public class BracketingNthOrderBrentSolver extends AbstractUnivariateSolver implements BracketedUnivariateSolver<UnivariateFunction>, Serializable
The changes with respect to the original Brent algorithm are:
AllowedSolution
,Constructor and Description |
---|
BracketingNthOrderBrentSolver()
Construct a solver with default accuracy and maximal order (1e-6 and 5 respectively)
|
BracketingNthOrderBrentSolver(double relativeAccuracy,
double absoluteAccuracy,
double functionValueAccuracy,
int maximalOrderIn)
Construct a solver.
|
BracketingNthOrderBrentSolver(double relativeAccuracy,
double absoluteAccuracy,
int maximalOrderIn)
Construct a solver.
|
BracketingNthOrderBrentSolver(double absoluteAccuracy,
int maximalOrderIn)
Construct a solver.
|
Modifier and Type | Method and Description |
---|---|
protected double |
doSolve()
Method for implementing actual optimization algorithms in derived
classes.
|
int |
getMaximalOrder()
Get the maximal order.
|
double |
solve(int maxEval,
UnivariateFunction f,
double min,
double max,
AllowedSolution allowedSolution)
Solve for a zero in the given interval.
|
double |
solve(int maxEval,
UnivariateFunction f,
double min,
double max,
double startValue,
AllowedSolution allowedSolution)
Solve for a zero in the given interval, start at
startValue . |
computeObjectiveValue, getAbsoluteAccuracy, getEvaluations, getFunctionValueAccuracy, getMax, getMaxEvaluations, getMin, getRelativeAccuracy, getStartValue, incrementEvaluationCount, isBracketing, isSequence, setup, solve, solve, solve, verifyBracketing, verifyInterval, verifySequence
clone, equals, finalize, getClass, hashCode, notify, notifyAll, toString, wait, wait, wait
getAbsoluteAccuracy, getEvaluations, getFunctionValueAccuracy, getMaxEvaluations, getRelativeAccuracy, solve, solve, solve
public BracketingNthOrderBrentSolver()
public BracketingNthOrderBrentSolver(double absoluteAccuracy, int maximalOrderIn)
absoluteAccuracy
- Absolute accuracy.maximalOrderIn
- maximal order.NumberIsTooSmallException
- if maximal order is lower than 2public BracketingNthOrderBrentSolver(double relativeAccuracy, double absoluteAccuracy, int maximalOrderIn)
relativeAccuracy
- Relative accuracy.absoluteAccuracy
- Absolute accuracy.maximalOrderIn
- maximal order.NumberIsTooSmallException
- if maximal order is lower than 2public BracketingNthOrderBrentSolver(double relativeAccuracy, double absoluteAccuracy, double functionValueAccuracy, int maximalOrderIn)
relativeAccuracy
- Relative accuracy.absoluteAccuracy
- Absolute accuracy.functionValueAccuracy
- Function value accuracy.maximalOrderIn
- maximal order.NumberIsTooSmallException
- if maximal order is lower than 2public int getMaximalOrder()
protected double doSolve()
doSolve
in class BaseAbstractUnivariateSolver<UnivariateFunction>
public double solve(int maxEval, UnivariateFunction f, double min, double max, AllowedSolution allowedSolution)
solve
in interface BracketedUnivariateSolver<UnivariateFunction>
maxEval
- Maximum number of evaluations.f
- Function to solve.min
- Lower bound for the interval.max
- Upper bound for the interval.allowedSolution
- The kind of solutions that the root-finding algorithm may
accept as solutions.public double solve(int maxEval, UnivariateFunction f, double min, double max, double startValue, AllowedSolution allowedSolution)
startValue
.
A solver may require that the interval brackets a single zero root.
Solvers that do require bracketing should be able to handle the case
where one of the endpoints is itself a root.solve
in interface BracketedUnivariateSolver<UnivariateFunction>
maxEval
- Maximum number of evaluations.f
- Function to solve.min
- Lower bound for the interval.max
- Upper bound for the interval.startValue
- Start value to use.allowedSolution
- The kind of solutions that the root-finding algorithm may
accept as solutions.Copyright © 2019 CNES. All rights reserved.