src/main/java/org/apache/commons/math/distribution/HypergeometricDistributionImpl.java - platform/external/apache-commons-math - Git at Google

 /*
  * 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.math.distribution;

 import java.io.Serializable;

 import org.apache.commons.math.MathRuntimeException;
 import org.apache.commons.math.exception.util.LocalizedFormats;
 import org.apache.commons.math.util.MathUtils;
 import org.apache.commons.math.util.FastMath;

 /**
  * The default implementation of {@link HypergeometricDistribution}.
  *
  * @version $Revision: 1054524 $ $Date: 2011-01-03 05:59:18 +0100 (lun. 03 janv. 2011) $
  */
 public class HypergeometricDistributionImpl extends AbstractIntegerDistribution
         implements HypergeometricDistribution, Serializable {

     /** Serializable version identifier */
     private static final long serialVersionUID = -436928820673516179L;

     /** The number of successes in the population. */
     private int numberOfSuccesses;

     /** The population size. */
     private int populationSize;

     /** The sample size. */
     private int sampleSize;

     /**
      * Construct a new hypergeometric distribution with the given the population
      * size, the number of successes in the population, and the sample size.
      *
      * @param populationSize the population size.
      * @param numberOfSuccesses number of successes in the population.
      * @param sampleSize the sample size.
      */
     public HypergeometricDistributionImpl(int populationSize,
             int numberOfSuccesses, int sampleSize) {
         super();
         if (numberOfSuccesses > populationSize) {
             throw MathRuntimeException
                     .createIllegalArgumentException(
                             LocalizedFormats.NUMBER_OF_SUCCESS_LARGER_THAN_POPULATION_SIZE,
                             numberOfSuccesses, populationSize);
         }
         if (sampleSize > populationSize) {
             throw MathRuntimeException
                     .createIllegalArgumentException(
                             LocalizedFormats.SAMPLE_SIZE_LARGER_THAN_POPULATION_SIZE,
                             sampleSize, populationSize);
         }

         setPopulationSizeInternal(populationSize);
         setSampleSizeInternal(sampleSize);
         setNumberOfSuccessesInternal(numberOfSuccesses);
     }

     /**
      * For this distribution, X, this method returns P(X &le; x).
      *
      * @param x the value at which the PDF is evaluated.
      * @return PDF for this distribution.
      */
     @Override
     public double cumulativeProbability(int x) {
         double ret;

         int[] domain = getDomain(populationSize, numberOfSuccesses, sampleSize);
         if (x < domain[0]) {
             ret = 0.0;
         } else if (x >= domain[1]) {
             ret = 1.0;
         } else {
             ret = innerCumulativeProbability(domain[0], x, 1, populationSize,
                                              numberOfSuccesses, sampleSize);
         }

         return ret;
     }

     /**
      * Return the domain for the given hypergeometric distribution parameters.
      *
      * @param n the population size.
      * @param m number of successes in the population.
      * @param k the sample size.
      * @return a two element array containing the lower and upper bounds of the
      *         hypergeometric distribution.
      */
     private int[] getDomain(int n, int m, int k) {
         return new int[] { getLowerDomain(n, m, k), getUpperDomain(m, k) };
     }

     /**
      * Access the domain value lower bound, based on <code>p</code>, used to
      * bracket a PDF root.
      *
      * @param p the desired probability for the critical value
      * @return domain value lower bound, i.e. P(X &lt; <i>lower bound</i>) &lt;
      *         <code>p</code>
      */
     @Override
     protected int getDomainLowerBound(double p) {
         return getLowerDomain(populationSize, numberOfSuccesses, sampleSize);
     }

     /**
      * Access the domain value upper bound, based on <code>p</code>, used to
      * bracket a PDF root.
      *
      * @param p the desired probability for the critical value
      * @return domain value upper bound, i.e. P(X &lt; <i>upper bound</i>) &gt;
      *         <code>p</code>
      */
     @Override
     protected int getDomainUpperBound(double p) {
         return getUpperDomain(sampleSize, numberOfSuccesses);
     }

