Subversion Repositories eFlore/Applications.cel

<?php

/**

 * PHPExcel

 *

 * Copyright (c) 2006 - 2013 PHPExcel

 *

 * This library is free software; you can redistribute it and/or

 * modify it under the terms of the GNU Lesser General Public

 * License as published by the Free Software Foundation; either

 * version 2.1 of the License, or (at your option) any later version.

 *

 * This library is distributed in the hope that it will be useful,

 * but WITHOUT ANY WARRANTY; without even the implied warranty of

 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU

 * Lesser General Public License for more details.

 *

 * You should have received a copy of the GNU Lesser General Public

 * License along with this library; if not, write to the Free Software

 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA

 *

 * @category	PHPExcel

 * @package		PHPExcel_Calculation

 * @copyright	Copyright (c) 2006 - 2013 PHPExcel (http://www.codeplex.com/PHPExcel)

 * @license		http://www.gnu.org/licenses/old-licenses/lgpl-2.1.txt	LGPL

 * @version		##VERSION##, ##DATE##

 */

/** PHPExcel root directory */

if (!defined('PHPEXCEL_ROOT')) {

	/**

	 * @ignore

	 */

	define('PHPEXCEL_ROOT', dirname(__FILE__) . '/../../');

	require(PHPEXCEL_ROOT . 'PHPExcel/Autoloader.php');

}

require_once PHPEXCEL_ROOT . 'PHPExcel/Shared/trend/trendClass.php';

/** LOG_GAMMA_X_MAX_VALUE */

define('LOG_GAMMA_X_MAX_VALUE', 2.55e305);

/** XMININ */

define('XMININ', 2.23e-308);

/** EPS */

define('EPS', 2.22e-16);

/** SQRT2PI */

define('SQRT2PI', 2.5066282746310005024157652848110452530069867406099);

/**

 * PHPExcel_Calculation_Statistical

 *

 * @category	PHPExcel

 * @package		PHPExcel_Calculation

 * @copyright	Copyright (c) 2006 - 2013 PHPExcel (http://www.codeplex.com/PHPExcel)

 */

class PHPExcel_Calculation_Statistical {

	private static function _checkTrendArrays(&$array1,&$array2) {

		if (!is_array($array1)) { $array1 = array($array1); }

		if (!is_array($array2)) { $array2 = array($array2); }

		$array1 = PHPExcel_Calculation_Functions::flattenArray($array1);

		$array2 = PHPExcel_Calculation_Functions::flattenArray($array2);

		foreach($array1 as $key => $value) {

			if ((is_bool($value)) || (is_string($value)) || (is_null($value))) {

				unset($array1[$key]);

				unset($array2[$key]);

			}

		}

		foreach($array2 as $key => $value) {

			if ((is_bool($value)) || (is_string($value)) || (is_null($value))) {

				unset($array1[$key]);

				unset($array2[$key]);

			}

		}

		$array1 = array_merge($array1);

		$array2 = array_merge($array2);

		return True;

	}	//	function _checkTrendArrays()

	/**

	 * Beta function.

	 *

	 * @author Jaco van Kooten

	 *

	 * @param p require p>0

	 * @param q require q>0

	 * @return 0 if p<=0, q<=0 or p+q>2.55E305 to avoid errors and over/underflow

	 */

	private static function _beta($p, $q) {

		if ($p <= 0.0 || $q <= 0.0 || ($p + $q) > LOG_GAMMA_X_MAX_VALUE) {

			return 0.0;

		} else {

			return exp(self::_logBeta($p, $q));

		}

	}	//	function _beta()

	/**

	 * Incomplete beta function

	 *

	 * @author Jaco van Kooten

	 * @author Paul Meagher

	 *

	 * The computation is based on formulas from Numerical Recipes, Chapter 6.4 (W.H. Press et al, 1992).

	 * @param x require 0<=x<=1

	 * @param p require p>0

	 * @param q require q>0

	 * @return 0 if x<0, p<=0, q<=0 or p+q>2.55E305 and 1 if x>1 to avoid errors and over/underflow

	 */

	private static function _incompleteBeta($x, $p, $q) {

		if ($x <= 0.0) {

			return 0.0;

		} elseif ($x >= 1.0) {

			return 1.0;

		} elseif (($p <= 0.0) || ($q <= 0.0) || (($p + $q) > LOG_GAMMA_X_MAX_VALUE)) {

			return 0.0;

		}

		$beta_gam = exp((0 - self::_logBeta($p, $q)) + $p * log($x) + $q * log(1.0 - $x));

		if ($x < ($p + 1.0) / ($p + $q + 2.0)) {

			return $beta_gam * self::_betaFraction($x, $p, $q) / $p;

		} else {

			return 1.0 - ($beta_gam * self::_betaFraction(1 - $x, $q, $p) / $q);

		}

	}	//	function _incompleteBeta()

	// Function cache for _logBeta function

	private static $_logBetaCache_p			= 0.0;

	private static $_logBetaCache_q			= 0.0;

	private static $_logBetaCache_result	= 0.0;

	/**

	 * The natural logarithm of the beta function.

