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2a8276b | 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 | function y = wprctile(X,p,varargin)
%WPRCTILE Returns weighted percentiles of a sample with six algorithms.
% The idea is to give more emphasis in some examples of data as compared to
% others by giving more weight. For example, we could give lower weights to
% the outliers. The motivation to write this function is to compute percentiles
% for Monte Carlo simulations where some simulations are very bad (in terms of
% goodness of fit between simulated and actual value) than the others and to
% give the lower weights based on some goodness of fit criteria.
%
% USAGE:
% y = WPRCTILE(X,p)
% y = WPRCTILE(X,p,w)
% y = WPRCTILE(X,p,w,type)
%
% INPUT:
% X - vector or matrix of the sample data
% p - scalar or a vector of percent values between 0 and 100
%
% w - positive weight vector for the sample data. Length of w must be
% equal to either number of rows or columns of X. If X is matrix, same
% weight vector w is used for all columns (DIM=1)or for all rows
% (DIM=2). If the weights are equal, then WPRCTILE is same as PRCTILE.
%
% type - an integer between 4 and 9 selecting one of the 6 quantile algorithms.
% Type 4: p(k) = k/n. That is, linear interpolation of the empirical cdf.
% Type 5: p(k) = (k-0.5)/n. That is a piecewise linear function where
% the knots are the values midway through the steps of the
% empirical cdf. This is popular amongst hydrologists. (default)
% PRCTILE also uses this formula.
% Type 6: p(k) = k/(n+1). Thus p(k) = E[F(x[k])].
% This is used by Minitab and by SPSS.
% Type 7: p(k) = (k-1)/(n-1). In this case, p(k) = mode[F(x[k])].
% This is used by S.
% Type 8: p(k) = (k-1/3)/(n+1/3). Then p(k) =~ median[F(x[k])].
% The resulting quantile estimates are approximately
% median-unbiased regardless of the distribution of x.
% Type 9: p(k) = (k-3/8)/(n+1/4). The resulting quantile estimates are
% approximately unbiased for the expected order statistics
% if x is normally distributed.
%
% Interpolating between the points pk and X(k) gives the sample
% quantile. Here pk is plotting position and X(k) is order statistics of
% x such that x(k)< x(k+1) < x(k+2)...
%
% OUTPUT:
% y - percentiles of the values in X
% When X is a vector, y is the same size as p, and y(i) contains the
% P(i)-th percentile.
% When X is a matrix, WPRCTILE calculates percentiles along dimension DIM
% which is based on: if size(X,1) == length(w), DIM = 1;
% elseif size(X,2) == length(w), DIM = 2;
%
% EXAMPLES:
% w = rand(1000,1);
% y = wprctile(x,[2.5 25 50 75 97.5],w,5);
% % here if the size of x is 1000-by-50, then y will be size of 6-by-50
% % if x is 50-by-1000, then y will be of the size of 50-by-6
%
% Please note that this version of WPRCTILE will not work with NaNs values and
% planned to update in near future to handle NaNs values as missing values.
%
% References: Rob J. Hyndman and Yanan Fan, 1996, Sample Quantiles in Statistical
% Package, The American Statistician, 50, 4.
%
% HISTORY:
% version 1.0.0, Release 2007/10/16: Initial release
% version 1.1.0, Release 2008/04/02: Implementation of other 5 algorithms and
% other minor improvements of code
%
%
% I appreciate the bug reports and suggestions.
% See also: PRCTILE (Statistical Toolbox)
% Author: Durga Lal Shrestha
% UNESCO-IHE Institute for Water Education, Delft, The Netherlands
% eMail: durgals@hotmail.com
% Website: http://www.hi.ihe.nl/durgalal/index.htm
% Copyright 2004-2007 Durga Lal Shrestha.
% $First created: 16-Oct-2007
% $Revision: 1.1.0 $ $Date: 02-Apr-2008 13:40:29 $
% ***********************************************************************
%% Input arguments check
% error(nargchk(2,4,nargin))
% if ~isvector(p) || numel(p) == 0
% error('wprctile:BadPercents', ...
% 'P must be a scalar or a non-empty vector.');
% elseif any(p < 0 | p > 100) || ~isreal(p)
% error('wprctile:BadPercents', ...
% 'P must take real values between 0 and 100');
% end
% if ndims(X)>2
% error('wprctile:InvalidNumberofDimensions','X Must be 2D.')
% end
% Default weight vector
if isvector(X)
w = ones(length(X),1);
else
w = ones(size(X,1),1); % works as dimension 1
end
type = 5;
if nargin > 2
if ~isempty(varargin{1})
w = varargin{1}; % weight vector
end
if nargin >3
type = varargin{2}; % type to compute quantile
end
end
if ~isvector(w)|| any(w<0)
error('wprctile:InvalidWeight', ...
'w must vecor and values should be greater than 0');
end
% Check if there are NaN in any of the input
nans = isnan(X);
if any(nans(:)) || any(isnan(p))|| any(isnan(w))
error('wprctile:NaNsInput',['This version of WPRCTILE will not work with ' ...
'NaNs values in any input and planned to update in near future to ' ...
'handle NaNs values as missing values.']);
end
%% Figure out which dimension WPRCTILE will work along using weight vector w
n = length(w);
[nrows, ncols] = size(X);
if nrows==n
dim = 1;
elseif ncols==n
dim = 2;
else
error('wprctile:InvalidDimension', ...
'length of w must be equal to either number of rows or columns of X');
end
%% Work along DIM = 1 i.e. columswise, convert back later if needed using tflag
tflag = false; % flag to note transpose
if dim==2
X = X';
tflag = true;
end
ncols = size(X,2);
np = length(p);
y = zeros(np,ncols);
% Change w to column vector
w = w(:);
% normalise weight vector such that sum of the weight vector equals to n
w = w*n/sum(w);
%% Work on each column separately because of weight vector
for i=1:ncols
[sortedX, ind] = sort(X(:,i)); % sort the data
sortedW = w(ind); % rearrange the weight according to ind
k = cumsum(sortedW); % cumulative weight
switch type % different algorithm to compute percentile
case 4
pk = k/n;
case 5
pk = (k-sortedW/2)/n;
case 6
pk = k/(n+1);
case 7
pk = (k-sortedW)/(n-1);
case 8
pk = (k-sortedW/3)/(n+1/3);
case 9
pk = (k-sortedW*3/8)/(n+1/4);
otherwise
error('wprctile:InvalidType', ...
'Integer to select one of the six quantile algorithm should be between 4 to 9.')
end
% to avoid NaN for outside the range, the minimum or maximum values in X are
% assigned to percentiles for percent values outside that range.
q = [0;pk;1];
xx = [sortedX(1); sortedX; sortedX(end)];
% Interpolation between q and xx for given value of p
y(:,i) = interp1q(q,xx,p(:)./100);
end
%% Transpose data back for DIM = 2 to the orginal dimension of X
% if p is row vector and X is vector then return y as row vector
if tflag || (min(size(X))==1 && size(p,1)==1)
y=y';
end |