     /**
      * Return the lowest domain value for the given hypergeometric distribution
      * parameters.
      *
      * @param n the population size.
      * @param m number of successes in the population.
      * @param k the sample size.
      * @return the lowest domain value of the hypergeometric distribution.
      */
     private int getLowerDomain(int n, int m, int k) {
         return FastMath.max(0, m - (n - k));
     }

     /**
      * Access the number of successes.
      *
      * @return the number of successes.
      */
     public int getNumberOfSuccesses() {
         return numberOfSuccesses;
     }

     /**
      * Access the population size.
      *
      * @return the population size.
      */
     public int getPopulationSize() {
         return populationSize;
     }

     /**
      * Access the sample size.
      *
      * @return the sample size.
      */
     public int getSampleSize() {
         return sampleSize;
     }

     /**
      * Return the highest domain value for the given hypergeometric distribution
      * parameters.
      *
      * @param m number of successes in the population.
      * @param k the sample size.
      * @return the highest domain value of the hypergeometric distribution.
      */
     private int getUpperDomain(int m, int k) {
         return FastMath.min(k, m);
     }

     /**
      * For this distribution, X, this method returns P(X = x).
      *
      * @param x the value at which the PMF is evaluated.
      * @return PMF for this distribution.
      */
     public double probability(int x) {
         double ret;

         int[] domain = getDomain(populationSize, numberOfSuccesses, sampleSize);
         if (x < domain[0] || x > domain[1]) {
             ret = 0.0;
         } else {
             double p = (double) sampleSize / (double) populationSize;
             double q = (double) (populationSize - sampleSize) / (double) populationSize;
             double p1 = SaddlePointExpansion.logBinomialProbability(x,
                     numberOfSuccesses, p, q);
             double p2 =
                 SaddlePointExpansion.logBinomialProbability(sampleSize - x,
                     populationSize - numberOfSuccesses, p, q);
             double p3 =
                 SaddlePointExpansion.logBinomialProbability(sampleSize, populationSize, p, q);
             ret = FastMath.exp(p1 + p2 - p3);
         }

         return ret;
     }

     /**
      * For the distribution, X, defined by the given hypergeometric distribution
      * parameters, this method returns P(X = x).
      *
      * @param n the population size.
      * @param m number of successes in the population.
      * @param k the sample size.
      * @param x the value at which the PMF is evaluated.
      * @return PMF for the distribution.
      */
     private double probability(int n, int m, int k, int x) {
         return FastMath.exp(MathUtils.binomialCoefficientLog(m, x) +
                MathUtils.binomialCoefficientLog(n - m, k - x) -
                MathUtils.binomialCoefficientLog(n, k));
     }

     /**
      * Modify the number of successes.
      *
      * @param num the new number of successes.
      * @throws IllegalArgumentException if <code>num</code> is negative.
      * @deprecated as of 2.1 (class will become immutable in 3.0)
      */
     @Deprecated
     public void setNumberOfSuccesses(int num) {
         setNumberOfSuccessesInternal(num);
     }

     /**
      * Modify the number of successes.
      *
      * @param num the new number of successes.
      * @throws IllegalArgumentException if <code>num</code> is negative.
      */
     private void setNumberOfSuccessesInternal(int num) {
         if (num < 0) {
             throw MathRuntimeException.createIllegalArgumentException(
                     LocalizedFormats.NEGATIVE_NUMBER_OF_SUCCESSES, num);
         }
         numberOfSuccesses = num;
     }

     /**
      * Modify the population size.
      *
      * @param size the new population size.
      * @throws IllegalArgumentException if <code>size</code> is not positive.
      * @deprecated as of 2.1 (class will become immutable in 3.0)
      */
     @Deprecated
     public void setPopulationSize(int size) {
         setPopulationSizeInternal(size);
     }

     /**
      * Modify the population size.
      *
      * @param size the new population size.
      * @throws IllegalArgumentException if <code>size</code> is not positive.
      */
     private void setPopulationSizeInternal(int size) {
         if (size <= 0) {
             throw MathRuntimeException.createIllegalArgumentException(
                     LocalizedFormats.NOT_POSITIVE_POPULATION_SIZE, size);
         }
         populationSize = size;
     }

