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* http://www.apache.org/licenses/LICENSE-2.0
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package org.apache.commons.math.ode.nonstiff;
import org.apache.commons.math.ode.DerivativeException;
import org.apache.commons.math.ode.FirstOrderDifferentialEquations;
import org.apache.commons.math.ode.FirstOrderIntegrator;
import org.apache.commons.math.ode.IntegratorException;
import org.apache.commons.math.ode.TestProblem1;
import org.apache.commons.math.ode.TestProblem3;
import org.apache.commons.math.ode.TestProblem4;
import org.apache.commons.math.ode.TestProblem5;
import org.apache.commons.math.ode.TestProblemHandler;
import org.apache.commons.math.ode.events.EventHandler;
import org.apache.commons.math.ode.nonstiff.DormandPrince853Integrator;
import org.apache.commons.math.ode.sampling.DummyStepHandler;
import org.apache.commons.math.ode.sampling.StepHandler;
import org.apache.commons.math.ode.sampling.StepInterpolator;
import junit.framework.*;
public class DormandPrince853IntegratorTest
extends TestCase {
public DormandPrince853IntegratorTest(String name) {
super(name);
}
public void testMissedEndEvent() throws IntegratorException, DerivativeException {
final double t0 = 1878250320.0000029;
final double tEvent = 1878250379.9999986;
final double[] k = { 1.0e-4, 1.0e-5, 1.0e-6 };
FirstOrderDifferentialEquations ode = new FirstOrderDifferentialEquations() {
public int getDimension() {
return k.length;
}
public void computeDerivatives(double t, double[] y, double[] yDot) {
for (int i = 0; i < y.length; ++i) {
yDot[i] = k[i] * y[i];
}
}
};
DormandPrince853Integrator integrator = new DormandPrince853Integrator(0.0, 100.0,
1.0e-10, 1.0e-10);
double[] y0 = new double[k.length];
for (int i = 0; i < y0.length; ++i) {
y0[i] = i + 1;
}
double[] y = new double[k.length];
integrator.setInitialStepSize(60.0);
double finalT = integrator.integrate(ode, t0, y0, tEvent, y);
Assert.assertEquals(tEvent, finalT, 5.0e-6);
for (int i = 0; i < y.length; ++i) {
Assert.assertEquals(y0[i] * Math.exp(k[i] * (finalT - t0)), y[i], 1.0e-9);
}
integrator.setInitialStepSize(60.0);
integrator.addEventHandler(new EventHandler() {
public void resetState(double t, double[] y) {
}
public double g(double t, double[] y) {
return t - tEvent;
}
public int eventOccurred(double t, double[] y, boolean increasing) {
Assert.assertEquals(tEvent, t, 5.0e-6);
return CONTINUE;
}
}, Double.POSITIVE_INFINITY, 1.0e-20, 100);
finalT = integrator.integrate(ode, t0, y0, tEvent + 120, y);
Assert.assertEquals(tEvent + 120, finalT, 5.0e-6);
for (int i = 0; i < y.length; ++i) {
Assert.assertEquals(y0[i] * Math.exp(k[i] * (finalT - t0)), y[i], 1.0e-9);
}
}
public void testDimensionCheck() {
try {
TestProblem1 pb = new TestProblem1();
DormandPrince853Integrator integrator = new DormandPrince853Integrator(0.0, 1.0,
1.0e-10, 1.0e-10);
integrator.integrate(pb,
0.0, new double[pb.getDimension()+10],
1.0, new double[pb.getDimension()+10]);
fail("an exception should have been thrown");
} catch(DerivativeException de) {
fail("wrong exception caught");
} catch(IntegratorException ie) {
}
}
public void testNullIntervalCheck() {
try {
TestProblem1 pb = new TestProblem1();
DormandPrince853Integrator integrator = new DormandPrince853Integrator(0.0, 1.0,
1.0e-10, 1.0e-10);
integrator.integrate(pb,
0.0, new double[pb.getDimension()],
0.0, new double[pb.getDimension()]);
fail("an exception should have been thrown");
} catch(DerivativeException de) {
fail("wrong exception caught");
} catch(IntegratorException ie) {
}
}
public void testMinStep() {
try {
TestProblem1 pb = new TestProblem1();
double minStep = 0.1 * (pb.getFinalTime() - pb.getInitialTime());
double maxStep = pb.getFinalTime() - pb.getInitialTime();
double[] vecAbsoluteTolerance = { 1.0e-15, 1.0e-16 };
double[] vecRelativeTolerance = { 1.0e-15, 1.0e-16 };
FirstOrderIntegrator integ = new DormandPrince853Integrator(minStep, maxStep,
vecAbsoluteTolerance,
vecRelativeTolerance);
TestProblemHandler handler = new TestProblemHandler(pb, integ);
integ.addStepHandler(handler);
integ.integrate(pb,
pb.getInitialTime(), pb.getInitialState(),
pb.getFinalTime(), new double[pb.getDimension()]);
