[10] | 1 | %FASTMAPD Fast Linear Map of Euclidean distances |
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| 2 | % |
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| 3 | % W = FASTMAPD(D,K) |
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| 4 | % |
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| 5 | % INPUT |
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| 6 | % D NxN symmetric dissimilarity matrix (dataset) |
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| 7 | % K Chosen dimensionality (optional; K is automatically detected) |
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| 8 | % |
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| 9 | % OUTPUT |
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| 10 | % W Linear map of Euclidean distances D into a Euclidean space |
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| 11 | % |
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| 12 | % DEFAULT |
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| 13 | % K = [] |
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| 14 | % |
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| 15 | % DESCRIPTION |
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| 16 | % This is an implementation of the FastMap algorithm. D is assumed to be |
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| 17 | % a square Euclidean distance matrix and K is the desired dimensionality of |
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| 18 | % the projection. However, if the dimensionality M of the original data is |
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| 19 | % smaller than K, then only a mapping to a M-dimensional space is returned. |
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| 20 | % |
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| 21 | % If D does not have a Euclidean behavior, a projection is done to the fewest |
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| 22 | % dimensions that explain the Euclidean part the best, i.e. do not deal with |
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| 23 | % negative squared distances. |
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| 24 | % |
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| 25 | % LITERATURE |
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| 26 | % 1. C. Faloutsos and K.-I. Lin, FastMap: A Fast Algorithm for Indexing, |
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| 27 | % Data-Mining and Visualization of Traditional and Multimedia Datasets, |
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| 28 | % ACM SIGMOD, International Conference on Management of Data, 163-174, 1995. |
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| 29 | % |
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| 30 | |
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| 31 | % Copyright: Elzbieta Pekalska, ela.pekalska@googlemail.com |
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| 32 | % Faculty EWI, Delft University of Technology and |
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| 33 | % School of Computer Science, University of Manchester |
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| 34 | |
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| 35 | |
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| 36 | function [W,P] = fastmapd(D,K) |
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| 37 | |
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| 38 | if nargin < 2, |
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| 39 | K = []; |
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| 40 | end |
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| 41 | if nargin < 1 | isempty(D) |
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[79] | 42 | W = prmapping(mfilename,K); |
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[10] | 43 | W = setname(W,'Fastmapd'); |
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| 44 | return |
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| 45 | end |
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| 46 | |
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| 47 | |
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| 48 | if (isdataset(D) | isa(D,'double')) |
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| 49 | if ismapping(K), |
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| 50 | % APPLY THE MAPPING |
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| 51 | pars = getdata(K); |
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| 52 | P = pars{1}; |
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| 53 | dd = pars{2}; |
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| 54 | X = pars{3}; |
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| 55 | K = pars{4}; |
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| 56 | |
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| 57 | nlab = getnlab(D); |
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| 58 | n = size(D,1); |
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| 59 | D = +D.^2; |
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| 60 | if all(diag(D) == 0) & issym(D) & length(X) == n, |
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| 61 | Y = X; |
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| 62 | else |
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| 63 | for k=1:K |
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| 64 | Y(:,k) = (D(:,P(k,1)) + dd(k)*ones(n,1) - D(:,P(k,2)))./(2*sqrt(dd(k))); |
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| 65 | D = (D - distm(Y(:,k),X(:,k))); |
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| 66 | end |
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| 67 | end |
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[79] | 68 | W = prdataset(Y,nlab); |
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[10] | 69 | return |
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| 70 | end |
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| 71 | end |
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| 72 | |
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| 73 | |
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| 74 | |
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| 75 | |
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| 76 | |
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| 77 | % TRAIN THE MAPPING |
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| 78 | if isdataset(D) |
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| 79 | nlab = getnlab(D); |
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| 80 | end |
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| 81 | discheck(D); |
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| 82 | |
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| 83 | n = size(D,1); |
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| 84 | D = +D.^2; |
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| 85 | if isempty(K), |
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| 86 | K = n-1; |
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| 87 | end |
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| 88 | |
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| 89 | k = 0; % Current dimensionality |
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| 90 | Z = 1:n; % Index of points |
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| 91 | tol = 1e-12; % Tolerance when the distances become close to zero |
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| 92 | tolNE = 1e-10; % Tolerance for the non-Euclidean behavior |
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| 93 | NEucl = 0; % Non-Euclidean behavior |
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| 94 | finito = 0; |
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| 95 | |
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| 96 | while ~finito, |
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| 97 | k = k+1; |
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| 98 | [mm,O] = max((D(Z,Z)),[],2); |
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| 99 | [mm,i] = max(mm); |
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| 100 | P(k,1) = Z(O(i)); % P is the index of pivots |
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| 101 | P(k,2) = Z(i); |
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| 102 | Z([O(i) i]) = []; |
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| 103 | dd(k) = D(P(k,1),P(k,2)); |
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| 104 | |
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| 105 | if dd(k) >= tol, |
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| 106 | X(:,k) = (D(:,P(k,1)) + dd(k)*ones(n,1) - D(:,P(k,2)))./(2*sqrt(dd(k))); |
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| 107 | D = (D - distm(X(:,k))); |
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| 108 | else |
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| 109 | P(k,:) = []; |
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| 110 | end |
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| 111 | |
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| 112 | if ~NEucl, |
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| 113 | NEucl = NEucl | any(D(:) < -tolNE); |
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| 114 | if NEucl, |
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| 115 | KKe = k; |
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| 116 | KK = k; |
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| 117 | end |
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| 118 | end |
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| 119 | |
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| 120 | finito = (k >= K) | (dd(k) <= tol) | NEucl; |
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| 121 | end |
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| 122 | if ~NEucl, |
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| 123 | KK = k; |
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| 124 | end |
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| 125 | |
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| 126 | if NEucl, |
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| 127 | disp('Distances do not have a Euclidean behavior!'); |
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| 128 | disp(['The Euclidean part of the distances is explained in ' num2str(KKe) 'D.']); |
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| 129 | else |
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| 130 | if KK < K, |
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| 131 | disp(['The distances are perfectly explained in ' num2str(KK) 'D.']); |
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| 132 | end |
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| 133 | end |
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| 134 | |
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[79] | 135 | W = prmapping(mfilename,'trained',{P,dd,X,KK},[],n,KK); |
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[10] | 136 | W = setname(W,'Fastmapd'); |
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| 137 | return |
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| 138 | |
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| 139 | |
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| 140 | |
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