[1] | 1 | %DMSTSPM Find the Shortest Paths along K Minimum Spanning Trees
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| 2 | %
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| 3 | % W = DMSTSPM (D,K,P)
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| 4 | %
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| 5 | % INPUT
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| 6 | % D NxN Symmetric dissimilarity matrix or dataset
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| 7 | % K Number of minimum spanning trees; (optional; default: 1)
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| 8 | % P Object number, P = 1..N;
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| 9 | % (optional; default: P with the largest distances to all other objects)
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| 10 | %
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| 11 | % OUTPUT
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| 12 | % W Mapping that determines the shortest paths
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| 13 | %
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| 14 | % DESCRIPTION
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| 15 | % Determines the shortest paths along a neighborhood graph defined by K minimum
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| 16 | % spanning trees. MSTs are found by the Prim's algorithm, starting from the
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| 17 | % point P. The result, however, does not depend on P. New vertices are projected
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| 18 | % on an edge of the existing neighborhood graph such that the distances
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| 19 | % between a new object and the vertices of this edge are the smallest. Then,
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| 20 | % the distances along the shortest paths are computed.
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| 21 | %
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| 22 | % DEFAULT
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| 23 | % K = 1
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| 24 | % P = max(dist)
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| 25 | %
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| 26 | % SEE ALSO
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| 27 | % KMST, DSPATH, DSPATHS
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| 28 |
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| 29 | % Elzbieta Pekalska, ela.pekalska@googlemail.com
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| 30 | % Faculty of EWI, Delft University of Technology, The Netherlands and
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| 31 | % School of Computer Science, University of Manchester
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| 32 |
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| 33 |
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| 34 |
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| 35 |
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| 36 | function W = dmstspm(D,K,p)
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| 37 |
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| 38 | if nargin < 3 | isempty(p),
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| 39 | [ss,p]= max(sum(+D));
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| 40 | end
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| 41 | if nargin < 2 | isempty(K),
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| 42 | K = 1;
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| 43 | end
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| 44 | if nargin < 1 | isempty(D)
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| 45 | W = mapping(mfilename,{K,p});
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| 46 | W = setname(W,'dmstspm');
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| 47 | return
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| 48 | end
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| 49 |
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| 50 |
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| 51 | if isdataset(D) | isa(D,'double'),
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| 52 |
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| 53 | if ismapping(K),
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| 54 | n_orig = getsize_in(K);
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| 55 | pars = getdata(K);
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| 56 |
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| 57 | L = pars{1}; % list of edges in the MSTs
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| 58 | dm = pars{2}; % weights of the edges
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| 59 | K = pars{3}; % number of MSTs
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| 60 |
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| 61 | W = D;
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| 62 | D = +D;
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| 63 | [m,n] = size(D);
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| 64 | if n ~= n_orig,
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| 65 | error('The number of columns in the test data does not match.')
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| 66 | end
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| 67 |
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| 68 | is_porig = (m > n & sum(diag(+D(1:n,:)))<=1e-16);
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| 69 | is_orig = (m == n & sum(diag(+D))<=1e-16);
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| 70 |
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| 71 | LL = [L; L(:,[2 1])];
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| 72 | ddm = [dm; dm];
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| 73 | DD = inf * ones(n_orig);
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| 74 | DD((LL(:,2)-1)*n_orig+LL(:,1)) = ddm;
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| 75 | DD(1:n_orig+1:end)=0;
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| 76 |
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| 77 | if is_orig | is_porig, % if (a part of) test data is the original distance matrix
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| 78 | Dp = dspaths(DD);
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| 79 | end
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| 80 |
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| 81 | if ~is_orig,
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| 82 | if is_porig,
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| 83 | pos = n;
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| 84 | Dp = [Dp; zeros(m-n,n)];
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| 85 | else
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| 86 | pos = 0;
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| 87 | Dp = zeros(m,n);
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| 88 | end
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| 89 |
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| 90 | dmn = zeros(m-pos,2);
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| 91 | dd = zeros(m-pos,1);
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| 92 | Ln = zeros(m-pos,2);
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| 93 | D = D(pos+1:m,:);
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| 94 |
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| 95 | [dmin,I] = min(D,[],2);
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| 96 | LL = L(:);
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| 97 | for i=1:length(I)
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| 98 | J = find(LL == I(i));
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| 99 | [dd(i),z] = min(ddm(J));
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| 100 | Ln(i,1:2) = [I(i) LL(J(z))];
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| 101 | end
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| 102 |
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| 103 | % Use the cosine law to determine the distances of the points
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| 104 | % projected onto the closest edge
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| 105 | X = (dmin.^2 + dd.^2 - D(Ln(I,2)*(m-pos)+I).^2) ./(2*dd);
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| 106 | dmn = [X dd-X];
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| 107 | Z = find(X < 0); % make corrections if distances are negative
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| 108 | if ~isempty(Z)
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| 109 | dmn(Z,:) = [-X(Z) dd(Z)-X(Z)];
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| 110 | end
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| 111 | Z = find(X > dd); % make corrections if distances are too large
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| 112 | if ~isempty(Z)
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| 113 | dmn(Z,:) = [X(Z) -dd(Z)+X(Z)];
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| 114 | end
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| 115 |
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| 116 | for i=1:length(I)
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| 117 | dnew = inf*ones(1,n);
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| 118 | dnew(Ln(i,:)) = dmn(i,:);
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| 119 | Q = dspaths([DD dnew'; dnew 0]); % Floyd's algorithm is used, since it is fast in Matlab
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| 120 | Dp(pos+i,:) = Q(n+1,1:n);
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| 121 | end
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| 122 | end
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| 123 |
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| 124 |
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| 125 | if isdataset(W),
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| 126 | W = setdata(W,Dp);
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| 127 | else
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| 128 | W = Dp;
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| 129 | end
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| 130 | return;
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| 131 |
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| 132 | else
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| 133 |
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| 134 | D = +D;
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| 135 | [n,m] = size(D);
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| 136 | if n ~= m | ~issym(D,1e-12),
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| 137 | error('D should be symmetric.')
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| 138 | end
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| 139 | D = 0.5*(D+D');
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| 140 |
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| 141 | [Lmst,d] = kdmst(D,K,p);
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| 142 | W = mapping(mfilename,'trained',{Lmst,d,K},[],n,n);
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| 143 | W = setname(W,'dmstspm');
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| 144 | end
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| 145 | end
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| 146 | return;
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