Mercurial > hg > smallbox
comparison Problems/private/dictdist.m @ 61:42fcbcfca132
(none)
author | idamnjanovic |
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date | Tue, 15 Mar 2011 12:21:31 +0000 |
parents | 207a6ae9a76f |
children |
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60:ad36f80e2ccf | 61:42fcbcfca132 |
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1 function [dist,ratio] = dictdist(approxD,D,epsilon) | |
2 %DICTDIST Distance between dictionaries. | |
3 % [DIST,RATIO] = DICTDIST(APPROXD,D) computes the distance between the | |
4 % approximate dictionary APPROXD and the true dictionary D, where APPROXD | |
5 % is NxK and D is NxM. | |
6 % | |
7 % The distance between the dictionary APPROXD and a single atom A of D is | |
8 % defined as: | |
9 % | |
10 % DIST(APPROXD,A) = min { 1-abs(APPROXD(:,i)' * A) } | |
11 % i | |
12 % | |
13 % The distance between the dictionaries APPROXD and D is defined as: | |
14 % | |
15 % DIST(APPROXD,D) = sum { dist(APPROXD, D(:,k)) } / M | |
16 % k | |
17 % | |
18 % Note that 0 <= DIST(APPROXD,D) <= 1, where 0 implies that all atoms in D | |
19 % appear in APPROXD, and 1 implies that the atoms of D are orthogonal to | |
20 % APPROXD. | |
21 % | |
22 % The similarity ratio between APPROXD and D is defined as: | |
23 % | |
24 % RATIO(APPROXD,D) = #(atoms in D that appear in APPROXD) / M | |
25 % | |
26 % where two atoms are considered identical when DIST(A1,A2) < EPSILON with | |
27 % EPSILON=0.01 by default. Note that 0 <= RATIO(APPROXD,D) <= 1, where 0 | |
28 % means APPROXD and D have no identical atoms, and 1 means that all atoms | |
29 % of D appear in APPROXD. | |
30 % | |
31 % [DIST,RATIO] = DICTDIST(DICT1,DICT2,EPSILON) specifies a different value | |
32 % for EPSILON. | |
33 | |
34 % Ron Rubinstein | |
35 % Computer Science Department | |
36 % Technion, Haifa 32000 Israel | |
37 % ronrubin@cs | |
38 % | |
39 % October 2007 | |
40 | |
41 | |
42 if (nargin < 3), epsilon = 0.01; end | |
43 | |
44 [n,m] = size(D); | |
45 | |
46 approxD = normcols(approxD*spdiag(sign(approxD(1,:)))); | |
47 D = normcols(D*spdiag(sign(D(1,:)))); | |
48 | |
49 identical_atoms = 0; | |
50 dist = 0; | |
51 | |
52 for i = 1:m | |
53 atom = D(:,i); | |
54 distances = 1-abs(atom'*approxD); | |
55 mindist = min(distances); | |
56 dist = dist + mindist; | |
57 identical_atoms = identical_atoms + (mindist < epsilon); | |
58 end | |
59 | |
60 dist = dist / m; | |
61 ratio = identical_atoms / m; |