius)
Compute the probability of collision using parameters necessary for creating a
collision definition instance. |
ProbabilityOfCollision |
AbstractShortTermEncounter2DPOCMethod.compute(Orbit primaryAtTCA,
StateCovariance primaryCovariance,
Orbit secondaryAtTCA,
StateCovariance secondaryCovariance,
double combinedRadius,
double zeroThreshold)
Compute the probability of collision using parameters necessary for creating a
collision definition instance. |
ProbabilityOfCollision |
ShortTermEncounter2DPOCMethod.compute(Orbit primaryAtTCA,
StateCovariance primaryCovariance,
Orbit secondaryAtTCA,
StateCovariance secondaryCovariance,
double combinedRadius,
double zeroThreshold)
Compute the probability of collision using parameters necessary for creating a
collision definition instance. |
default ProbabilityOfCollision |
ShortTermEncounter2DPOCMethod.compute(ShortTermEncounter2DDefinition encounter)
Compute the probability of collision using given collision definition.
|
ProbabilityOfCollision |
AbstractShortTermEncounter2DPOCMethod.compute(ShortTermEncounter2DDefinition encounter,
double zeroThreshold)
Compute the probability of collision using given collision definition.
|
ProbabilityOfCollision |
ShortTermEncounter2DPOCMethod.compute(ShortTermEncounter2DDefinition encounter,
double zeroThreshold)
Compute the probability of collision using given collision definition.
|
ProbabilityOfCollision |
AbstractShortTermEncounter1DNumerical2DPOCMethod.compute(ShortTermEncounter2DDefinition encounterDefinition,
org.hipparchus.analysis.integration.UnivariateIntegrator customIntegrator,
int customMaxNbOfEval,
double zeroThreshold)
Compute the probability of collision using a given collision definition.
|
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