File Coverage

blib/lib/Fsdb/Support/TDistribution.pm

Criterion	Covered	Total	%
statement	6	55	10.9
branch	0	36	0.0
condition			n/a
subroutine	2	6	33.3
pod	4	4	100.0
total	12	101	11.8

line	stmt	bran	sub	pod	time	code
1						#!/usr/bin/perl -w
2
3						#
4						# Fsdb::Support::TDistribution.pm
5						# Copyright (C) 1995-1998 by John Heidemann
6						# $Id: c16ee50eb7a15728d65c5c44ec920470ba64d366 $
7						#
8						# This program is distributed under terms of the GNU general
9						# public license, version 2. See the file COPYING
10						# in $dblib for details.
11						#
12
13						#
14						# This code is a Perl port of Geoff Kuenning's C-lanague statistics
15						# program (stats.c), but modified to use alpha instead of gamma.
16						#
17
18						package Fsdb::Support::TDistribution;
19
20
21						=head1 NAME
22
23						Fsdb::Support::TDistribution - t-distributions for stats
24
25						=head1 SYNOPSIS
26
27						use Fsdb::Support::TDistribution;
28
29						$stats = new DbStats(options);
30
31						=cut
32						#'
33
34
35	1		1		6	use Exporter 'import';
	1				2
	1				72
36						@EXPORT = qw();
37						@EXPORT_OK = qw(t_distribution);
38						($VERSION) = 1.0;
39
40	1		1		5	use Carp qw(croak);
	1				2
	1				839
41						#'
42
43						# interval vars
44						my(@t_nus, %t_values, @t_alphas);
45						my($inited) = undef;
46
47
48						=head2 init_t_distr
49
50						internal intialization
51
52						=cut
53						sub init_t_distr {
54	0		0	1		my($t_values) = "
55						alphas: 0.4, 0.3, 0.2, 0.1, 0.06666666666667, 0.05, 0.04, 0.03333333333333, 0.025, 0.02, 0.01666666666667, 0.0125, 0.01, 0.00833333333333, 0.00625, 0.005
56						1: 0.325, 0.727, 1.376, 3.078, 4.702, 6.314, 7.916, 9.524, 12.706, 15.895, 19.043, 25.452, 31.821, 38.342, 51.334, 63.657
57						2: 0.289, 0.617, 1.061, 1.886, 2.456, 2.920, 3.320, 3.679, 4.303, 4.849, 5.334, 6.205, 6.965, 7.665, 8.897, 9.925
58						3: 0.277, 0.584, 0.978, 1.638, 2.045, 2.353, 2.605, 2.823, 3.182, 3.482, 3.738, 4.177, 4.541, 4.864, 5.408, 5.841
59						4: 0.271, 0.569, 0.941, 1.533, 1.879, 2.132, 2.333, 2.502, 2.776, 2.999, 3.184, 3.495, 3.747, 3.966, 4.325, 4.604
60						5: 0.267, 0.559, 0.920, 1.476, 1.790, 2.015, 2.191, 2.337, 2.571, 2.757, 2.910, 3.163, 3.365, 3.538, 3.818, 4.032
61						6: 0.265, 0.553, 0.906, 1.440, 1.735, 1.943, 2.104, 2.237, 2.447, 2.612, 2.748, 2.969, 3.143, 3.291, 3.528, 3.707
62						7: 0.263, 0.549, 0.896, 1.415, 1.698, 1.895, 2.046, 2.170, 2.365, 2.517, 2.640, 2.841, 2.998, 3.130, 3.341, 3.499
63						8: 0.262, 0.546, 0.889, 1.397, 1.670, 1.860, 2.004, 2.122, 2.306, 2.449, 2.565, 2.752, 2.896, 3.018, 3.211, 3.355
64						9: 0.261, 0.543, 0.883, 1.383, 1.650, 1.833, 1.973, 2.086, 2.262, 2.398, 2.508, 2.685, 2.821, 2.936, 3.116, 3.250
65						10: 0.260, 0.542, 0.879, 1.372, 1.634, 1.812, 1.948, 2.058, 2.228, 2.359, 2.465, 2.634, 2.764, 2.872, 3.043, 3.169
66						11: 0.260, 0.540, 0.876, 1.363, 1.621, 1.796, 1.928, 2.036, 2.201, 2.328, 2.430, 2.593, 2.718, 2.822, 2.985, 3.106
67						12: 0.259, 0.539, 0.873, 1.356, 1.610, 1.782, 1.912, 2.017, 2.179, 2.303, 2.402, 2.560, 2.681, 2.782, 2.939, 3.055
68						13: 0.259, 0.538, 0.870, 1.350, 1.601, 1.771, 1.899, 2.002, 2.160, 2.282, 2.379, 2.533, 2.650, 2.748, 2.900, 3.012
