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/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

package org.apache.commons.math3.ode.nonstiff;

import org.apache.commons.math3.Field;
import org.apache.commons.math3.RealFieldElement;
import org.apache.commons.math3.ode.FieldEquationsMapper;
import org.apache.commons.math3.ode.FieldODEStateAndDerivative;


This class implements a step interpolator for the Gill fourth
order Runge-Kutta integrator.

This interpolator allows to compute dense output inside the last
step computed. The interpolation equation is consistent with the
integration scheme :

    
  
  • Using reference point at step start:
    
  y(tn + θ h) = y (tn)
                   + θ (h/6) [ (6 - 9 θ + 4 θ2) y'1
                                   + (    6 θ - 4 θ2) ((1-1/√2) y'2 + (1+1/√2)) y'3)
                                   + (  - 3 θ + 4 θ2) y'4
                                   ]
  
    • 
  
  • Using reference point at step start:
    
  y(tn + θ h) = y (tn + h)
                   - (1 - θ) (h/6) [ (1 - 5 θ + 4 θ2) y'1
                                         + (2 + 2 θ - 4 θ2) ((1-1/√2) y'2 + (1+1/√2)) y'3)
                                         + (1 +   θ + 4 θ2) y'4
                                         ]
  
    • 




where θ belongs to [0 ; 1] and where y'1 to y'4
are the four evaluations of the derivatives already computed during
the step.


Type parameters:
  • <T> – the type of the field elements
See Also:
  • GillFieldIntegrator
Since:3.6
/**
 * This class implements a step interpolator for the Gill fourth
 * order Runge-Kutta integrator.
 *
 * <p>This interpolator allows to compute dense output inside the last
 * step computed. The interpolation equation is consistent with the
 * integration scheme :
 * <ul>
 *   <li>Using reference point at step start:<br>
 *   y(t<sub>n</sub> + &theta; h) = y (t<sub>n</sub>)
 *                    + &theta; (h/6) [ (6 - 9 &theta; + 4 &theta;<sup>2</sup>) y'<sub>1</sub>
 *                                    + (    6 &theta; - 4 &theta;<sup>2</sup>) ((1-1/&radic;2) y'<sub>2</sub> + (1+1/&radic;2)) y'<sub>3</sub>)
 *                                    + (  - 3 &theta; + 4 &theta;<sup>2</sup>) y'<sub>4</sub>
 *                                    ]
 *   </li>
 *   <li>Using reference point at step start:<br>
 *   y(t<sub>n</sub> + &theta; h) = y (t<sub>n</sub> + h)
 *                    - (1 - &theta;) (h/6) [ (1 - 5 &theta; + 4 &theta;<sup>2</sup>) y'<sub>1</sub>
 *                                          + (2 + 2 &theta; - 4 &theta;<sup>2</sup>) ((1-1/&radic;2) y'<sub>2</sub> + (1+1/&radic;2)) y'<sub>3</sub>)
 *                                          + (1 +   &theta; + 4 &theta;<sup>2</sup>) y'<sub>4</sub>
 *                                          ]
 *   </li>
 * </ul>
 * </p>
 * where &theta; belongs to [0 ; 1] and where y'<sub>1</sub> to y'<sub>4</sub>
 * are the four evaluations of the derivatives already computed during
 * the step.</p>
 *
 * @see GillFieldIntegrator
 * @param <T> the type of the field elements
 * @since 3.6
 */

class GillFieldStepInterpolator<T extends RealFieldElement<T>>
  extends RungeKuttaFieldStepInterpolator<T> {

    
First Gill coefficient. 
/** First Gill coefficient. */
    private final T one_minus_inv_sqrt_2;

    
Second Gill coefficient. 
/** Second Gill coefficient. */
    private final T one_plus_inv_sqrt_2;

    
Simple constructor.

