1 | %IKPCA Indefinite Kernel Principal Component Analysis
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2 | %
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3 | % [W,SIG,L] = IKPCA(K,ALF)
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4 | % OR
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5 | % [W,SIG,L] = IKPCA(W,ALF)
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6 | %
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7 | % INPUT
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8 | % K NxN kernel or symmetric similarity matrix (dataset)
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9 | % W Trained IKPCA projection into a kernel-induced pseudo-Euclidean subspace
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10 | % ALF Parameter determining the dimension and the mapping (optional, default: Inf)
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11 | % (0,1) - fraction of the total magnitude of the preserved variance
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12 | % Inf - no dimension reduction; keeping all dimensions (it's VERY noisy)
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13 | % 'p' - projection into a Euclidean space based on the positive eigenvalues only
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14 | % 'PARp'- projection into a Euclidean space based on the PAR fraction of
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15 | % positive eigenvalues; e.g. ALF = '0.9p'
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16 | % 'n' - projection into a Euclidean space based on the negative eigenvalues only
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17 | % 'PARn'- projection into a (negative) Euclidean space based on the PAR fraction
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18 | % of negative eigenvalues; e.g. ALF = '0.7n'
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19 | % 'P1pP2n'- projection into a Euclidean space based on the P1 positive eigenvalues
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20 | % and P2 negative eigenvalues; e.g. ALF = '0.7p0.1n', ALF = '7p2n'
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21 | % 1 .. N - total number of significant dimensions
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22 | % [P1 P2] - P1 dimensions or a fraction of preserved variance in the positive
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23 | % subspace and P2 dimensions or a fraction of preserved variance in
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24 | % the negative subspace; e.g. ALF = [5 10], ALF = [0.9 0.1]
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25 | %
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26 | % OUTPUT
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27 | % W Indefinite Kernel PCA mapping
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28 | % SIG Signature of the kernel Pseudo-Euclidean subspace
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29 | % L Sorted list of eigenvalues
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30 | %
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31 | % DEFAULTS
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32 | % ALF = Inf
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33 | %
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34 | % DESCRIPTION
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35 | % Performs principal component analysis in a kernel space (either Hilbert or Krein
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36 | % space) by finding M significant principal components. M is determined by ALF,
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37 | % e.g. such that at least the fraction ALF of the total variance is preserved.
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38 | % The parameter SIG describes the signature of the subspace. L is a sorted list
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39 | % of eigenvalues describing the variances in the (pseudo-)Euclidean subspace.
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40 | % The projection X is found as X = K*W. The signature is also stored in X.user.
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41 | %
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42 | % A trained mapping can be reduced by:
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43 | % [W,SIG,L] = IKPCA(W,ALF)
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44 | %
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45 | % SEE ALSO
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46 | % MAPPINGS, DATASETS, PCAM, PSEM
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47 | %
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48 | % REFERENCE
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49 | % 1. E. Pekalska and R.P.W. Duin. Indefinite Kernel Principal Component Analysis.
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50 | % Technical Report, 2006.
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51 | % 2. B. Schölkopf, A. Smola, and K.-R. Müller. Kernel Principal Component Analysis.
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52 | % in Advances in Kernel Methods - SV Learning, pages 327-352. MIT Press, Cambridge, MA, 1999.
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53 | %
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54 |
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55 | % Copyright: Elzbieta Pekalska, ela.pekalska@googlemail.com
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56 | % Faculty EWI, Delft University of Technology and
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57 | % School of Computer Science, University of Manchester, UK
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58 |
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59 |
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60 | function [W,sig,L] = ikpca (K,alf,prec)
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61 |
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62 | % PREC is the precision parameter used for the automatic
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63 | % selection (heuristic) of the number of dominant eigenvalues.
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64 | % This happens when SELEIGS is called with the parameter 'CUT'.