	 *

	 * @param p require p>0

	 * @param q require q>0

	 * @return 0 if p<=0, q<=0 or p+q>2.55E305 to avoid errors and over/underflow

	 * @author Jaco van Kooten

	 */

	private static function _logBeta($p, $q) {

		if ($p != self::$_logBetaCache_p || $q != self::$_logBetaCache_q) {

			self::$_logBetaCache_p = $p;

			self::$_logBetaCache_q = $q;

			if (($p <= 0.0) || ($q <= 0.0) || (($p + $q) > LOG_GAMMA_X_MAX_VALUE)) {

				self::$_logBetaCache_result = 0.0;

			} else {

				self::$_logBetaCache_result = self::_logGamma($p) + self::_logGamma($q) - self::_logGamma($p + $q);

			}

		}

		return self::$_logBetaCache_result;

	}	//	function _logBeta()

	/**

	 * Evaluates of continued fraction part of incomplete beta function.

	 * Based on an idea from Numerical Recipes (W.H. Press et al, 1992).

	 * @author Jaco van Kooten

	 */

	private static function _betaFraction($x, $p, $q) {

		$c = 1.0;

		$sum_pq = $p + $q;

		$p_plus = $p + 1.0;

		$p_minus = $p - 1.0;

		$h = 1.0 - $sum_pq * $x / $p_plus;

		if (abs($h) < XMININ) {

			$h = XMININ;

		}

		$h = 1.0 / $h;

		$frac = $h;

		$m	 = 1;

		$delta = 0.0;

		while ($m <= MAX_ITERATIONS && abs($delta-1.0) > PRECISION ) {

			$m2 = 2 * $m;

			// even index for d

			$d = $m * ($q - $m) * $x / ( ($p_minus + $m2) * ($p + $m2));

			$h = 1.0 + $d * $h;

			if (abs($h) < XMININ) {

				$h = XMININ;

			}

			$h = 1.0 / $h;

			$c = 1.0 + $d / $c;

			if (abs($c) < XMININ) {

				$c = XMININ;

			}

			$frac *= $h * $c;

			// odd index for d

			$d = -($p + $m) * ($sum_pq + $m) * $x / (($p + $m2) * ($p_plus + $m2));

			$h = 1.0 + $d * $h;

			if (abs($h) < XMININ) {

				$h = XMININ;

			}

			$h = 1.0 / $h;

			$c = 1.0 + $d / $c;

			if (abs($c) < XMININ) {

				$c = XMININ;

			}

			$delta = $h * $c;

			$frac *= $delta;

			++$m;

		}

		return $frac;

	}	//	function _betaFraction()

	/**

	 * logGamma function

	 *

	 * @version 1.1

	 * @author Jaco van Kooten

	 *

	 * Original author was Jaco van Kooten. Ported to PHP by Paul Meagher.

	 *

	 * The natural logarithm of the gamma function. <br />

	 * Based on public domain NETLIB (Fortran) code by W. J. Cody and L. Stoltz <br />

	 * Applied Mathematics Division <br />

	 * Argonne National Laboratory <br />

	 * Argonne, IL 60439 <br />

	 * <p>

	 * References:

	 * <ol>

	 * <li>W. J. Cody and K. E. Hillstrom, 'Chebyshev Approximations for the Natural

	 *	 Logarithm of the Gamma Function,' Math. Comp. 21, 1967, pp. 198-203.</li>

	 * <li>K. E. Hillstrom, ANL/AMD Program ANLC366S, DGAMMA/DLGAMA, May, 1969.</li>

	 * <li>Hart, Et. Al., Computer Approximations, Wiley and sons, New York, 1968.</li>

	 * </ol>

	 * </p>

	 * <p>

	 * From the original documentation:

	 * </p>

	 * <p>

	 * This routine calculates the LOG(GAMMA) function for a positive real argument X.

	 * Computation is based on an algorithm outlined in references 1 and 2.

	 * The program uses rational functions that theoretically approximate LOG(GAMMA)

	 * to at least 18 significant decimal digits. The approximation for X > 12 is from

	 * reference 3, while approximations for X < 12.0 are similar to those in reference

	 * 1, but are unpublished. The accuracy achieved depends on the arithmetic system,

	 * the compiler, the intrinsic functions, and proper selection of the

	 * machine-dependent constants.

	 * </p>

	 * <p>

	 * Error returns: <br />

	 * The program returns the value XINF for X .LE. 0.0 or when overflow would occur.

