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Introduction

Scope

This section describes PATRIUS optimization features.

It will focus on the JOptimizer functionalities, which provides solvers for general convex optimization problems.

Javadoc

The optimization classes are available in the package fr.cnes.sirius.patrius.math.optim.

Library Javadoc
Patrius Package fr.cnes.sirius.patrius.math.optim

Links

None as of now.

Useful Documents

None as of now.

Package Overview

The optimization functionalities for joptimizer are organized in the following packages:

  • fr.cnes.sirius.patrius.math.optim.joptimizer.algebra compounds the classes with the algebra functionalities.
  • fr.cnes.sirius.patrius.math.optim.joptimizer.functions compounds the classes with the optimization functions.
  • fr.cnes.sirius.patrius.math.optim.joptimizer.optimizers compounds the classes with the optimizers.
  • fr.cnes.sirius.patrius.math.optim.joptimizer.solvers compounds the classes with the solvers.
  • fr.cnes.sirius.patrius.math.optim.joptimizer.util compounds the utility classes.

Features Description

Features descritpion for the joptimizer package.

Optimizers

The JOptimizer class implements the convex optimizer (see "S.Boyd and L.Vandenberghe, Convex Optimization").

The algorithm selection is implemented as a Chain of Responsibility pattern, and this class is the client of the chain.

The different methods implemented to solve the convex optimization problem are:

  • Interior point methods
    • PrimalDualMethod : primal-dual interior-point method.
    • LPPrimalDualMethod : primal-dual interior-point method for linear problems.
    • BarrierMethod
  • Quality constrained minimization
    • NewtonLEConstrainedFSP : linear equality constrained newton optimizer, with a feasible starting point.
    • NewtonLEConstrainedISP : linear equality constrained newton optimizer, with an infeasible starting point.
  • Unconstrained minimization
    • NewtonUnconstrained : unconstrained newton optimizer.

Optimization problem

The OptimizationRequest class has all the setting field's necessaires to define an optimization problem.

The LPOptimizationRequest is an extension of this class for linear optimization problems.

The general form of a linear problem is (1):

min(c) s.t.
A.x = b
lb <= x <= ub

The OptimizationResponse is the class with the getters and setters to set and get the response after the optimization. The LPOptimizationResponse is the extended class applied to linear problems.

Standard converter

The LPStandardConverter converts a general linear problem stated in the form (2):

min(c) s.t. 
G.x < h 
A.x = b 
lb <= x <= ub

to the (strictly)standard form:

min(c) s.t. 
A.x = b 
x >= 0

or to the (quasi)standard form (1).

Presolver

The LPPresolver implements a presolver for a linear problem in the form (1).

It applies a set of techniques to the linear programming problem before a linear programming solver solves it. This set of techniques aims at reducing the size of the LP problem by eliminating redundant constraints and variables and identifying possible infeasibility and unboundedness of the problem.

Solvers

The AbstractKKTSolver implements a solver for the KKT system:

H.v + [A]T.w = -g
A.v = -h

where H is a square and symmetric matrix.

The following classes are an extension of AbstractKKTSolver:

  • AugmentedKKTSolver (for singular H)
  • BasicKKTSolver
  • UpperDiagonalHKKTSolver (for upper diagonal H)

Functions

Different functions are implemented, all of them twice differentiable.

  • Linear functions

The LinearMultivariateRealFunction represents a function in the form of:

f(x) = q.x + r
  • Quadratic functions

The QuadraticMultivariateRealFunction represents a function in the form of:

f(x) := 1/2 x.P.x + q.x + r

where x, q ∈ R n, P is a symmetric nXn matrix and r ∈ R.

With the extended PSDQuadraticMultivariateRealFunction and PDQuadraticMultivariateRealFunction classes for P symmetric and positive semi-definite, and P symmetric and positive definite, respectively.

  • Barrier functions

The LogarithmicBarrier is the default barrier function for the barrier method algorithm.