fail("an exception should have been thrown");
} catch(DerivativeException de) {
fail("wrong exception caught");
} catch(IntegratorException ie) {
}
}
public void testIncreasingTolerance()
throws DerivativeException, IntegratorException {
int previousCalls = Integer.MAX_VALUE;
for (int i = -12; i < -2; ++i) {
TestProblem1 pb = new TestProblem1();
double minStep = 0;
double maxStep = pb.getFinalTime() - pb.getInitialTime();
double scalAbsoluteTolerance = Math.pow(10.0, i);
double scalRelativeTolerance = 0.01 * scalAbsoluteTolerance;
FirstOrderIntegrator integ = new DormandPrince853Integrator(minStep, maxStep,
scalAbsoluteTolerance,
scalRelativeTolerance);
TestProblemHandler handler = new TestProblemHandler(pb, integ);
integ.addStepHandler(handler);
integ.integrate(pb,
pb.getInitialTime(), pb.getInitialState(),
pb.getFinalTime(), new double[pb.getDimension()]);
// the 1.3 factor is only valid for this test
// and has been obtained from trial and error
// there is no general relation between local and global errors
assertTrue(handler.getMaximalValueError() < (1.3 * scalAbsoluteTolerance));
assertEquals(0, handler.getMaximalTimeError(), 1.0e-12);
int calls = pb.getCalls();
assertEquals(integ.getEvaluations(), calls);
assertTrue(calls <= previousCalls);
previousCalls = calls;
}
}
public void testBackward()
throws DerivativeException, IntegratorException {
TestProblem5 pb = new TestProblem5();
double minStep = 0;
double maxStep = pb.getFinalTime() - pb.getInitialTime();
double scalAbsoluteTolerance = 1.0e-8;
double scalRelativeTolerance = 0.01 * scalAbsoluteTolerance;
FirstOrderIntegrator integ = new DormandPrince853Integrator(minStep, maxStep,
scalAbsoluteTolerance,
scalRelativeTolerance);
TestProblemHandler handler = new TestProblemHandler(pb, integ);
integ.addStepHandler(handler);
integ.integrate(pb, pb.getInitialTime(), pb.getInitialState(),
pb.getFinalTime(), new double[pb.getDimension()]);
assertTrue(handler.getLastError() < 8.1e-8);
assertTrue(handler.getMaximalValueError() < 1.1e-7);
assertEquals(0, handler.getMaximalTimeError(), 1.0e-12);
assertEquals("Dormand-Prince 8 (5, 3)", integ.getName());
}
public void testEvents()
throws DerivativeException, IntegratorException {
TestProblem4 pb = new TestProblem4();
double minStep = 0;
double maxStep = pb.getFinalTime() - pb.getInitialTime();
double scalAbsoluteTolerance = 1.0e-9;
double scalRelativeTolerance = 0.01 * scalAbsoluteTolerance;
FirstOrderIntegrator integ = new DormandPrince853Integrator(minStep, maxStep,
scalAbsoluteTolerance,
scalRelativeTolerance);
TestProblemHandler handler = new TestProblemHandler(pb, integ);
integ.addStepHandler(handler);
EventHandler[] functions = pb.getEventsHandlers();
for (int l = 0; l < functions.length; ++l) {
integ.addEventHandler(functions[l],
Double.POSITIVE_INFINITY, 1.0e-8 * maxStep, 1000);
}
assertEquals(functions.length, integ.getEventHandlers().size());
integ.integrate(pb,
pb.getInitialTime(), pb.getInitialState(),
pb.getFinalTime(), new double[pb.getDimension()]);
assertTrue(handler.getMaximalValueError() < 5.0e-8);
assertEquals(0, handler.getMaximalTimeError(), 1.0e-12);
assertEquals(12.0, handler.getLastTime(), 1.0e-8 * maxStep);
integ.clearEventHandlers();
assertEquals(0, integ.getEventHandlers().size());
}
public void testKepler()
throws DerivativeException, IntegratorException {
final TestProblem3 pb = new TestProblem3(0.9);
double minStep = 0;
double maxStep = pb.getFinalTime() - pb.getInitialTime();
double scalAbsoluteTolerance = 1.0e-8;
double scalRelativeTolerance = scalAbsoluteTolerance;
FirstOrderIntegrator integ = new DormandPrince853Integrator(minStep, maxStep,
scalAbsoluteTolerance,
scalRelativeTolerance);
integ.addStepHandler(new KeplerHandler(pb));
integ.integrate(pb,
pb.getInitialTime(), pb.getInitialState(),
pb.getFinalTime(), new double[pb.getDimension()]);
assertEquals(integ.getEvaluations(), pb.getCalls());
assertTrue(pb.getCalls() < 3300);
}
public void testVariableSteps()
throws DerivativeException, IntegratorException {
final TestProblem3 pb = new TestProblem3(0.9);
double minStep = 0;
double maxStep = pb.getFinalTime() - pb.getInitialTime();
