machinevision-toolbox-matlabMachine Vision Toolbox for MATLAB
Synopsis
Machine Vision Toolbox for MATLAB® release 4.
The Machine Vision Toolbox (MVTB) provides many functions that are useful in machine vision and vision-based control. It is a somewhat eclectic collection reflecting my personal interest in areas of photometry, photogrammetry, colorimetry. It includes over 100 functions spanning operations such as image file reading and writing, acquisition, display, filtering, blob, point and line feature extraction, mathematical morphology, homographies, visual Jacobians, camera calibration and color space conversion. With input from a web camera and output to a robot (not provided) it would be possible to implement a visual servo system entirely in MATLAB.
An image is usually treated as a rectangular array of scalar values representing intensity or perhaps range. The matrix is the natural datatype for MATLAB and thus makes the manipulation of images easily expressible in terms of arithmetic statements in MATLAB language. Many image operations such as thresholding, filtering and statistics can be achieved with existing MATLAB functions.
Advantages of the Toolbox are that:
- the code is mature and provides a point of comparison for other implementations of the same algorithms;
- the routines are generally written in a straightforward manner which allows for easy understanding, perhaps at the expense of computational efficiency. If you feel strongly about computational efficiency then you can always rewrite the function to be more efficient, compile the M-file using the MATLAB compiler, or create a MEX version;
- since source code is available there is a benefit for understanding and teaching.
Code Examples
Binary blobs
>> im = iread('shark2.png'); % read a binary image of two sharks
>> idisp(im); % display it with interactive viewing tool
>> f = iblobs(im, 'class', 1) % find all the white blobs
f =
(1) area=7827, cent=(172.3,156.1), theta=-0.21, b/a=0.585, color=1, label=2, touch=0, parent=1
(2) area=7827, cent=(372.3,356.1), theta=-0.21, b/a=0.585, color=1, label=3, touch=0, parent=1
>> f.plot_box('g') % put a green bounding box on each blob
>> f.plot_centroid('o'); % put a circle+cross on the centroid of each blob
>> f.plot_centroid('x');
Binary blob hierarchy
We can load a binary image with nested objects
>> im = iread('multiblobs.png');
>> idisp(im)
and request the blob label image which we then display
>> [label, m] = ilabel(im);
>> idisp(label, 'colormap', jet, 'bar')
Camera modelling
>> cam = CentralCamera('focal', 0.015, 'pixel', 10e-6, ...
'resolution', [1280 1024], 'centre', [640 512], 'name', 'mycamera')
cam =
name: mycamera [central-perspective]
focal length: 0.015
pixel size: (1e-05, 1e-05)
principal pt: (640, 512)
number pixels: 1280 x 1024
pose: t = (0, 0, 0), RPY/yxz = (0, 0, 0) deg
and its intrinsic parameters are
>> cam.K
ans =
1.0e+03 *
1.5000 0 0.6400
0 1.5000 0.5120
0 0 0.0010
We can define an arbitrary point in the world
>> P = [0.3, 0.4, 3.0]';
and then project it into the camera
>> cam.project(P)
ans =
790
712
which is the corresponding coordinate in pixels. If we shift the camera slightly the image plane coordiante will also change
>> cam.project(P, 'pose', SE3(0.1, 0, 0) )
ans =
740
712
We can define an edge-based cube model and project it into the camera's image plane
>> [X,Y,Z] = mkcube(0.2, 'pose', SE3(0, 0, 1), 'edge');
>> cam.mesh(X, Y, Z);
or with a fisheye camera
>> cam = FishEyeCamera('name', 'fisheye', ...
'projection', 'equiangular', ...
'pixel', 10e-6, ...
