-
Notifications
You must be signed in to change notification settings - Fork 36
/
repeatabilityDemo.m
276 lines (227 loc) · 9.82 KB
/
repeatabilityDemo.m
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
function repeatabilityDemo(resultsPath)
% REPEATABILITYDEMO Demonstrates how to run the repatability benchmark
% REPEATABILITYDEMO() Runs the repeatability demo.
%
% REPEATABILITYDEMO(RESULTS_PATH) Run the demo and save the results to
% path RESULTS_PATH.
% Author: Karel Lenc and Andrea Vedaldi
% AUTORIGHTS
if nargin < 1, resultsPath = ''; end;
% --------------------------------------------------------------------
% PART 1: Image feature detectors
% --------------------------------------------------------------------
import datasets.*;
import benchmarks.*;
import localFeatures.*;
% The feature detector/descriptor code is encapsualted in a corresponding
% class. For example, VLFeatSift() encapslate the SIFT implementation in
% VLFeat.
%
% In addition to wrapping the detector code, each object instance
% contains a specific setting of parameters (for example, the
% cornerness threshold). In order to compare different parameter
% settings, one simply creates multiple instances of these objects.
siftDetector = VlFeatSift();
thrSiftDetector = VlFeatSift('PeakThresh',11);
% VLBenchmarks enables a simple access to a number of public
% benchmakrs. It also provides simple facilities to generate test data
% on the fly. Here we generate an image consiting of a number of
% Gaussian blobs and we save it to disk for use with the detectors.
ellBlobs = datasets.helpers.genEllipticBlobs('Width',500,'Height',500,...
'NumDeformations',4);
ellBlobsPath = 'ellBlobs.png';
imwrite(ellBlobs,ellBlobsPath);
% Next, we extract the features by running the detectors we
% prepared.
%
% VLBeanchmarks is smart. The detector output is cached (for each
% input image and parameter setting), so the next time the detector is
% called the output is read from disk rather than being comptued
% again. VLBenchmarks automatically checks whether the detector
% parameters, image, or code change based on their modification date
% and invalidates the cache if necessary. You can also invoke the
% disableCaching() method in each detector to prevent it from caching.
siftFrames = siftDetector.extractFeatures(ellBlobsPath);
thrSiftFrames = thrSiftDetector.extractFeatures(ellBlobsPath);
% Now show the frames
figure(1); clf;
imshow(ellBlobs);
siftHandle = vl_plotframe(siftFrames,'g');
thrSiftHandle = vl_plotframe(thrSiftFrames,'r','LineWidth',1);
legend([siftHandle thrSiftHandle],'SIFT','SIFT PT=10','Location','SE');
helpers.printFigure(resultsPath,'siftFrames',0.9);
% --------------------------------------------------------------------
% PART 2: Detector repeatability
% --------------------------------------------------------------------
% A detector repeatability is measured against a benchmark. In this
% case we create an instance of the VGG Affine Testbed (graffity
% sequence).
dataset = datasets.VggAffineDataset('Category','graf');
% Next, the benchmark is intialised by choosing various
% parameters. The defaults correspond to the seetting in the original
% publication (IJCV05).
repBenchmark = RepeatabilityBenchmark('Mode','Repeatability');
% Prepare three detectors, the two from PART 1 and a third one that
% detects MSER image features.
mser = VlFeatMser();
featExtractors = {siftDetector, thrSiftDetector, mser};
% Now we are ready to run the repeatability test. We do this by fixing
% a reference image A and looping through other images B in the
% set. To this end we use the following information:
%
% dataset.NumImages:
% Number of images in the dataset.
%
% dataset.getImagePath(i):
% Path to the i-th image.
%
% dataset.getTransformation(i):
% Transformation from the first (reference) image to image i.
%
% Like for the detector output (see PART 1), VLBenchmarks caches the
% output of the test. This can be disabled by calling
% repBenchmark.disableCaching().
repeatability = [];
numCorresp = [];
imageAPath = dataset.getImagePath(1);
for d = 1:numel(featExtractors)
for i = 2:dataset.NumImages
[repeatability(d,i) numCorresp(d,i)] = ...
repBenchmark.testFeatureExtractor(featExtractors{d}, ...
dataset.getTransformation(i), ...
dataset.getImagePath(1), ...
dataset.getImagePath(i));
end
end
% The scores can now be prented, as well as visualized in a
% graph. This uses two simple functions defined below in this file.
detectorNames = {'SIFT','SIFT PT=10','MSER'};
printScores(detectorNames, 100 * repeatability, 'Repeatability');
printScores(detectorNames, numCorresp, 'Number of correspondences');
figure(2); clf;
plotScores(detectorNames, dataset, 100 * repeatability, 'Repeatability');
helpers.printFigure(resultsPath,'repeatability',0.6);
figure(3); clf;
plotScores(detectorNames, dataset, numCorresp, 'Number of correspondences');
helpers.printFigure(resultsPath,'numCorresp',0.6);
% Optionally, we can also see the matched frames itself. In this
% example we examine the matches between the reference and fourth
% image.