	 * The computation is believed to be free of underflow and overflow.

	 * </p>

	 * @return MAX_VALUE for x < 0.0 or when overflow would occur, i.e. x > 2.55E305

	 */

	// Function cache for logGamma

	private static $_logGammaCache_result	= 0.0;

	private static $_logGammaCache_x		= 0.0;

	private static function _logGamma($x) {

		// Log Gamma related constants

		static $lg_d1 = -0.5772156649015328605195174;

		static $lg_d2 = 0.4227843350984671393993777;

		static $lg_d4 = 1.791759469228055000094023;

		static $lg_p1 = array(	4.945235359296727046734888,

								201.8112620856775083915565,

								2290.838373831346393026739,

								11319.67205903380828685045,

								28557.24635671635335736389,

								38484.96228443793359990269,

								26377.48787624195437963534,

								7225.813979700288197698961 );

		static $lg_p2 = array(	4.974607845568932035012064,

								542.4138599891070494101986,

								15506.93864978364947665077,

								184793.2904445632425417223,

								1088204.76946882876749847,

								3338152.967987029735917223,

								5106661.678927352456275255,

								3074109.054850539556250927 );

		static $lg_p4 = array(	14745.02166059939948905062,

								2426813.369486704502836312,

								121475557.4045093227939592,

								2663432449.630976949898078,

								29403789566.34553899906876,

								170266573776.5398868392998,

								492612579337.743088758812,

								560625185622.3951465078242 );

		static $lg_q1 = array(	67.48212550303777196073036,

								1113.332393857199323513008,

								7738.757056935398733233834,

								27639.87074403340708898585,

								54993.10206226157329794414,

								61611.22180066002127833352,

								36351.27591501940507276287,

								8785.536302431013170870835 );

		static $lg_q2 = array(	183.0328399370592604055942,

								7765.049321445005871323047,

								133190.3827966074194402448,

								1136705.821321969608938755,

								5267964.117437946917577538,

								13467014.54311101692290052,

								17827365.30353274213975932,

								9533095.591844353613395747 );

		static $lg_q4 = array(	2690.530175870899333379843,

								639388.5654300092398984238,

								41355999.30241388052042842,

								1120872109.61614794137657,

								14886137286.78813811542398,

								101680358627.2438228077304,

								341747634550.7377132798597,

								446315818741.9713286462081 );

		static $lg_c  = array(	-0.001910444077728,

								8.4171387781295e-4,

								-5.952379913043012e-4,

								7.93650793500350248e-4,

								-0.002777777777777681622553,

								0.08333333333333333331554247,

								0.0057083835261 );

	// Rough estimate of the fourth root of logGamma_xBig

	static $lg_frtbig = 2.25e76;

	static $pnt68	 = 0.6796875;

	if ($x == self::$_logGammaCache_x) {

		return self::$_logGammaCache_result;

	}

	$y = $x;

	if ($y > 0.0 && $y <= LOG_GAMMA_X_MAX_VALUE) {

		if ($y <= EPS) {

			$res = -log(y);

		} elseif ($y <= 1.5) {

			// ---------------------

			//	EPS .LT. X .LE. 1.5

			// ---------------------

			if ($y < $pnt68) {

				$corr = -log($y);

				$xm1 = $y;

			} else {

				$corr = 0.0;

				$xm1 = $y - 1.0;

			}

			if ($y <= 0.5 || $y >= $pnt68) {

				$xden = 1.0;

				$xnum = 0.0;

				for ($i = 0; $i < 8; ++$i) {

					$xnum = $xnum * $xm1 + $lg_p1[$i];

					$xden = $xden * $xm1 + $lg_q1[$i];

				}

				$res = $corr + $xm1 * ($lg_d1 + $xm1 * ($xnum / $xden));

			} else {

				$xm2 = $y - 1.0;

				$xden = 1.0;

				$xnum = 0.0;

				for ($i = 0; $i < 8; ++$i) {

					$xnum = $xnum * $xm2 + $lg_p2[$i];

					$xden = $xden * $xm2 + $lg_q2[$i];

				}

				$res = $corr + $xm2 * ($lg_d2 + $xm2 * ($xnum / $xden));

			}

		} elseif ($y <= 4.0) {

			// ---------------------

			//	1.5 .LT. X .LE. 4.0

			// ---------------------

			$xm2 = $y - 2.0;

			$xden = 1.0;

			$xnum = 0.0;

			for ($i = 0; $i < 8; ++$i) {

				$xnum = $xnum * $xm2 + $lg_p2[$i];

				$xden = $xden * $xm2 + $lg_q2[$i];

			}

			$res = $xm2 * ($lg_d2 + $xm2 * ($xnum / $xden));