69						14: 0.258, 0.537, 0.868, 1.345, 1.593, 1.761, 1.887, 1.989, 2.145, 2.264, 2.359, 2.510, 2.624, 2.720, 2.868, 2.977
70						15: 0.258, 0.536, 0.866, 1.341, 1.587, 1.753, 1.878, 1.978, 2.131, 2.249, 2.342, 2.490, 2.602, 2.696, 2.841, 2.947
71						16: 0.258, 0.535, 0.865, 1.337, 1.581, 1.746, 1.869, 1.968, 2.120, 2.235, 2.327, 2.473, 2.583, 2.675, 2.817, 2.921
72						17: 0.257, 0.534, 0.863, 1.333, 1.576, 1.740, 1.862, 1.960, 2.110, 2.224, 2.315, 2.458, 2.567, 2.657, 2.796, 2.898
73						18: 0.257, 0.534, 0.862, 1.330, 1.572, 1.734, 1.855, 1.953, 2.101, 2.214, 2.303, 2.445, 2.552, 2.641, 2.778, 2.878
74						19: 0.257, 0.533, 0.861, 1.328, 1.568, 1.729, 1.850, 1.946, 2.093, 2.205, 2.293, 2.433, 2.539, 2.627, 2.762, 2.961
75						20: 0.257, 0.533, 0.860, 1.325, 1.564, 1.725, 1.844, 1.940, 2.086, 2.197, 2.285, 2.423, 2.528, 2.614, 2.748, 2.845
76						21: 0.257, 0.592, 0.859, 1.323, 1.561, 1.721, 1.840, 1.935, 2.080, 2.189, 2.277, 2.414, 2.518, 2.603, 2.735, 2.831
77						22: 0.256, 0.532, 0.858, 1.321, 1.558, 1.717, 1.835, 1.930, 2.074, 2.183, 2.269, 2.405, 2.508, 2.593, 2.724, 2.819
78						23: 0.256, 0.532, 0.858, 1.319, 1.556, 1.714, 1.832, 1.926, 2.069, 2.177, 2.263, 2.398, 2.500, 2.584, 2.713, 2.807
79						24: 0.256, 0.531, 0.857, 1.318, 1.553, 1.711, 1.828, 1.922, 2.064, 2.172, 2.257, 2.391, 2.492, 2.575, 2.704, 2.797,
80						25: 0.256, 0.531, 0.856, 1.316, 1.551, 1.708, 1.825, 1.918, 2.060, 2.167, 2.251, 2.385, 2.485, 2.568, 2.695, 2.787
81						26: 0.256, 0.531, 0.856, 1.315, 1.549, 1.706, 1.822, 1.915, 2.056, 2.162, 2.246, 2.379, 2.479, 2.561, 2.687, 2.779
82						27: 0.256, 0.531, 0.855, 1.314, 1.547, 1.703, 1.819, 1.912, 2.052, 2.158, 2.242, 2.373, 2.473, 2.554, 2.680, 2.771
83						28: 0.256, 0.530, 0.855, 1.313, 1.546, 1.701, 1.817, 1.909, 2.048, 2.154, 2.237, 2.368, 2.467, 2.548, 2.673, 2.763
84						29: 0.256, 0.530, 0.854, 1.311, 1.544, 1.699, 1.814, 1.906, 2.045, 2.150, 2.233, 2.364, 2.462, 2.543, 2.667, 2.756
85						30: 0.256, 0.530, 0.854, 1.310, 1.543, 1.697, 1.812, 1.904, 2.042, 2.147, 2.230, 2.360, 2.457, 2.537, 2.661, 2.750
86						40: 0.255, 0.529, 0.851, 1.303, 1.532, 1.684, 1.796, 1.886, 2.021, 2.123, 2.203, 2.329, 2.423, 2.501, 2.619, 2.704
87						50: 0.255, 0.528, 0.849, 1.299, 1.526, 1.676, 1.787, 1.875, 2.009, 2.109, 2.188, 2.311, 2.403, 2.479, 2.594, 2.678
88						75: 0.254, 0.527, 0.846, 1.293, 1.517, 1.665, 1.775, 1.861, 1.992, 2.090, 2.167, 2.287, 2.377, 2.450, 2.562, 2.643
89						100: 0.254, 0.526, 0.845, 1.290, 1.513, 1.660, 1.769, 1.855, 1.984, 2.081, 2.157, 2.276, 2.364, 2.436, 2.547, 2.626
90						10000: 0.253, 0.524, 0.842, 1.282, 1.501, 1.645, 1.751, 1.834, 1.960, 2.054, 2.127, 2.241, 2.326, 2.395, 2.501, 2.57
91						";
92						# In a previous version, and in Geoff's code, the last line
93						# was listed as MAXINT (Geoff) or 2^31-1 (my code).
94						# My code broke on 64-bit comptuers (welcome to 2001!)
95						# when n exceeded 2^31. Yuri Pradkin proceeded to exercise
96						# this bug.
97						# Geoff's code wouldn't have broken,
98						# BUT IMHO linear interpolation between such widely disparate numbers
99						# doesn't make sense. I therefore define 10000 (arbitarily)
100						# as infinity, and added code below to handle values greater than that.