     /**
      * Modify the sample size.
      *
      * @param size the new sample size.
      * @throws IllegalArgumentException if <code>size</code> is negative.
      * @deprecated as of 2.1 (class will become immutable in 3.0)
      */
     @Deprecated
     public void setSampleSize(int size) {
         setSampleSizeInternal(size);
     }
     /**
      * Modify the sample size.
      *
      * @param size the new sample size.
      * @throws IllegalArgumentException if <code>size</code> is negative.
      */
     private void setSampleSizeInternal(int size) {
         if (size < 0) {
             throw MathRuntimeException.createIllegalArgumentException(
                     LocalizedFormats.NOT_POSITIVE_SAMPLE_SIZE, size);
         }
         sampleSize = size;
     }

     /**
      * For this distribution, X, this method returns P(X &ge; x).
      *
      * @param x the value at which the CDF is evaluated.
      * @return upper tail CDF for this distribution.
      * @since 1.1
      */
     public double upperCumulativeProbability(int x) {
         double ret;

         final int[] domain = getDomain(populationSize, numberOfSuccesses, sampleSize);
         if (x < domain[0]) {
             ret = 1.0;
         } else if (x > domain[1]) {
             ret = 0.0;
         } else {
             ret = innerCumulativeProbability(domain[1], x, -1, populationSize, numberOfSuccesses, sampleSize);
         }

         return ret;
     }

     /**
      * For this distribution, X, this method returns P(x0 &le; X &le; x1). This
      * probability is computed by summing the point probabilities for the values
      * x0, x0 + 1, x0 + 2, ..., x1, in the order directed by dx.
      *
      * @param x0 the inclusive, lower bound
      * @param x1 the inclusive, upper bound
      * @param dx the direction of summation. 1 indicates summing from x0 to x1.
      *            0 indicates summing from x1 to x0.
      * @param n the population size.
      * @param m number of successes in the population.
      * @param k the sample size.
      * @return P(x0 &le; X &le; x1).
      */
     private double innerCumulativeProbability(int x0, int x1, int dx, int n,
             int m, int k) {
         double ret = probability(n, m, k, x0);
         while (x0 != x1) {
             x0 += dx;
             ret += probability(n, m, k, x0);
         }
         return ret;
     }

     /**
      * Returns the lower bound for the support for the distribution.
      *
      * For population size <code>N</code>,
      * number of successes <code>m</code>, and
      * sample size <code>n</code>,
      * the lower bound of the support is
      * <code>max(0, n + m - N)</code>
      *
      * @return lower bound of the support
      * @since 2.2
      */
     public int getSupportLowerBound() {
         return FastMath.max(0,
                 getSampleSize() + getNumberOfSuccesses() - getPopulationSize());
     }

     /**
      * Returns the upper bound for the support of the distribution.
      *
      * For number of successes <code>m</code> and
      * sample size <code>n</code>,
      * the upper bound of the support is
      * <code>min(m, n)</code>
      *
      * @return upper bound of the support
      * @since 2.2
      */
     public int getSupportUpperBound() {
         return FastMath.min(getNumberOfSuccesses(), getSampleSize());
     }

     /**
      * Returns the mean.
      *
      * For population size <code>N</code>,
      * number of successes <code>m</code>, and
      * sample size <code>n</code>, the mean is
      * <code>n * m / N</code>
      *
      * @return the mean
      * @since 2.2
      */
     protected double getNumericalMean() {
         return (double)(getSampleSize() * getNumberOfSuccesses()) / (double)getPopulationSize();
     }

     /**
      * Returns the variance.
      *
      * For population size <code>N</code>,
      * number of successes <code>m</code>, and
      * sample size <code>n</code>, the variance is
      * <code>[ n * m * (N - n) * (N - m) ] / [ N^2 * (N - 1) ]</code>
      *
      * @return the variance
      * @since 2.2
      */
     public double getNumericalVariance() {
         final double N = getPopulationSize();
         final double m = getNumberOfSuccesses();
         final double n = getSampleSize();
         return ( n * m * (N - n) * (N - m) ) / ( (N*N * (N - 1)) );
     }
 }
	/*
	* 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.math.distribution;

	import java.io.Serializable;

	import org.apache.commons.math.MathRuntimeException;
	import org.apache.commons.math.exception.util.LocalizedFormats;
	import org.apache.commons.math.util.MathUtils;
	import org.apache.commons.math.util.FastMath;