		} elseif ($y <= 12.0) {

			// ----------------------

			//	4.0 .LT. X .LE. 12.0

			// ----------------------

			$xm4 = $y - 4.0;

			$xden = -1.0;

			$xnum = 0.0;

			for ($i = 0; $i < 8; ++$i) {

				$xnum = $xnum * $xm4 + $lg_p4[$i];

				$xden = $xden * $xm4 + $lg_q4[$i];

			}

			$res = $lg_d4 + $xm4 * ($xnum / $xden);

		} else {

			// ---------------------------------

			//	Evaluate for argument .GE. 12.0

			// ---------------------------------

			$res = 0.0;

			if ($y <= $lg_frtbig) {

				$res = $lg_c[6];

				$ysq = $y * $y;

				for ($i = 0; $i < 6; ++$i)

					$res = $res / $ysq + $lg_c[$i];

				}

				$res /= $y;

				$corr = log($y);

				$res = $res + log(SQRT2PI) - 0.5 * $corr;

				$res += $y * ($corr - 1.0);

			}

		} else {

			// --------------------------

			//	Return for bad arguments

			// --------------------------

			$res = MAX_VALUE;

		}

		// ------------------------------

		//	Final adjustments and return

		// ------------------------------

		self::$_logGammaCache_x = $x;

		self::$_logGammaCache_result = $res;

		return $res;

	}	//	function _logGamma()

	//

	//	Private implementation of the incomplete Gamma function

	//

	private static function _incompleteGamma($a,$x) {

		static $max = 32;

		$summer = 0;

		for ($n=0; $n<=$max; ++$n) {

			$divisor = $a;

			for ($i=1; $i<=$n; ++$i) {

				$divisor *= ($a + $i);

			}

			$summer += (pow($x,$n) / $divisor);

		}

		return pow($x,$a) * exp(0-$x) * $summer;

	}	//	function _incompleteGamma()

	//

	//	Private implementation of the Gamma function

	//

	private static function _gamma($data) {

		if ($data == 0.0) return 0;

		static $p0 = 1.000000000190015;

		static $p = array ( 1 => 76.18009172947146,

							2 => -86.50532032941677,

							3 => 24.01409824083091,

							4 => -1.231739572450155,

							5 => 1.208650973866179e-3,

							6 => -5.395239384953e-6

						  );

		$y = $x = $data;

		$tmp = $x + 5.5;

		$tmp -= ($x + 0.5) * log($tmp);

		$summer = $p0;

		for ($j=1;$j<=6;++$j) {

			$summer += ($p[$j] / ++$y);

		}

		return exp(0 - $tmp + log(SQRT2PI * $summer / $x));

	}	//	function _gamma()

	/***************************************************************************

	 *								inverse_ncdf.php

	 *							-------------------

	 *	begin				: Friday, January 16, 2004

	 *	copyright			: (C) 2004 Michael Nickerson

	 *	email				: nickersonm@yahoo.com

	 *

	 ***************************************************************************/

	private static function _inverse_ncdf($p) {

		//	Inverse ncdf approximation by Peter J. Acklam, implementation adapted to

		//	PHP by Michael Nickerson, using Dr. Thomas Ziegler's C implementation as

		//	a guide. http://home.online.no/~pjacklam/notes/invnorm/index.html

		//	I have not checked the accuracy of this implementation. Be aware that PHP

		//	will truncate the coeficcients to 14 digits.

		//	You have permission to use and distribute this function freely for

		//	whatever purpose you want, but please show common courtesy and give credit

		//	where credit is due.

		//	Input paramater is $p - probability - where 0 < p < 1.

		//	Coefficients in rational approximations

		static $a = array(	1 => -3.969683028665376e+01,

							2 => 2.209460984245205e+02,

							3 => -2.759285104469687e+02,

							4 => 1.383577518672690e+02,

							5 => -3.066479806614716e+01,

							6 => 2.506628277459239e+00

						 );

		static $b = array(	1 => -5.447609879822406e+01,

							2 => 1.615858368580409e+02,

							3 => -1.556989798598866e+02,

							4 => 6.680131188771972e+01,

							5 => -1.328068155288572e+01

						 );

		static $c = array(	1 => -7.784894002430293e-03,

							2 => -3.223964580411365e-01,

							3 => -2.400758277161838e+00,

							4 => -2.549732539343734e+00,

							5 => 4.374664141464968e+00,

							6 => 2.938163982698783e+00

						 );

		static $d = array(	1 => 7.784695709041462e-03,

							2 => 3.224671290700398e-01,

							3 => 2.445134137142996e+00,

							4 => 3.754408661907416e+00

						 );

		//	Define lower and upper region break-points.

		$p_low = 0.02425;			//Use lower region approx. below this

		$p_high = 1 - $p_low;		//Use upper region approx. above this

		if (0 < $p && $p < $p_low) {

			//	Rational approximation for lower region.