%
% We do this by running the repeatabiltiy score again. However, since
% the results are cached, this is fast.
imageBIdx = 3;
[drop drop siftCorresps siftReprojFrames] = ...
repBenchmark.testFeatureExtractor(siftDetector, ...
dataset.getTransformation(imageBIdx), ...
dataset.getImagePath(1), ...
dataset.getImagePath(imageBIdx));
% And plot the feature frame correspondences
figure(4); clf;
imshow(dataset.getImagePath(imageBIdx));
benchmarks.helpers.plotFrameMatches(siftCorresps,...
siftReprojFrames,...
'IsReferenceImage',false,...
'PlotMatchLine',false,...
'PlotUnmatched',false);
helpers.printFigure(resultsPath,'correspondences',0.75);
% --------------------------------------------------------------------
% PART 3: Detector matching score
% --------------------------------------------------------------------
% The matching score is similar to the repeatability score, but
% involves computing a descriptor. Detectors like SIFT bundle a
% descriptor as well. However, most of them (e.g. MSER) do not have an
% associated descriptor (e.g. MSER). In this case we can bind one of
% our choice by using the DescriptorAdapter class.
%
% In this particular example, the object encapsulating the SIFT
% detector is used as descriptor form MSER.
mserWithSift = DescriptorAdapter(mser, siftDetector);
featExtractors = {siftDetector, thrSiftDetector, mserWithSift};
% We create a benchmark object and run the tests as before, but in
% this case we request that descriptor-based matched should be tested.
matchingBenchmark = RepeatabilityBenchmark('Mode','MatchingScore');
matchScore = [];
numMatches = [];
for d = 1:numel(featExtractors)
for i = 2:dataset.NumImages
[matchScore(d,i) numMatches(d,i)] = ...
matchingBenchmark.testFeatureExtractor(featExtractors{d}, ...
dataset.getTransformation(i), ...
dataset.getImagePath(1), ...
dataset.getImagePath(i));
end
end
% Print and plot the results
detectorNames = {'SIFT','SIFT PT=10','MSER with SIFT'};
printScores(detectorNames, matchScore*100, 'Match Score');
printScores(detectorNames, numMatches, 'Number of matches') ;
figure(5); clf;
plotScores(detectorNames, dataset, matchScore*100,'Matching Score');
helpers.printFigure(resultsPath,'matchingScore',0.6);
figure(6); clf;
plotScores(detectorNames, dataset, numMatches,'Number of matches');
helpers.printFigure(resultsPath,'numMatches',0.6);
% Same as with the correspondences, we can plot the matches based on
% feature frame descriptors. The code is nearly identical.
imageBIdx = 3;
[r nc siftCorresps siftReprojFrames] = ...
matchingBenchmark.testFeatureExtractor(siftDetector, ...
dataset.getTransformation(imageBIdx), ...
dataset.getImagePath(1), ...
dataset.getImagePath(imageBIdx));
figure(7); clf;
imshow(imread(dataset.getImagePath(imageBIdx)));
benchmarks.helpers.plotFrameMatches(siftCorresps,...
siftReprojFrames,...
'IsReferenceImage',false,...
'PlotMatchLine',false,...
'PlotUnmatched',false);
helpers.printFigure(resultsPath,'matches',0.75);
% --------------------------------------------------------------------
% Helper functions
% --------------------------------------------------------------------
function printScores(detectorNames, scores, name)
numDetectors = numel(detectorNames);
maxNameLen = length('Method name');
for k = 1:numDetectors
maxNameLen = max(maxNameLen,length(detectorNames{k}));
end
fprintf(['\n', name,':\n']);
formatString = ['%' sprintf('%d',maxNameLen) 's:'];
fprintf(formatString,'Method name');
for k = 2:size(scores,2)
fprintf('\tImg#%02d',k);
end
fprintf('\n');
for k = 1:numDetectors
fprintf(formatString,detectorNames{k});
for l = 2:size(scores,2)
fprintf('\t%6s',sprintf('%.2f',scores(k,l)));
end
fprintf('\n');
end
end
function plotScores(detectorNames, dataset, score, titleText)
xstart = max([find(sum(score,1) == 0, 1) + 1 1]);
xend = size(score,2);
xLabel = dataset.ImageNamesLabel;
xTicks = dataset.ImageNames;
plot(xstart:xend,score(:,xstart:xend)','+-','linewidth', 2); hold on ;
ylabel(titleText) ;
xlabel(xLabel);
set(gca,'XTick',xstart:1:xend);
set(gca,'XTickLabel',xTicks);
title(titleText);
set(gca,'xtick',1:size(score,2));
maxScore = max([max(max(score)) 1]);
meanEndValue = mean(score(:,xend));
legendLocation = 'SouthEast';
if meanEndValue < maxScore/2
legendLocation = 'NorthEast';
end
legend(detectorNames,'Location',legendLocation);
grid on ;
axis([xstart xend 0 maxScore]);
end
end