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65 |
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66 | if nargin < 3 | isempty(prec),
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67 | prec = 1e-4;
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68 | end
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69 | if nargin < 2 | isempty(alf),
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70 | alf = inf;
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71 | end
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72 | if nargin < 1 | isempty(K),
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73 | W = prmapping(mfilename,alf,prec);
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74 | W = setname(W,'IKPCA');
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75 | return
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76 | end
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77 |
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78 |
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79 | if (isdataset(K) | isa(K,'double')),
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80 | if ismapping(alf),
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81 | % APPLY THE MAPPING: project new data using the trained mapping
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82 | [m,n] = size(K);
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83 | pars = getdata(alf);
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84 |
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85 | % Parameters
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86 | QL = pars{1}; % Normalized eigenvectors
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87 | Kme = pars{2}; % Row vector of the average original kernel values
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88 |
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89 | % Centering the kernel
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90 | H = -repmat(1/n,n,n);
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91 | H(1:n+1:end) = H(1:n+1:end) + 1; % H = eye(n) - ones(n,n)/n
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92 | K = (K - repmat(Kme,m,1)) * H;
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93 | W = K*QL;
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94 | if isdataset(W),
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95 | W.name = ['Projected ' updname(W.name)];
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96 | W.user = pars{4}; % Signature of the PE subspace
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97 | end
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98 | return;
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99 | end
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100 | end
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101 |
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102 |
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103 |
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104 | % REDUCE ALREADY TRAINED MAPPING
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105 | if ismapping(K),
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106 | pars = getdata(K);
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107 |
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108 | QL = pars{1};
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109 | L = pars{3};
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110 | m = size(Q,1);
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111 |
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112 | [ll,P] = sort(-abs(L));
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113 | L = L(P);
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114 | QL = QL(:,P);
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115 | [J,sig] = seleigs(L,alf,pars{5});% J is the index of selected eigenvalues
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116 | QL = QL(:,J); % Eigenvectors
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117 | L = L(J); % Eigenvalues
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118 |
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119 | W = prmapping(mfilename,'trained',{QL,pars{2},L,sig,pars{5}},[],m,length(J));
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120 | W = setname(W,'IKPCA');
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121 | return
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122 | end
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123 |
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124 |
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125 |
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126 |
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127 | % TRAIN THE MAPPING
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128 | K = +K;
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129 | [n,m] = size(K);
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130 |
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131 | % Tolerance value used in comparisons
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132 | if mean(diag(+K)) < 1,
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133 | tol = 1e-12;
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134 | else
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135 | tol = 1e-10;
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136 | end
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137 |
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138 | if ~issym(K,tol),
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139 | prwarning(1,'Kernel should be symmetric. It is made so by averaging.')
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140 | K = 0.5 * (K+K');
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141 | end
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142 |
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143 | eigmin = min(preig(K));
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144 | if eigmin < 0 & abs(eigmin) < 1e-12
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145 | disp(['Minimum eig(K) = ' num2str(eigmin) '. K might be indefinite due to numerical inaccuracies.']);
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146 | end
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147 |
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148 |
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149 | Kme = mean(K,2)';
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150 |
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151 | % Project the data such that the mean lies at the origin
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152 | H = -repmat(1/n,n,n);
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153 | H(1:n+1:end) = H(1:n+1:end) + 1; % H = eye(n) - ones(n,n)/n
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154 | K = H * K * H; % K is now a centered kernel
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155 | K = 0.5 * (K+K'); % Make sure that K is symmetric after centering
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156 |
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157 | [Q, L] = preig(K);
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158 | Q = real(Q);
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159 | l = diag(real(L));
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160 | [lm,Z] = sort(-abs(l));
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161 | Q = Q(:,Z);
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162 | l = l(Z);
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163 |
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164 | % Eigenvalues are now sorted by decreasing absolute value
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165 |
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166 | [J,sig] = seleigs(l,alf,prec); % J is the index of selected eigenvalues
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167 | L = l(J); % Eigenvalues
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168 | Q = Q(:,J); % Eigenvectors
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169 |
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170 | % Normalize Q such that the eigenvectors of the corresponding
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171 | % covariance matrix are J-orthonormal
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172 | QL = Q * diag(1./sqrt(abs(L)));
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173 |
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174 | % Determine the mapping
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175 | W = prmapping(mfilename,'trained',{QL,Kme,L,sig,prec},[],m,sum(sig));
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176 | W = setname(W,'IKPCA');
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177 | return
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