'resolution', [1280 1024]);
>> [X,Y,Z] = mkcube(0.2, 'centre', [0.2, 0, 0.3], 'edge');
>> cam.mesh(X, Y, Z);
Bundle adjustment
Color space
Plot the CIE chromaticity space
showcolorspace('xy')
lambda = [460:10:540 560:20:600];
[x,y]=lambda2xy(lambda*1e-9);
hold on
plot_point([x y]', 'printf', {' %d', lambda}, 'ko', 'MarkerFaceColor', 'k', 'MarkerSize', 6)
Load the spectrum of sunlight at the Earth's surface and compute the CIE xy chromaticity coordinates
lambda = [400:5:700] * 1e-9; % visible light
sun_at_ground = loadspectrum(lambda, 'solar');
>> lambda2xy(lambda, sun_at_ground)
ans =
0.3327 0.3454
>> colorname(ans, 'xy')
loading rgb.txt
ans =
'antiquewhite4'
Hough transform
im = iread('church.png', 'grey', 'double');
edges = icanny(im);
h = Hough(edges, 'suppress', 10);
lines = h.lines();
idisp(im, 'dark');
lines(1:10).plot('g');
lines = lines.seglength(edges);
lines(1)
k = find( lines.length > 80);
lines(k).plot('b--')
SURF features
We load two images and compute a set of SURF features for each
>> im1 = iread('eiffel2-1.jpg', 'mono', 'double');
>> im2 = iread('eiffel2-2.jpg', 'mono', 'double');
>> sf1 = isurf(im1);
>> sf2 = isurf(im2);
We can match features between images based purely on the similarity of the features, and display the correspondences found
>> m = sf1.match(sf2)
m =
644 corresponding points (listing suppressed)
>> m(1:5)
ans =
(819.56, 358.557) <-> (708.008, 563.342), dist=0.002137
(1028.3, 231.748) <-> (880.14, 461.094), dist=0.004057
(1027.6, 571.118) <-> (885.147, 742.088), dist=0.004297
(927.724, 509.93) <-> (800.833, 692.564), dist=0.004371
(854.35, 401.633) <-> (737.504, 602.187), dist=0.004417
>> idisp({im1, im2})
>> m.subset(100).plot('w')
Clearly there are some bad matches here, but we we can use RANSAC and the epipolar constraint implied by the fundamental matrix to estimate the fundamental matrix and classify correspondences as inliers or outliers
>> F = m.ransac(@fmatrix, 1e-4, 'verbose')
617 trials
295 outliers
0.000145171 final residual
F =
0.0000 -0.0000 0.0087
0.0000 0.0000 -0.0135
-0.0106 0.0116 3.3601
>> m.inlier.subset(100).plot('g')
>> hold on
>> m.outlier.subset(100).plot('r')
>> hold off
where green lines show correct correspondences (inliers) and red lines show bad correspondences (outliers)
Fundamental matrix
What's new
- Travis CI is now running on the code base
- All code related to pose representation has been split out into the Spatial Math Toolbox. This repo is now a dependency.
Installation
Install from shared MATLAB Drive folder
This will work for MATLAB Online or MATLAB Desktop provided you have MATLAB drive setup.
- Click on the appropriate link below and an invitation to share will be emailed to the address associated with your MATLAB account:
- Accept the invitation.
- A folder named RVC1 or RVC2 will appear in your MATLAB drive folder.
- Use the MATLAB file browser and navigate to the folder RVCx/rvctools and double-click the script named startup_rvc.m
Note that this is a combo-installation that includes the Robotics Toolbox (RTB) as well.
Install from github
You need to have a recent version of MATLAB, R2016b or later.
The Machine Vision Toolbox for MATLAB has dependency on two other GitHub repositories: spatial-math
and toolbox-common-matlab
.
To install the Toolbox on your computer from github follow these simple instructions.
From the shell:
mkdir rvctools
cd rvctools
git clone https://github.com/petercorke/machinevision-toolbox-matlab.git vision
git clone https://github.com/petercorke/spatial-math.git smtb
git clone https://github.com/petercorke/toolbox-common-matlab.git common
make -C vision
The last command builds the MEX files. Then, from within MATLAB
>> addpath rvctools/common % rvctools is the same folder as above
>> startup_rvc
The second line sets up the MATLAB path appropriately but it's only for the current session. You can either:
- Repeat this everytime you start MATLAB
- Add the MATLAB commands above to your
startup.m
file - Once you have run startup_rvc, run
pathtool
and push theSave
button, this will save the path settings for subsequent sessions.
Downloading the example images
The Robotics, Vision & Control book (2nd edition) uses a number of example images and image sequences. These are bulky and not really appropriate to keep on Github but you can download them. There are two zip archives:
Archive | Size | Contents |
---|---|---|
images-RVC2a.zip | 74M | All images, seq/*, mosaic/*, campus/* |
images-RVC2a.zip | 255M | Chapter 14: bridge-l/*, bridge-r/* |
Each will expand into the ./images
folder which is the default location that MVTB searches for images and sequences.
To download the main (and smaller) archive
cd rvctools/vision
wget petercorke.com/files/MVTB/images-RVC2a.zip
unzip images-RVC2a
To download the second (and larger) archive
cd rvctools/vision
wget petercorke.com/files/MVTB/images-RVC2b.zip
unzip images-RVC2b
Download the contributed code
Some MVTB functions are wrappers of third-party open-source software. Working versions, some patched, can be downloaded below. If you are not using MacOS you will need to rebuild the code.
Archive | Size | Contents |
---|---|---|
contrib.zip | 16M | vl_feat, graphseg, EPnP, camera calibration |
contrib2.zip | 5M | SIFT, SURF |
The packages, and their home pages are
Tool | Author | MVTB function |
---|---|---|
OpenSurf | isurf |
|
SIFT | isift |
|
vl_feat | A. Vedaldi and B. Fulkerson | imser , isift , BagOfWords |
graphseg | P. Felzenszwalb, D. Huttenlocher | igraphseg |
Efficient perspective-n-point camera pose estimation (EPnP) | V. Lepetit, F. Moreno-Noguer, P. Fua | CentralCamera.estpose |
Camera Calibration Toolbox for MATLAB | Jean-Yves Bouget | calib_gui |
Online resources:
Please email bug reports, comments or code contribtions to me at rvc@petercorke.com
Contributors
Contributions welcome. There's a user forum at http://tiny.cc/rvcforum
License
This toolbox is released under GNU LGPL.