source: prextra/inckernel.m @ 33

Last change on this file since 33 was 5, checked in by bduin, 14 years ago
File size: 2.8 KB
Line 
1function K = inckernel(par,I,J);
2%INCKERNEL Kernel definition for incsvdd
3%
4%              K = INCKERNEL(PAR,I,J);
5%
6% Computation of the kernel function for the incremental SVDD. It is
7% assumed that there is a global variable X_incremental, containing the
8% objects. This is to avoid unnecessary overhead for very large
9% datasets. Therefore we will also not use the 'standard' ways to comute
10% the kernel (i.e. proxm).
11%
12% The kernel is defined by PAR.  We assume that PAR is a structure
13% containing:
14%  PAR.type   the kernel type
15%       'kernel'       | 'k': X_incremental(I,J)
16%       'polynomial'   | 'p': sign(xI*xJ'+1).*(xI*xJ'+1).^s
17%       'exponential'  | 'e': exp(-(||xI-xJ||)/s)
18%       'radial_basis' | 'r': exp(-(||xI-xJ||.^2)/(s*s))
19%       'sigmoid'      | 's': sigm((sign(xI*xJ').*(xI*xJ'))/s)
20%       'distance'     | 'd': ||xI-xJ||.^s
21% And the special case:
22%       'inline'       | 'i': use s as an inline function
23%  PAR.s      the free parameter,
24%             when more than 1 free parameter is required, then par.s
25%             can be a vector of length 2 or more.
26% The index vectors I and J indicate between which objects in
27% X_incremental the kernel should be computed.
28%
29% See also: incsvdd, proxm
30
31% Copyright: D. Tax, R.P.W. Duin, davidt@ph.tn.tudelft.nl
32% Faculty of Applied Physics, Delft University of Technology
33% P.O. Box 5046, 2600 GA Delft, The Netherlands
34
35if nargin<2
36        I = [];
37        J = [];
38end
39
40global X_incremental;
41if isempty(X_incremental)
42  error('No data matrix X_incremental defined');
43end
44if isa(X_incremental,'dataset');
45  error('Please make X_incremental a normal matlab array');
46end
47
48A = X_incremental(I,:);
49B = X_incremental(J,:);
50
51switch par.type
52case {'kernel' 'k'}
53        if isempty(I) & isempty(J)
54                K = X_incremental;
55        else
56                K = X_incremental(I,J);
57        end
58case {'polynomial' 'p'}
59        K = A*B';
60        [n,d] = size(A);
61        [m,d] = size(B);
62        if par.s ~= round(par.s)
63                K = K + ones(n,m);
64                K = sign(K).*abs(K).^par.s;
65        elseif par.s ~= 1
66                K = K + ones(n,m);
67                K = K.^par.s;
68        end
69case {'sigmoid' 's'}
70        K = A*B';
71        if length(par.s)>1
72                K = sigm(K/par.s(1) + par.s(2));   %DXD: I need this sometimes
73        else
74                K = sigm(K/par.s);
75        end
76case {'exponential' 'e'}
77        K = sqeucldistm(A,B);
78        J = find(K<0);
79        K(J) = zeros(size(J));
80        K = exp(-sqrt(K)/par.s);
81case {'radial_basis' 'r'}
82        K = sqeucldistm(A,B);
83        J = find(K<0);
84        K(J) = zeros(size(J));
85        K = exp(-K/(par.s*par.s));
86case {'inv_radial_basis' 'i'}
87        K = sqeucldistm(A,B);
88        J = find(K<0);
89        K(J) = zeros(size(J));
90        K = exp(sqrt(K)/par.s);
91case {'distance' 'd'}
92        K = sqeucldistm(A,B);
93        J = find(K<0);
94        K(J) = zeros(size(J));
95        if par.s ~= 2
96                K = K.^(par.s/2);
97        end
98case {'inline' 'i'}
99        error('Sorry, this does not work yet.');
100case {'combp1s2'}
101        K = sqeucldistm(A,B);
102        J = find(K<0);
103        K(J) = zeros(size(J));
104        K = exp(-K/(2*2));
105        K = par.s*A*B' + (1-par.s)*K;
106otherwise
107        error(sprintf('Unknown proximity type: %s',par.type))
108end
109
110return
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