	/**
	* The default implementation of {@link HypergeometricDistribution}.
	*
	* @version $Revision: 1054524 $ $Date: 2011-01-03 05:59:18 +0100 (lun. 03 janv. 2011) $
	*/
	public class HypergeometricDistributionImpl extends AbstractIntegerDistribution
	implements HypergeometricDistribution, Serializable {

	/** Serializable version identifier */
	private static final long serialVersionUID = -436928820673516179L;

	/** The number of successes in the population. */
	private int numberOfSuccesses;

	/** The population size. */
	private int populationSize;

	/** The sample size. */
	private int sampleSize;

	/**
	* Construct a new hypergeometric distribution with the given the population
	* size, the number of successes in the population, and the sample size.
	*
	* @param populationSize the population size.
	* @param numberOfSuccesses number of successes in the population.
	* @param sampleSize the sample size.
	*/
	public HypergeometricDistributionImpl(int populationSize,
	int numberOfSuccesses, int sampleSize) {
	super();
	if (numberOfSuccesses > populationSize) {
	throw MathRuntimeException
	.createIllegalArgumentException(
	LocalizedFormats.NUMBER_OF_SUCCESS_LARGER_THAN_POPULATION_SIZE,
	numberOfSuccesses, populationSize);
	}
	if (sampleSize > populationSize) {
	throw MathRuntimeException
	.createIllegalArgumentException(
	LocalizedFormats.SAMPLE_SIZE_LARGER_THAN_POPULATION_SIZE,
	sampleSize, populationSize);
	}

	setPopulationSizeInternal(populationSize);
	setSampleSizeInternal(sampleSize);
	setNumberOfSuccessesInternal(numberOfSuccesses);
	}

	/**
	* For this distribution, X, this method returns P(X ≤ x).
	*
	* @param x the value at which the PDF is evaluated.
	* @return PDF for this distribution.
	*/
	@Override
	public double cumulativeProbability(int x) {
	double ret;

	int[] domain = getDomain(populationSize, numberOfSuccesses, sampleSize);
	if (x < domain[0]) {
	ret = 0.0;
	} else if (x >= domain[1]) {
	ret = 1.0;
	} else {
	ret = innerCumulativeProbability(domain[0], x, 1, populationSize,
	numberOfSuccesses, sampleSize);
	}

	return ret;
	}

	/**
	* Return the domain for the given hypergeometric distribution parameters.
	*
	* @param n the population size.
	* @param m number of successes in the population.
	* @param k the sample size.
	* @return a two element array containing the lower and upper bounds of the
	* hypergeometric distribution.
	*/
	private int[] getDomain(int n, int m, int k) {
	return new int[] { getLowerDomain(n, m, k), getUpperDomain(m, k) };
	}

	/**
	* Access the domain value lower bound, based on <code>p</code>, used to
	* bracket a PDF root.
	*
	* @param p the desired probability for the critical value
	* @return domain value lower bound, i.e. P(X < <i>lower bound</i>) <
	* <code>p</code>
	*/
	@Override
	protected int getDomainLowerBound(double p) {
	return getLowerDomain(populationSize, numberOfSuccesses, sampleSize);
	}

	/**
	* Access the domain value upper bound, based on <code>p</code>, used to
	* bracket a PDF root.
	*
	* @param p the desired probability for the critical value
	* @return domain value upper bound, i.e. P(X < <i>upper bound</i>) >
	* <code>p</code>
	*/
	@Override
	protected int getDomainUpperBound(double p) {
	return getUpperDomain(sampleSize, numberOfSuccesses);
	}