			$q = sqrt(-2 * log($p));

			return ((((($c[1] * $q + $c[2]) * $q + $c[3]) * $q + $c[4]) * $q + $c[5]) * $q + $c[6]) /

					(((($d[1] * $q + $d[2]) * $q + $d[3]) * $q + $d[4]) * $q + 1);

		} elseif ($p_low <= $p && $p <= $p_high) {

			//	Rational approximation for central region.

			$q = $p - 0.5;

			$r = $q * $q;

			return ((((($a[1] * $r + $a[2]) * $r + $a[3]) * $r + $a[4]) * $r + $a[5]) * $r + $a[6]) * $q /

				   ((((($b[1] * $r + $b[2]) * $r + $b[3]) * $r + $b[4]) * $r + $b[5]) * $r + 1);

		} elseif ($p_high < $p && $p < 1) {

			//	Rational approximation for upper region.

			$q = sqrt(-2 * log(1 - $p));

			return -((((($c[1] * $q + $c[2]) * $q + $c[3]) * $q + $c[4]) * $q + $c[5]) * $q + $c[6]) /

					 (((($d[1] * $q + $d[2]) * $q + $d[3]) * $q + $d[4]) * $q + 1);

		}

		//	If 0 < p < 1, return a null value

		return PHPExcel_Calculation_Functions::NULL();

	}	//	function _inverse_ncdf()

	private static function _inverse_ncdf2($prob) {

		//	Approximation of inverse standard normal CDF developed by

		//	B. Moro, "The Full Monte," Risk 8(2), Feb 1995, 57-58.

		$a1 = 2.50662823884;

		$a2 = -18.61500062529;

		$a3 = 41.39119773534;

		$a4 = -25.44106049637;

		$b1 = -8.4735109309;

		$b2 = 23.08336743743;

		$b3 = -21.06224101826;

		$b4 = 3.13082909833;

		$c1 = 0.337475482272615;

		$c2 = 0.976169019091719;

		$c3 = 0.160797971491821;

		$c4 = 2.76438810333863E-02;

		$c5 = 3.8405729373609E-03;

		$c6 = 3.951896511919E-04;

		$c7 = 3.21767881768E-05;

		$c8 = 2.888167364E-07;

		$c9 = 3.960315187E-07;

		$y = $prob - 0.5;

		if (abs($y) < 0.42) {

			$z = ($y * $y);

			$z = $y * ((($a4 * $z + $a3) * $z + $a2) * $z + $a1) / (((($b4 * $z + $b3) * $z + $b2) * $z + $b1) * $z + 1);

		} else {

			if ($y > 0) {

				$z = log(-log(1 - $prob));

			} else {

				$z = log(-log($prob));

			}

			$z = $c1 + $z * ($c2 + $z * ($c3 + $z * ($c4 + $z * ($c5 + $z * ($c6 + $z * ($c7 + $z * ($c8 + $z * $c9)))))));

			if ($y < 0) {

				$z = -$z;

			}

		}

		return $z;

	}	//	function _inverse_ncdf2()

	private static function _inverse_ncdf3($p) {

		//	ALGORITHM AS241 APPL. STATIST. (1988) VOL. 37, NO. 3.

		//	Produces the normal deviate Z corresponding to a given lower

		//	tail area of P; Z is accurate to about 1 part in 10**16.

		//

		//	This is a PHP version of the original FORTRAN code that can

		//	be found at http://lib.stat.cmu.edu/apstat/

		$split1 = 0.425;

		$split2 = 5;

		$const1 = 0.180625;

		$const2 = 1.6;

		//	coefficients for p close to 0.5

		$a0 = 3.3871328727963666080;

		$a1 = 1.3314166789178437745E+2;

		$a2 = 1.9715909503065514427E+3;

		$a3 = 1.3731693765509461125E+4;

		$a4 = 4.5921953931549871457E+4;

		$a5 = 6.7265770927008700853E+4;

		$a6 = 3.3430575583588128105E+4;

		$a7 = 2.5090809287301226727E+3;

		$b1 = 4.2313330701600911252E+1;

		$b2 = 6.8718700749205790830E+2;

		$b3 = 5.3941960214247511077E+3;

		$b4 = 2.1213794301586595867E+4;

		$b5 = 3.9307895800092710610E+4;

		$b6 = 2.8729085735721942674E+4;

		$b7 = 5.2264952788528545610E+3;

		//	coefficients for p not close to 0, 0.5 or 1.