double scalAbsoluteTolerance = 1.0e-8;
double scalRelativeTolerance = scalAbsoluteTolerance;
FirstOrderIntegrator integ = new DormandPrince853Integrator(minStep, maxStep,
scalAbsoluteTolerance,
scalRelativeTolerance);
integ.addStepHandler(new VariableHandler());
double stopTime = integ.integrate(pb,
pb.getInitialTime(), pb.getInitialState(),
pb.getFinalTime(), new double[pb.getDimension()]);
assertEquals(pb.getFinalTime(), stopTime, 1.0e-10);
assertEquals("Dormand-Prince 8 (5, 3)", integ.getName());
}
public void testNoDenseOutput()
throws DerivativeException, IntegratorException {
TestProblem1 pb1 = new TestProblem1();
TestProblem1 pb2 = pb1.copy();
double minStep = 0.1 * (pb1.getFinalTime() - pb1.getInitialTime());
double maxStep = pb1.getFinalTime() - pb1.getInitialTime();
double scalAbsoluteTolerance = 1.0e-4;
double scalRelativeTolerance = 1.0e-4;
FirstOrderIntegrator integ = new DormandPrince853Integrator(minStep, maxStep,
scalAbsoluteTolerance,
scalRelativeTolerance);
integ.addStepHandler(DummyStepHandler.getInstance());
integ.integrate(pb1,
pb1.getInitialTime(), pb1.getInitialState(),
pb1.getFinalTime(), new double[pb1.getDimension()]);
int callsWithoutDenseOutput = pb1.getCalls();
assertEquals(integ.getEvaluations(), callsWithoutDenseOutput);
integ.addStepHandler(new InterpolatingStepHandler());
integ.integrate(pb2,
pb2.getInitialTime(), pb2.getInitialState(),
pb2.getFinalTime(), new double[pb2.getDimension()]);
int callsWithDenseOutput = pb2.getCalls();
assertEquals(integ.getEvaluations(), callsWithDenseOutput);
assertTrue(callsWithDenseOutput > callsWithoutDenseOutput);
}
public void testUnstableDerivative()
throws DerivativeException, IntegratorException {
final StepProblem stepProblem = new StepProblem(0.0, 1.0, 2.0);
FirstOrderIntegrator integ =
new DormandPrince853Integrator(0.1, 10, 1.0e-12, 0.0);
integ.addEventHandler(stepProblem, 1.0, 1.0e-12, 1000);
double[] y = { Double.NaN };
integ.integrate(stepProblem, 0.0, new double[] { 0.0 }, 10.0, y);
assertEquals(8.0, y[0], 1.0e-12);
}
private static class KeplerHandler implements StepHandler {
public KeplerHandler(TestProblem3 pb) {
this.pb = pb;
reset();
}
public boolean requiresDenseOutput() {
return true;
}
public void reset() {
nbSteps = 0;
maxError = 0;
}
public void handleStep(StepInterpolator interpolator,
boolean isLast)
throws DerivativeException {
++nbSteps;
for (int a = 1; a < 10; ++a) {
double prev = interpolator.getPreviousTime();
double curr = interpolator.getCurrentTime();
double interp = ((10 - a) * prev + a * curr) / 10;
interpolator.setInterpolatedTime(interp);
double[] interpolatedY = interpolator.getInterpolatedState ();
double[] theoreticalY = pb.computeTheoreticalState(interpolator.getInterpolatedTime());
double dx = interpolatedY[0] - theoreticalY[0];
double dy = interpolatedY[1] - theoreticalY[1];
double error = dx * dx + dy * dy;
if (error > maxError) {
maxError = error;
}
}
if (isLast) {
assertTrue(maxError < 2.4e-10);
assertTrue(nbSteps < 150);
}
}
private int nbSteps;
private double maxError;
private TestProblem3 pb;
}
private static class VariableHandler implements StepHandler {
public VariableHandler() {
reset();
}
public boolean requiresDenseOutput() {
return false;
}
public void reset() {
firstTime = true;
minStep = 0;
maxStep = 0;
}
public void handleStep(StepInterpolator interpolator,
boolean isLast) {
double step = Math.abs(interpolator.getCurrentTime()
- interpolator.getPreviousTime());
if (firstTime) {
minStep = Math.abs(step);
maxStep = minStep;
firstTime = false;
} else {
if (step < minStep) {
minStep = step;
}
if (step > maxStep) {
maxStep = step;
}
}
if (isLast) {
assertTrue(minStep < (1.0 / 100.0));
assertTrue(maxStep > (1.0 / 2.0));
}
}
private boolean firstTime = true;
private double minStep = 0;
private double maxStep = 0;
}
private static class InterpolatingStepHandler implements StepHandler {
public boolean requiresDenseOutput() {
return true;
}
public void reset() {
}
public void handleStep(StepInterpolator interpolator,
boolean isLast)
throws DerivativeException {
double prev = interpolator.getPreviousTime();
double curr = interpolator.getCurrentTime();
interpolator.setInterpolatedTime(0.5*(prev + curr));
}
}
}