	/**
	* Return the lowest domain value for the given hypergeometric distribution
	* parameters.
	*
	* @param n the population size.
	* @param m number of successes in the population.
	* @param k the sample size.
	* @return the lowest domain value of the hypergeometric distribution.
	*/
	private int getLowerDomain(int n, int m, int k) {
	return FastMath.max(0, m - (n - k));
	}

	/**
	* Access the number of successes.
	*
	* @return the number of successes.
	*/
	public int getNumberOfSuccesses() {
	return numberOfSuccesses;
	}

	/**
	* Access the population size.
	*
	* @return the population size.
	*/
	public int getPopulationSize() {
	return populationSize;
	}

	/**
	* Access the sample size.
	*
	* @return the sample size.
	*/
	public int getSampleSize() {
	return sampleSize;
	}

	/**
	* Return the highest domain value for the given hypergeometric distribution
	* parameters.
	*
	* @param m number of successes in the population.
	* @param k the sample size.
	* @return the highest domain value of the hypergeometric distribution.
	*/
	private int getUpperDomain(int m, int k) {
	return FastMath.min(k, m);
	}

	/**
	* For this distribution, X, this method returns P(X = x).
	*
	* @param x the value at which the PMF is evaluated.
	* @return PMF for this distribution.
	*/
	public double probability(int x) {
	double ret;

	int[] domain = getDomain(populationSize, numberOfSuccesses, sampleSize);
	if (x < domain[0] \|\| x > domain[1]) {
	ret = 0.0;
	} else {
	double p = (double) sampleSize / (double) populationSize;
	double q = (double) (populationSize - sampleSize) / (double) populationSize;
	double p1 = SaddlePointExpansion.logBinomialProbability(x,
	numberOfSuccesses, p, q);
	double p2 =
	SaddlePointExpansion.logBinomialProbability(sampleSize - x,
	populationSize - numberOfSuccesses, p, q);
	double p3 =
	SaddlePointExpansion.logBinomialProbability(sampleSize, populationSize, p, q);
	ret = FastMath.exp(p1 + p2 - p3);
	}

	return ret;
	}

	/**
	* For the distribution, X, defined by the given hypergeometric distribution
	* parameters, this method returns P(X = x).
	*
	* @param n the population size.
	* @param m number of successes in the population.
	* @param k the sample size.
	* @param x the value at which the PMF is evaluated.
	* @return PMF for the distribution.
	*/
	private double probability(int n, int m, int k, int x) {
	return FastMath.exp(MathUtils.binomialCoefficientLog(m, x) +
	MathUtils.binomialCoefficientLog(n - m, k - x) -
	MathUtils.binomialCoefficientLog(n, k));
	}

	/**
	* Modify the number of successes.
	*
	* @param num the new number of successes.
	* @throws IllegalArgumentException if <code>num</code> is negative.
	* @deprecated as of 2.1 (class will become immutable in 3.0)
	*/
	@Deprecated
	public void setNumberOfSuccesses(int num) {
	setNumberOfSuccessesInternal(num);
	}

	/**
	* Modify the number of successes.
	*
	* @param num the new number of successes.
	* @throws IllegalArgumentException if <code>num</code> is negative.
	*/
	private void setNumberOfSuccessesInternal(int num) {
	if (num < 0) {
	throw MathRuntimeException.createIllegalArgumentException(
	LocalizedFormats.NEGATIVE_NUMBER_OF_SUCCESSES, num);
	}
	numberOfSuccesses = num;
	}

	/**
	* Modify the population size.
	*
	* @param size the new population size.
	* @throws IllegalArgumentException if <code>size</code> is not positive.
	* @deprecated as of 2.1 (class will become immutable in 3.0)
	*/
	@Deprecated
	public void setPopulationSize(int size) {
	setPopulationSizeInternal(size);
	}

	/**
	* Modify the population size.
	*
	* @param size the new population size.
	* @throws IllegalArgumentException if <code>size</code> is not positive.
	*/
	private void setPopulationSizeInternal(int size) {
	if (size <= 0) {
	throw MathRuntimeException.createIllegalArgumentException(
	LocalizedFormats.NOT_POSITIVE_POPULATION_SIZE, size);
	}
	populationSize = size;
	}