		$c0 = 1.42343711074968357734;

		$c1 = 4.63033784615654529590;

		$c2 = 5.76949722146069140550;

		$c3 = 3.64784832476320460504;

		$c4 = 1.27045825245236838258;

		$c5 = 2.41780725177450611770E-1;

		$c6 = 2.27238449892691845833E-2;

		$c7 = 7.74545014278341407640E-4;

		$d1 = 2.05319162663775882187;

		$d2 = 1.67638483018380384940;

		$d3 = 6.89767334985100004550E-1;

		$d4 = 1.48103976427480074590E-1;

		$d5 = 1.51986665636164571966E-2;

		$d6 = 5.47593808499534494600E-4;

		$d7 = 1.05075007164441684324E-9;

		//	coefficients for p near 0 or 1.

		$e0 = 6.65790464350110377720;

		$e1 = 5.46378491116411436990;

		$e2 = 1.78482653991729133580;

		$e3 = 2.96560571828504891230E-1;

		$e4 = 2.65321895265761230930E-2;

		$e5 = 1.24266094738807843860E-3;

		$e6 = 2.71155556874348757815E-5;

		$e7 = 2.01033439929228813265E-7;

		$f1 = 5.99832206555887937690E-1;

		$f2 = 1.36929880922735805310E-1;

		$f3 = 1.48753612908506148525E-2;

		$f4 = 7.86869131145613259100E-4;

		$f5 = 1.84631831751005468180E-5;

		$f6 = 1.42151175831644588870E-7;

		$f7 = 2.04426310338993978564E-15;

		$q = $p - 0.5;

		//	computation for p close to 0.5

		if (abs($q) <= split1) {

			$R = $const1 - $q * $q;

			$z = $q * ((((((($a7 * $R + $a6) * $R + $a5) * $R + $a4) * $R + $a3) * $R + $a2) * $R + $a1) * $R + $a0) /

					  ((((((($b7 * $R + $b6) * $R + $b5) * $R + $b4) * $R + $b3) * $R + $b2) * $R + $b1) * $R + 1);

		} else {

			if ($q < 0) {

				$R = $p;

			} else {

				$R = 1 - $p;

			}

			$R = pow(-log($R),2);

			//	computation for p not close to 0, 0.5 or 1.

			If ($R <= $split2) {

				$R = $R - $const2;

				$z = ((((((($c7 * $R + $c6) * $R + $c5) * $R + $c4) * $R + $c3) * $R + $c2) * $R + $c1) * $R + $c0) /

					 ((((((($d7 * $R + $d6) * $R + $d5) * $R + $d4) * $R + $d3) * $R + $d2) * $R + $d1) * $R + 1);

			} else {

			//	computation for p near 0 or 1.

				$R = $R - $split2;

				$z = ((((((($e7 * $R + $e6) * $R + $e5) * $R + $e4) * $R + $e3) * $R + $e2) * $R + $e1) * $R + $e0) /

					 ((((((($f7 * $R + $f6) * $R + $f5) * $R + $f4) * $R + $f3) * $R + $f2) * $R + $f1) * $R + 1);

			}

			if ($q < 0) {

				$z = -$z;

			}

		}

		return $z;

	}	//	function _inverse_ncdf3()

	/**

	 * AVEDEV

	 *

	 * Returns the average of the absolute deviations of data points from their mean.

	 * AVEDEV is a measure of the variability in a data set.

	 *

	 * Excel Function:

	 *		AVEDEV(value1[,value2[, ...]])

	 *

	 * @access	public

	 * @category Statistical Functions

	 * @param	mixed		$arg,...		Data values

	 * @return	float

	 */

	public static function AVEDEV() {

		$aArgs = PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args());

		// Return value

		$returnValue = null;

		$aMean = self::AVERAGE($aArgs);

		if ($aMean != PHPExcel_Calculation_Functions::DIV0()) {

			$aCount = 0;

			foreach ($aArgs as $k => $arg) {

				if ((is_bool($arg)) &&

					((!PHPExcel_Calculation_Functions::isCellValue($k)) || (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE))) {

					$arg = (integer) $arg;

				}

				// Is it a numeric value?

				if ((is_numeric($arg)) && (!is_string($arg))) {

					if (is_null($returnValue)) {

						$returnValue = abs($arg - $aMean);

					} else {

						$returnValue += abs($arg - $aMean);

					}

					++$aCount;

				}

			}

			// Return

			if ($aCount == 0) {

				return PHPExcel_Calculation_Functions::DIV0();

			}

			return $returnValue / $aCount;

		}

		return PHPExcel_Calculation_Functions::NaN();

	}	//	function AVEDEV()

	/**

	 * AVERAGE

	 *

	 * Returns the average (arithmetic mean) of the arguments

	 *

	 * Excel Function:

	 *		AVERAGE(value1[,value2[, ...]])