Params:
  • field – field to which the time and state vector elements belong
  • forward – integration direction indicator
  • yDotK – slopes at the intermediate points
  • globalPreviousState – start of the global step
  • globalCurrentState – end of the global step
  • softPreviousState – start of the restricted step
  • softCurrentState – end of the restricted step
  • mapper – equations mapper for the all equations
/** Simple constructor.
     * @param field field to which the time and state vector elements belong
     * @param forward integration direction indicator
     * @param yDotK slopes at the intermediate points
     * @param globalPreviousState start of the global step
     * @param globalCurrentState end of the global step
     * @param softPreviousState start of the restricted step
     * @param softCurrentState end of the restricted step
     * @param mapper equations mapper for the all equations
     */
    GillFieldStepInterpolator(final Field<T> field, final boolean forward,
                              final T[][] yDotK,
                              final FieldODEStateAndDerivative<T> globalPreviousState,
                              final FieldODEStateAndDerivative<T> globalCurrentState,
                              final FieldODEStateAndDerivative<T> softPreviousState,
                              final FieldODEStateAndDerivative<T> softCurrentState,
                              final FieldEquationsMapper<T> mapper) {
        super(field, forward, yDotK,
              globalPreviousState, globalCurrentState, softPreviousState, softCurrentState,
              mapper);
        final T sqrt = field.getZero().add(0.5).sqrt();
        one_minus_inv_sqrt_2 = field.getOne().subtract(sqrt);
        one_plus_inv_sqrt_2  = field.getOne().add(sqrt);
    }

    
{@inheritDoc} 
/** {@inheritDoc} */
    @Override
    protected GillFieldStepInterpolator<T> create(final Field<T> newField, final boolean newForward, final T[][] newYDotK,
                                                  final FieldODEStateAndDerivative<T> newGlobalPreviousState,
                                                  final FieldODEStateAndDerivative<T> newGlobalCurrentState,
                                                  final FieldODEStateAndDerivative<T> newSoftPreviousState,
                                                  final FieldODEStateAndDerivative<T> newSoftCurrentState,
                                                  final FieldEquationsMapper<T> newMapper) {
        return new GillFieldStepInterpolator<T>(newField, newForward, newYDotK,
                                                newGlobalPreviousState, newGlobalCurrentState,
                                                newSoftPreviousState, newSoftCurrentState,
                                                newMapper);
    }

    
{@inheritDoc} 
/** {@inheritDoc} */
    @SuppressWarnings("unchecked")
    @Override
    protected FieldODEStateAndDerivative<T> computeInterpolatedStateAndDerivatives(final FieldEquationsMapper<T> mapper,
                                                                                   final T time, final T theta,
                                                                                   final T thetaH, final T oneMinusThetaH) {

        final T one        = time.getField().getOne();
        final T twoTheta   = theta.multiply(2);
        final T fourTheta2 = twoTheta.multiply(twoTheta);
        final T coeffDot1  = theta.multiply(twoTheta.subtract(3)).add(1);
        final T cDot23     = twoTheta.multiply(one.subtract(theta));
        final T coeffDot2  = cDot23.multiply(one_minus_inv_sqrt_2);
        final T coeffDot3  = cDot23.multiply(one_plus_inv_sqrt_2);
        final T coeffDot4  = theta.multiply(twoTheta.subtract(1));
        final T[] interpolatedState;
        final T[] interpolatedDerivatives;

        if (getGlobalPreviousState() != null && theta.getReal() <= 0.5) {
            final T s               = thetaH.divide(6.0);
            final T c23             = s.multiply(theta.multiply(6).subtract(fourTheta2));
            final T coeff1          = s.multiply(fourTheta2.subtract(theta.multiply(9)).add(6));
            final T coeff2          = c23.multiply(one_minus_inv_sqrt_2);
            final T coeff3          = c23.multiply(one_plus_inv_sqrt_2);
            final T coeff4          = s.multiply(fourTheta2.subtract(theta.multiply(3)));
            interpolatedState       = previousStateLinearCombination(coeff1, coeff2, coeff3, coeff4);
            interpolatedDerivatives = derivativeLinearCombination(coeffDot1, coeffDot2, coeffDot3, coeffDot4);
        } else {
            final T s      = oneMinusThetaH.divide(-6.0);
            final T c23    = s.multiply(twoTheta.add(2).subtract(fourTheta2));
            final T coeff1 = s.multiply(fourTheta2.subtract(theta.multiply(5)).add(1));
            final T coeff2 = c23.multiply(one_minus_inv_sqrt_2);
            final T coeff3 = c23.multiply(one_plus_inv_sqrt_2);
            final T coeff4 = s.multiply(fourTheta2.add(theta).add(1));
            interpolatedState       = currentStateLinearCombination(coeff1, coeff2, coeff3, coeff4);
            interpolatedDerivatives = derivativeLinearCombination(coeffDot1, coeffDot2, coeffDot3, coeffDot4);
        }

        return new FieldODEStateAndDerivative<T>(time, interpolatedState, interpolatedDerivatives);

    }

}