	/**
	* Modify the sample size.
	*
	* @param size the new sample size.
	* @throws IllegalArgumentException if <code>size</code> is negative.
	* @deprecated as of 2.1 (class will become immutable in 3.0)
	*/
	@Deprecated
	public void setSampleSize(int size) {
	setSampleSizeInternal(size);
	}
	/**
	* Modify the sample size.
	*
	* @param size the new sample size.
	* @throws IllegalArgumentException if <code>size</code> is negative.
	*/
	private void setSampleSizeInternal(int size) {
	if (size < 0) {
	throw MathRuntimeException.createIllegalArgumentException(
	LocalizedFormats.NOT_POSITIVE_SAMPLE_SIZE, size);
	}
	sampleSize = size;
	}

	/**
	* For this distribution, X, this method returns P(X ≥ x).
	*
	* @param x the value at which the CDF is evaluated.
	* @return upper tail CDF for this distribution.
	* @since 1.1
	*/
	public double upperCumulativeProbability(int x) {
	double ret;

	final int[] domain = getDomain(populationSize, numberOfSuccesses, sampleSize);
	if (x < domain[0]) {
	ret = 1.0;
	} else if (x > domain[1]) {
	ret = 0.0;
	} else {
	ret = innerCumulativeProbability(domain[1], x, -1, populationSize, numberOfSuccesses, sampleSize);
	}

	return ret;
	}

	/**
	* For this distribution, X, this method returns P(x0 ≤ X ≤ x1). This
	* probability is computed by summing the point probabilities for the values
	* x0, x0 + 1, x0 + 2, ..., x1, in the order directed by dx.
	*
	* @param x0 the inclusive, lower bound
	* @param x1 the inclusive, upper bound
	* @param dx the direction of summation. 1 indicates summing from x0 to x1.
	* 0 indicates summing from x1 to x0.
	* @param n the population size.
	* @param m number of successes in the population.
	* @param k the sample size.
	* @return P(x0 ≤ X ≤ x1).
	*/
	private double innerCumulativeProbability(int x0, int x1, int dx, int n,
	int m, int k) {
	double ret = probability(n, m, k, x0);
	while (x0 != x1) {
	x0 += dx;
	ret += probability(n, m, k, x0);
	}
	return ret;
	}

	/**
	* Returns the lower bound for the support for the distribution.
	*
	* For population size <code>N</code>,
	* number of successes <code>m</code>, and
	* sample size <code>n</code>,
	* the lower bound of the support is
	* <code>max(0, n + m - N)</code>
	*
	* @return lower bound of the support
	* @since 2.2
	*/
	public int getSupportLowerBound() {
	return FastMath.max(0,
	getSampleSize() + getNumberOfSuccesses() - getPopulationSize());
	}

	/**
	* Returns the upper bound for the support of the distribution.
	*
	* For number of successes <code>m</code> and
	* sample size <code>n</code>,
	* the upper bound of the support is
	* <code>min(m, n)</code>
	*
	* @return upper bound of the support
	* @since 2.2
	*/
	public int getSupportUpperBound() {
	return FastMath.min(getNumberOfSuccesses(), getSampleSize());
	}

	/**
	* Returns the mean.
	*
	* For population size <code>N</code>,
	* number of successes <code>m</code>, and
	* sample size <code>n</code>, the mean is
	* <code>n * m / N</code>
	*
	* @return the mean
	* @since 2.2
	*/
	protected double getNumericalMean() {
	return (double)(getSampleSize() * getNumberOfSuccesses()) / (double)getPopulationSize();
	}

	/**
	* Returns the variance.
	*
	* For population size <code>N</code>,
	* number of successes <code>m</code>, and
	* sample size <code>n</code>, the variance is
	* <code>[ n * m * (N - n) * (N - m) ] / [ N^2 * (N - 1) ]</code>
	*
	* @return the variance
	* @since 2.2
	*/
	public double getNumericalVariance() {
	final double N = getPopulationSize();
	final double m = getNumberOfSuccesses();
	final double n = getSampleSize();
	return ( n * m * (N - n) * (N - m) ) / ( (NN (N - 1)) );
	}
	}