	 *

	 * @access	public

	 * @category Statistical Functions

	 * @param	mixed		$arg,...		Data values

	 * @return	float

	 */

	public static function AVERAGE() {

		$returnValue = $aCount = 0;

		// Loop through arguments

		foreach (PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args()) as $k => $arg) {

			if ((is_bool($arg)) &&

				((!PHPExcel_Calculation_Functions::isCellValue($k)) || (PHPExcel_Calculation_Functions::getCompatibilityMode() == PHPExcel_Calculation_Functions::COMPATIBILITY_OPENOFFICE))) {

				$arg = (integer) $arg;

			}

			// Is it a numeric value?

			if ((is_numeric($arg)) && (!is_string($arg))) {

				if (is_null($returnValue)) {

					$returnValue = $arg;

				} else {

					$returnValue += $arg;

				}

				++$aCount;

			}

		}

		// Return

		if ($aCount > 0) {

			return $returnValue / $aCount;

		} else {

			return PHPExcel_Calculation_Functions::DIV0();

		}

	}	//	function AVERAGE()

	/**

	 * AVERAGEA

	 *

	 * Returns the average of its arguments, including numbers, text, and logical values

	 *

	 * Excel Function:

	 *		AVERAGEA(value1[,value2[, ...]])

	 *

	 * @access	public

	 * @category Statistical Functions

	 * @param	mixed		$arg,...		Data values

	 * @return	float

	 */

	public static function AVERAGEA() {

		// Return value

		$returnValue = null;

		$aCount = 0;

		// Loop through arguments

		foreach (PHPExcel_Calculation_Functions::flattenArrayIndexed(func_get_args()) as $k => $arg) {

			if ((is_bool($arg)) &&

				(!PHPExcel_Calculation_Functions::isMatrixValue($k))) {

			} else {

				if ((is_numeric($arg)) || (is_bool($arg)) || ((is_string($arg) && ($arg != '')))) {

					if (is_bool($arg)) {

						$arg = (integer) $arg;

					} elseif (is_string($arg)) {

						$arg = 0;

					}

					if (is_null($returnValue)) {

						$returnValue = $arg;

					} else {

						$returnValue += $arg;

					}

					++$aCount;

				}

			}

		}

		// Return

		if ($aCount > 0) {

			return $returnValue / $aCount;

		} else {

			return PHPExcel_Calculation_Functions::DIV0();

		}

	}	//	function AVERAGEA()

	/**

	 * AVERAGEIF

	 *

	 * Returns the average value from a range of cells that contain numbers within the list of arguments

	 *

	 * Excel Function:

	 *		AVERAGEIF(value1[,value2[, ...]],condition)

	 *

	 * @access	public

	 * @category Mathematical and Trigonometric Functions

	 * @param	mixed		$arg,...		Data values

	 * @param	string		$condition		The criteria that defines which cells will be checked.

	 * @param	mixed[]		$averageArgs	Data values

	 * @return	float

	 */

	public static function AVERAGEIF($aArgs,$condition,$averageArgs = array()) {

		// Return value

		$returnValue = 0;

		$aArgs = PHPExcel_Calculation_Functions::flattenArray($aArgs);

		$averageArgs = PHPExcel_Calculation_Functions::flattenArray($averageArgs);

		if (empty($averageArgs)) {

			$averageArgs = $aArgs;

		}

		$condition = PHPExcel_Calculation_Functions::_ifCondition($condition);

		// Loop through arguments

		$aCount = 0;

		foreach ($aArgs as $key => $arg) {

			if (!is_numeric($arg)) { $arg = PHPExcel_Calculation::_wrapResult(strtoupper($arg)); }

			$testCondition = '='.$arg.$condition;

			if (PHPExcel_Calculation::getInstance()->_calculateFormulaValue($testCondition)) {

				if ((is_null($returnValue)) || ($arg > $returnValue)) {

					$returnValue += $arg;

					++$aCount;

				}

			}

		}

		// Return

		if ($aCount > 0) {

			return $returnValue / $aCount;

		} else {

			return PHPExcel_Calculation_Functions::DIV0();

		}

	}	//	function AVERAGEIF()

	/**

	 * BETADIST

	 *

	 * Returns the beta distribution.

	 *

	 * @param	float		$value			Value at which you want to evaluate the distribution

	 * @param	float		$alpha			Parameter to the distribution

	 * @param	float		$beta			Parameter to the distribution

	 * @param	boolean		$cumulative

	 * @return	float

	 *

	 */

	public static function BETADIST($value,$alpha,$beta,$rMin=0,$rMax=1) {

		$value	= PHPExcel_Calculation_Functions::flattenSingleValue($value);

		$alpha	= PHPExcel_Calculation_Functions::flattenSingleValue($alpha);

		$beta	= PHPExcel_Calculation_Functions::flattenSingleValue($beta);

		$rMin	= PHPExcel_Calculation_Functions::flattenSingleValue($rMin);

