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<group> |
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<p><em>Maximally Stable Extremal Regions (MSER)</em> is a feature |
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detector; Like the <a href="tut.sift">SIFT detector</a>, the |
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MSER algorithm extracts from an image <code>I</code> a number of |
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co-variant regions, called MSERs. An MSER is a <em>stable</em> |
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connected component of some level sets of the |
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image <code>I</code>. Optionally, elliptical frames are attached to |
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the MSERs by fitting ellipses to the regions. For a more in-depth explanation |
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of the MSER detector, see our <a href="%pathto:root;api/mser_8h.html">API reference for MSER</a></p> |
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<ul> |
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<li><a href="%pathto:tut.mser.extract;">Extracting MSERs</a></li> |
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<li><a href="%pathto:tut.mser.param;">MSER parameters</a></li> |
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<li><a href="%pathto:tut.mser.conventions;">Conventions</a></li> |
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</ul> |
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<h1 id="tut.mser.extract">Extracting MSERs</h1> |
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<p>Each MSERs can be identified uniquely by (at least) one of its |
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pixels <code>x</code>, as the connected component of the level set at |
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level <code>I(x)</code> which contains <code>x</code>. Such a pixel is |
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called <em>seed</em> of the region.</p> |
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<p>To demonstrate the usage of the MATLAB command <code>vl_mser</code> |
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we open MATLAB and load a test image</p> |
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<pre> |
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pfx = fullfile(vl_root,'data','spots.jpg') ; |
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I = imread(pfx) ; |
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image(I) ; |
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</pre> |
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<div class="figure"> |
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<image src="%pathto:root;demo/mser_basic_0.jpg"/> |
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<div class="caption"> |
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<span class="content"> |
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A test image. |
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</span> |
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</div> |
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</div> |
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<p>We then convert the image to a format that is suitable for the |
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<code>vl_mser</code> command.</p> |
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<pre> |
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I = uint8(rgb2gray(I)) ; |
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</pre> |
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<p>We compute the region seeds and the elliptical frames by</p> |
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<pre> |
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[r,f] = vl_mser(I,'MinDiversity',0.7,... |
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'MaxVariation',0.2,... |
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'Delta',10) ; |
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</pre> |
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<p>We plot the region frames by</p> |
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<pre> |
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f = vl_ertr(f) ; |
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vl_plotframe(f) ; |
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</pre> |
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<p><code>vl_ertr</code> transposes the elliptical frame and is |
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required here because the <code>vl_mser</code> code assumes that the row index |
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is the first index, but the normal image convention assumes that this is the |
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<code>x</code> (column) index.</p> |
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<p>Plotting the MSERs themselves is a bit more involved as they have |
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arbitrary shape. To this end, we exploit two |
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functions: <code>vl_erfill</code>, which, given an image and a region |
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seed, returns a list of the pixels belonging to that region, and |
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the MATLAB built-in <code>contour</code>, which draws the contour lines |
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of a function. We start by</p> |
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<pre> |
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M = zeros(size(I)) ; |
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for x=r' |
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s = vl_erfill(I,x) ; |
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M(s) = M(s) + 1; |
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end |
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</pre> |
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<p>which computes a matrix <code>M</code> whose value are equal to the |
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number of overlapping extremal regions. Next, we use <code>M</code> |
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and <code>contour</code> to display the region boundaries:</p> |
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<pre> |
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figure(2) ; |
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clf ; imagesc(I) ; hold on ; axis equal off; colormap gray ; |
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[c,h]=contour(M,(0:max(M(:)))+.5) ; |
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set(h,'color','y','linewidth',3) ; |
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</pre> |
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<div class="figure"> |
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<image src="%pathto:root;demo/mser_basic_contours.jpg"/> |
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<image src="%pathto:root;demo/mser_basic_frames.jpg"/> |
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<div class="caption"> |
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<span class="content"> |
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Extracted MSERs (left) and fitted ellipses (right). |
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</span> |
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</div> |
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</div> |
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<p>Notice that we only find dark-on-bright regions by default. To include |
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bright-on-dark regions we simply repeat the process with <code>255-I</code>. |
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</p> |
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<pre> |
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[r,f] = vl_mser(uint8(255-I),'MinDiversity',0.7,'MaxVariation',0.2,'Delta',10) ; |
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</pre> |
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<div class="figure"> |
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<image src="%pathto:root;demo/mser_basic_contours_both.jpg"/> |
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<image src="%pathto:root;demo/mser_basic_frames_both.jpg"/> |
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<div class="caption"> |
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<span class="content"> |
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Extracted MSERs (left) and fitted ellipses (right) for both bright-on-dark |
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(green) and dark-on-bright (yellow). |
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</span> |
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</div> |
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</div> |
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<h1 id="tut.mser.param">MSER parameters</h1> |