If fi(x) are the inequalities of the problem, then the function:

Φ(x) = − ∑_i (log(−fi(x)))

Algebra

Factorization

The CholeskyFactorization implements the Cholesky L . L[T] factorization and inverse for symmetric and positive matrix:

Q = L.L[T]

with L lower-triangular.

Rescaler

The Matrix1NornRescaler calculates the matrix rescaling factors, so that the 1-norm of each row and each column of the scaled matrix asymptotically converges to one.

Getting Started

Example 1

Example of a linear problem optimized by the primal-dual interior-point method.

The problem is:

min(-100x + y) s.t.
x - y = 0
0 <= x <= 1
0 <= y <= 1

First, the definition of the variables:

final double[] c = new double[] { -100, 1 }
final double[][] a = new double[][] { { 1, -1 } }
final double[] b = new double[] { 0 }
final double[] lb = new double[] { 0, 0 }
final double[] ub = new double[] { 1, 1 }

Definition of the optimization problem by setting the variables:

final LPOptimizationRequest or = new LPOptimizationRequest()
or.setC(c)
or.setA(a)
or.setB(b)
or.setLb(lb)
or.setUb(ub)

Additional parameters (tolerance, check the solution accuracy, etc) can also be setted:

or.setCheckKKTSolutionAccuracy(true)
or.setToleranceFeas(1.E-7)
or.setTolerance(1.E-7)
or.setDumpProblem(true)
or.setRescalingDisabled(true)

Definition of the optimizer and setting the optimization problem:

LPPrimalDualMethod opt = new LPPrimalDualMethod()
opt.setLPOptimizationRequest(or)

Optimization and check that it has not failed:

final int returnCode = opt.optimize()
if (returnCode == OptimizationResponse.FAILED) {
    fail()
}

Recuperate the response and the solution:

final LPOptimizationResponse response = opt.getLPOptimizationResponse()
final double[] sol = response.getSolution()

Validation:

final RealVector cVector = new ArrayRealVector(c)
final RealVector solVector = new ArrayRealVector(sol)
final double value = cVector.dotProduct(solVector)
assertEquals(2, sol.length)
assertEquals(1, sol[0], or.getTolerance())
assertEquals(1, sol[1], or.getTolerance())
assertEquals(-99, value, or.getTolerance())

Example 2

Example of the optimization of a linear objective function with quadratic constraints.

The problem is:

min(-e.x) s.t.
1/2 x.P.x < v
x + y + z = 1
x > 0
y > 0
z > 0

Definition of the linear objective function:

final double[] e = { -0.018, -0.025, -0.01 }
final LinearMultivariateRealFunction objectiveFunction = new LinearMultivariateRealFunction(e, 0)

Definition of the quadratic and linear constraints:

final double[][] p = { { 1.68, 0.34, 0.38 }, { 0.34, 3.09, -1.59 }, { 0.38, -1.59, 1.54 } }
final double v = 0.3
final PDQuadraticMultivariateRealFunction qc0 = new PDQuadraticMultivariateRealFunction(p, null,-v)
final LinearMultivariateRealFunction lc0 = new LinearMultivariateRealFunction(new double[] { -1, 0, 0 }, 0)
final LinearMultivariateRealFunction lc1 = new LinearMultivariateRealFunction(new double[] { 0, -1, 0 }, 0)
final LinearMultivariateRealFunction lc2 = new LinearMultivariateRealFunction(new double[] { 0, 0, -1 }, 0)
final ConvexMultivariateRealFunction[] constraints = new ConvexMultivariateRealFunction[] { qc0, lc0, lc1, lc2 }

Definition of the equality constraint:

final double[][] a = {{ 1, 1, 1 }}
final double[] b = { 1 }

Definition of the optimization problem and setting the parameters:

final OptimizationRequest or = new OptimizationRequest()
or.setF0(objectiveFunction)
or.setFi(constraints)
or.setA(a)
or.setB(b)
or.setToleranceFeas(1.e-6)  // additional parameter

Definition of the optimizer and setting the optimization problem:

final JOptimizer opt = new JOptimizer()
opt.setLPOptimizationRequest(or)

Optimization and check that it has not failed:

final int returnCode = opt.optimize()
if (returnCode == OptimizationResponse.FAILED) {
    fail()
}