101						# This approach is all very hackish; I need to consult a Real
102						# Statistician. ---johnh 2011-03-10
103	0					my($nui) = -1;
104	0					foreach (split(/\n/, $t_values)) {
105	0	0				next if (/^\s*$/);
106	0					my(@values) = split(/[ \t\n:,]+/, $_);
107	0	0				$values[0] = 0 if ($values[0] eq 'alphas');
108	0					my($nu) = $values[0] + 0; shift @values;
	0
109	0	0				if ($nui >= 0) {
110	0					push (@t_nus, $nu);
111	0	0				croak("Bad number of values in table.\n") if ($#values != $#t_alphas);
112						};
113	0					foreach $i (0..$#values) {
114	0	0				croak("Zero t_value for nu=$nu, alpha=$alpha.\n") if ($values[$i] == 0);
115	0	0				if ($nui >= 0) {
116	0					$t_values{$nu,$t_alphas[$i]} = $values[$i] + 0.0;
117						} else {
118	0					$t_alphas[$i] = $values[$i];
119						};
120						};
121	0					$nui++;
122						};
123	0					$inited = 1;
124						}
125
126
127						=head2 interpolate
128
129						Linear interpolation, given
130						desired x, x bounding (low and high) x and y values.
131
132						=cut
133						sub interpolate {
134	0		0	1		my($x, $x_low, $x_high, $y_low, $y_high) = @_;
135	0					return $y_low + (($x - $x_low) / ($x_high - $x_low)) * ($y_high - $y_low);
136						}
137
138						=head2 floats_equal
139
140						compare to floating point numbers with a bit of fuzz
141
142						=cut
143						sub floats_equal {
144	0		0	1		my($a, $b) = @_;
145	0	0				my $delta = $a-$b; $delta = -$delta if ($delta < 0.0);
	0
146	0					return $delta < 0.000001;
147						}
148
149
150						=head2 t_distribution($nu, $alpha)
151
152						Return the value interpolated from a t-distribution.
153
154						=cut
155						# Geoff's version was in terms of gamma (1-alpha), but that was confusing.
156						# '
157						sub t_distribution {
158	0		0	1		my($nu, $alpha) = @_; # degrees of freedom, confidence half-interval
159	0	0				croak("Bad (negative) nu: $nu.\n") if ($nu <= 0);
160
161	0	0				&init_t_distr() if (!$inited);
162
163						# search in the alpha dimension
164	0	0				croak("Alpha value too high, off of left of table.")
165						if ($alpha > $t_alphas[0]);
166	0					my($alphai);
167	0					for ($alphai = 0; $alphai <= $#t_alphas; $alphai++) {
168	0	0				last if ($t_alphas[$alphai] <= $alpha);
169						};
170	0	0				croak("Alpha value too low, off of right of table.")
171						if ($alphai > $#t_alphas);
172	0					my($alpha_left) = $t_alphas[$alphai-1];
173	0					my($alpha_right) = $t_alphas[$alphai];
174
175						# search in the nu dimension
176	0					my($nui);
177	0					for ($nui = 0; $nui <= $#t_nus; $nui++) {
178	0	0				last if ($t_nus[$nui] >= $nu);
179						};
180	0					my($nu_less, $nu_more);
181	0	0				if ($nui > $#t_nus) {
		0
182						# at infinity?
183	0					$nu_less = $nu_more = $#t_nus;
184						} elsif ($t_nus[$nui] == $nu) {
185	0					$nu_less = $nu_more = $nui;
186						} else{
187	0					$nu_less = $t_nus[$nui-1];
188	0					$nu_more = $t_nus[$nui];
189						};
190
191						# now do interopation, if necssary
192	0	0				if (floats_equal($t_alphas[$alphai], $alpha)) {
		0
193	0	0				if ($nu_less == $nu_more) {
194						# print "exact match\n";
195	0					return $t_values{$t_nus[$nu_more],$alpha};
196						} else {
197						# print "interpolate nu: $nu ($nu_less,$nu_more)\n";
198						return &interpolate($nu, $nu_less, $nu_more,
199	0					$t_values{$nu_less,$alpha}, $t_values{$nu_more,$alpha});
200						};
201						} elsif ($t_nus[$nui] == $nu) {
202						# print "interpolate alpha: $alpha ($alpha_left,$alpha_right)\n";
203						return &interpolate($alpha, $alpha_left, $alpha_right,
204	0					$t_values{$nu,$alpha_left}, $t_values{$nu,$alpha_right});
205						} else {
206	0					croak("Neither nu nor alpha match, case not implemented.");
207						# Geoff's code:
208						# value_low = interpolate (alpha,
209						# alphas[alpha_index - 1],
210						# alphas[alpha_index],
211						# t_values[nu_index - 1].values[alpha_index - 1],
212						# t_values[nu_index - 1].values[alpha_index]);
213						# value_high = interpolate (alpha,
214						# alphas[alpha_index - 1],
215						# alphas[alpha_index],
216						# t_values[nu_index].values[alpha_index - 1],
217						# t_values[nu_index].values[alpha_index]);
218						# return interpolate ((double) nu,
219						# (double) t_values[nu_index - 1].nu,
220						# (double) t_values[nu_index].nu,
221						# value_low,
222						# value_high);
223						};
224						}
225
226						1;