		$rMax	= PHPExcel_Calculation_Functions::flattenSingleValue($rMax);

		if ((is_numeric($value)) && (is_numeric($alpha)) && (is_numeric($beta)) && (is_numeric($rMin)) && (is_numeric($rMax))) {

			if (($value < $rMin) || ($value > $rMax) || ($alpha <= 0) || ($beta <= 0) || ($rMin == $rMax)) {

				return PHPExcel_Calculation_Functions::NaN();

			}

			if ($rMin > $rMax) {

				$tmp = $rMin;

				$rMin = $rMax;

				$rMax = $tmp;

			}

			$value -= $rMin;

			$value /= ($rMax - $rMin);

			return self::_incompleteBeta($value,$alpha,$beta);

		}

		return PHPExcel_Calculation_Functions::VALUE();

	}	//	function BETADIST()

	/**

	 * BETAINV

	 *

	 * Returns the inverse of the beta distribution.

	 *

	 * @param	float		$probability	Probability at which you want to evaluate the distribution

	 * @param	float		$alpha			Parameter to the distribution

	 * @param	float		$beta			Parameter to the distribution

	 * @param	float		$rMin			Minimum value

	 * @param	float		$rMax			Maximum value

	 * @param	boolean		$cumulative

	 * @return	float

	 *

	 */

	public static function BETAINV($probability,$alpha,$beta,$rMin=0,$rMax=1) {

		$probability	= PHPExcel_Calculation_Functions::flattenSingleValue($probability);

		$alpha			= PHPExcel_Calculation_Functions::flattenSingleValue($alpha);

		$beta			= PHPExcel_Calculation_Functions::flattenSingleValue($beta);

		$rMin			= PHPExcel_Calculation_Functions::flattenSingleValue($rMin);

		$rMax			= PHPExcel_Calculation_Functions::flattenSingleValue($rMax);

		if ((is_numeric($probability)) && (is_numeric($alpha)) && (is_numeric($beta)) && (is_numeric($rMin)) && (is_numeric($rMax))) {

			if (($alpha <= 0) || ($beta <= 0) || ($rMin == $rMax) || ($probability <= 0) || ($probability > 1)) {

				return PHPExcel_Calculation_Functions::NaN();

			}

			if ($rMin > $rMax) {

				$tmp = $rMin;

				$rMin = $rMax;

				$rMax = $tmp;

			}

			$a = 0;

			$b = 2;

			$i = 0;

			while ((($b - $a) > PRECISION) && ($i++ < MAX_ITERATIONS)) {

				$guess = ($a + $b) / 2;

				$result = self::BETADIST($guess, $alpha, $beta);

				if (($result == $probability) || ($result == 0)) {

					$b = $a;

				} elseif ($result > $probability) {

					$b = $guess;

				} else {

					$a = $guess;

				}

			}

			if ($i == MAX_ITERATIONS) {

				return PHPExcel_Calculation_Functions::NA();

			}

			return round($rMin + $guess * ($rMax - $rMin),12);

		}

		return PHPExcel_Calculation_Functions::VALUE();

	}	//	function BETAINV()

	/**

	 * BINOMDIST

	 *

	 * Returns the individual term binomial distribution probability. Use BINOMDIST in problems with

	 *		a fixed number of tests or trials, when the outcomes of any trial are only success or failure,

	 *		when trials are independent, and when the probability of success is constant throughout the

	 *		experiment. For example, BINOMDIST can calculate the probability that two of the next three

	 *		babies born are male.

	 *

	 * @param	float		$value			Number of successes in trials

	 * @param	float		$trials			Number of trials

	 * @param	float		$probability	Probability of success on each trial

	 * @param	boolean		$cumulative

	 * @return	float

	 *

	 * @todo	Cumulative distribution function

	 *

	 */

	public static function BINOMDIST($value, $trials, $probability, $cumulative) {

		$value			= floor(PHPExcel_Calculation_Functions::flattenSingleValue($value));

		$trials			= floor(PHPExcel_Calculation_Functions::flattenSingleValue($trials));

		$probability	= PHPExcel_Calculation_Functions::flattenSingleValue($probability);

		if ((is_numeric($value)) && (is_numeric($trials)) && (is_numeric($probability))) {

			if (($value < 0) || ($value > $trials)) {

				return PHPExcel_Calculation_Functions::NaN();

			}

			if (($probability < 0) || ($probability > 1)) {

				return PHPExcel_Calculation_Functions::NaN();

			}

			if ((is_numeric($cumulative)) || (is_bool($cumulative))) {

				if ($cumulative) {

					$summer = 0;

					for ($i = 0; $i <= $value; ++$i) {

						$summer += PHPExcel_Calculation_MathTrig::COMBIN($trials,$i) * pow($probability,$i) * pow(1 - $probability,$trials - $i);