Recuperate the response and the solution:

final LPOptimizationResponse response = opt.getLPOptimizationResponse()
final double[] sol = response.getSolution()

Validation:

assertEquals(1., sol[0] + sol[1] + sol[2], 1.e-6)
assertTrue(sol[0] > 0)
assertTrue(sol[1] > 0)
assertTrue(sol[2] > 0)
final RealVector xVector = MatrixUtils.createRealVector(sol)
final RealMatrix pMatrix = MatrixUtils.createRealMatrix(p)
final double xPx = xVector.dotProduct(pMatrix.operate(xVector))
assertTrue(0.5 * xPx < v)

Contents

Interfaces

The interfaces related to the joptimizer are listed here :

Interface Summary Javadoc
BarrierFunction Interface for the barrier function used by a given barrier optimization method. ...
ConvexMultivariateRealFunction Interface for convex multivariate real functions. ...
MatrixRescaler An interface to classes that implement an algorithm to rescale matrices. ...
StrictlyConvexMultivariateRealFunction Interface for striclty convex multivariate real functions. ...
TwiceDifferentiableMultivariateRealFunction Interface for twice-differentiable multivariate functions. ...

Classes

The classes related to the joptimizer are listed here :

Class Summary Javadoc
AlgebraUtils Algebraic utility operations ...
CholeskyFactorization Implements the Cholesky L.L[T] factorization and inverse for symmetric and positive matrix. ...
Matrix1NornRescaler Calculates the matrix rescaling factors so that the 1-norm of each row and each column of the scaled matrix asymptotically converges to one. ...
FunctionsUtils Utility class for optimization function building. ...
LinearMultivariateRealFunction Represents a function f(x) = q.x + r. ...
LogarithmicBarrier Default barrier function for the barrier method algorithm. ...
PDQuadraticMultivariateRealFunction Extends the class QuadraticMultivariateRealFunction with P symmetric and positive definite. ...
PSDQuadraticMultivariateRealFunction Extends the class QuadraticMultivariateRealFunction with P symmetric and positive semi-definite. ...
QuadraticMultivariateRealFunction Represents a quadratic multivariate function in the form of f(x):= 1/2 x.P.x + q.x + r. ...
AbstractLPOptimizationRequestHandler Abstract class for Linear Problem Optimization Request Handler. ...
BarrierMethod Implements the Barrier Method. ...
BasicPhaseIBM Implements the Basic Phase I Method as a Barried Method. ...
BasicPhaseILPPDM Implements the Basic Phase I Method form LP problems as a Primal-Dual Method. ...
BasicPhaseIPDM Implements the Basic Phase I Method as a Primal-Dual Method. ...
JOptimizer Implements the convex optimizer. ...
LPPresolver Presolver for a linear problem. ...
LPPrimalDualMethod Implements the Primal-dual interior-point method for linear problems. ...
LPStandardConverter Converts a general LP problem into a strictly standard or quasi standard form. ...
NewtonLEConstrainedFSP Linear equality constrained newton optimizer, with feasible starting point. ...
NewtonLEConstrainedISP Linear equality constrained newton optimizer, with infeasible starting point. ...
NewtonUnconstrained Unconstrained newton optimizer. ...
OptimizationRequest Implements an optimization problem. ...
OptimizationRequestHandler Generic class for optimization process. ...
OptimizationResponse Optimization process output: stores the solution as well as an exit code. ...
PrimalDualMethod Implements a primal-dual interior-point method. ...
AbstractKKTSolver Abstract class for solving KKT systems. ...
AugmentedKKTSolver Extension of AbstractKKTSolver for singular matrix. ...
BasicKKTSolver Extension of AbstractKKTSolver for the basic solver. ...
UpperDiagonalHKKTSolver Extends the class AbstractKKTSolver for upper diagonal matrix. ...
ArrayUtils Class offering operations on arrays, primitive arrays (like int[]) and primitive wrapper arrays (like Integer[]). ...
MutableInt A mutable (int) wrapper. ...
Utils Utility class. ...