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<p>In the original formulation, MSERs are controlled by a single |
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parameter <code>Δ</code>, which controls how the stability is |
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calculated. Its effect is shown in the figure below.</p> |
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<div class="figure"> |
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<image src="%pathto:root;demo/mser_delta_0.jpg"/> |
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<image src="%pathto:root;demo/mser_delta_1.jpg"/> |
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<image src="%pathto:root;demo/mser_delta_2.jpg"/> |
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<image src="%pathto:root;demo/mser_delta_3.jpg"/> |
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<image src="%pathto:root;demo/mser_delta_4.jpg"/> |
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<div class="caption"> |
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<span class="content"> |
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<b>Effect of <code>Δ</code>.</b> We start with a synthetic |
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image which has an intensity profile as shown. The bumps have |
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heights equal to 32, 64, 96, 128 and 160. As we increase |
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<code>Δ</code>, fewer and fewer regions are detected until |
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finally at <code>Δ=160</code> there is no region |
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<code>R</code> which is stable at <code>R(+Δ)</code>. |
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</span> |
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</div> |
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</div> |
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<p>The stability of an extremal region <code>R</code> is the inverse |
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of the relative area variation of the region <code>R</code> when the |
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intensity level is increased by <code>Δ</code>. Formally, the |
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variation is defined as:</p> |
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<pre> |
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|R(+Δ) - R| |
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----------- |
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|R| |
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</pre> |
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<p>where <code>|R|</code> denotes the area of the extremal region |
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<code>R</code>, <code>R(+Δ)</code> is the extremal region |
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<code>+Δ</code> levels up which contains <code>R</code> and |
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<code>|R(+Δ) - R|</code> is the area difference of the two |
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regions. </p> |
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<p>A stable region has a small variation. The algorithm finds regions which |
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are "maximally stable", meaning that they have a lower variation |
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than the regions one level below or above. Note that due to the |
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discrete nature of the image, the region below / above may be |
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coincident with the actual region, in which case the region is still |
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deemed maximal.</p> |
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<p>However, even if an extremal region is maximally stable, it might be |
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rejected if:</p> |
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<ul> |
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<li>it is too big (see the parameter <code>MaxArea</code>);</li> |
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<li>it is too small (see the parameter <code>MinArea</code>);</li> |
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<li>it is too unstable (see the parameter <code>MaxVariation</code>);</li> |
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<li>it is too similar to its parent MSER (see the |
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parameter <code>MinDiversity</code>).</li> |
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</ul> |
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<h1 id="tut.mser.conventions">Conventions</h1> |
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<p>As mentioned in the introduction, <code>vl_mser</code> uses |
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matrix indices as image coordinates. Compared to the usual MATLAB |
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convention for images, this means that the <code>x</code> |
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and <code>y</code> axis are swapped (this has been done to make the |
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convention consistent with images with three or more dimensions). Thus |
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the frames computed by the program may need to be "transposed" as |
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in:</p> |
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<pre> |
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[r,f] = vl_mser(I) ; |
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f = vl_ertr(f) ; |
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</pre> |
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<p>On the other hand, the region seeds <code>r</code> are already in |
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row major format, which is the standard MATLAB format for pixel |
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indices.</p> |
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<p>Instead of transposing the frames, one can start by transposing |
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the image. In this case, the frames <code>f</code> have the standard |
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image convention, but the region seeds are in column-major format and |
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may need to be "transposed" as in:</p> |
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<pre> |
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[r,f] = vl_mser(I') ; |
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[i,j] = sub2ind(size(I'),r) ; |
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r = ind2sub(size(I),j,i) ; |
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</pre> |
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<p>The command line utility <code>mser</code> uses the normal image |
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convention (because images are rasterized in column-major |
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order). Therefore the image frames are in the standard format, and the |
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region seeds are in column major format.</p> |
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<p>In order to convert from the command line utility convention to |
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the MATLAB convention one needs also to recall that MATLAB coordinates |
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starts from (1,1), but the command line utility uses the more common |
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convention (0,0). For instance, let the files <code>image.frame</code> |
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and <code>image.seed</code> contain the feature frames and seeds in |
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ASCII format as generated by the command line utility. Then</p> |
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<pre> |
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r_ = load('image.seed')' + 1 ; |
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f_ = load('image.frame')' ; |
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f_(1:2,:) = f_(1:2,:) + 1 ; |
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[r,f] = vl_mser(I') ; % notice the transpose |
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</pre> |
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<p>produces identical (up to numerical noise) region |
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seeds <code>r</code> and <code>r_</code> and frames <code>f</code> |
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and <code>f_</code>.</p> |
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</group> |
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