-
Notifications
You must be signed in to change notification settings - Fork 10
/
README.txt
116 lines (99 loc) · 6.61 KB
/
README.txt
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
NOTE: THIS MODULE CAN BE FOUND NOW IN THE OFFICIAL opencv_contrib REPOSITORY
(https://github.com/Itseez/opencv_contrib/tree/master/modules/reg)
OpenCV pixel-intensity based registration module
------------------------------------------------
Author: Alfonso Sanchez-Beato
alfonsosanchezbeato__at__gmail.com
These classes implement a module for OpenCV for parametric image registration.
The implemented method is direct alignment, that is, it uses directly the pixel
values for calculating the registration between a pair of images, as opposed to
feature-based registration. The implementation follows essentially the
corresponding part of the paper "Image Alignment and Stitching: A Tutorial",
from Richard Szeliski.
As far as I know, these methods have not been implemented publicly previously in
the OpenCV framework. Currently, the registration methods that can be found are
either template matching or feature based.
Feature based methods have some advantages over pixel based methods when we are
trying to register pictures that have been shoot under different lighting
conditions or exposition times, or when the images overlap only partially. On
the other hand, the main advantage of pixel-based methods when compared to
feature based methods is their better precision for some pictures (those shoot
under similar lighting conditions and that have a significative overlap), due to
the fact that we are using all the information available in the image, which
allows us to achieve subpixel accuracy. This is particularly important for
certain applications like multi-frame denoising or super-resolution.
In fact, pixel and feature registration methods can complement each other: an
application could first obtain a coarse registration using features and then
refine the registration using a pixel based method on the overlapping area of
the images. The code developed allows this use case.
The module implements classes derived from the abstract classes cv::reg::Map or
cv::reg::Mapper. The former models a coordinate transformation between two
reference frames, while the later encapsulates a way of invoking a method that
calculates a Map between two images. Although the objective has been to
implement pixel based methods, the module could be extended to support other
methods that can calculate transformations between images (feature methods,
optical flow, etc.).
Each class derived from Map implements a motion model, as follows:
* MapShift: Models a simple translation
* MapAffine: Models an affine transformation
* MapProject: Models a projective transformation
MapProject can also be used to model affine motion or translations, but some
operations on it are more costly, and that is the reason for defining the other
two classes.
The classes derived from Mapper are
* MapperGradShift: Gradient based alignment for calculating translations. It
produces a MapShift (two parameters that correspond to the shift vector).
* MapperGradEuclid: Gradient based alignment for euclidean motions, that is,
rotations and translations. It calculates three parameters (angle and shift
vector), although the result is stored in a MapAffine object for convenience.
* MapperGradSimilar: Gradient based alignment for calculating similarities,
which adds scaling to the euclidean motion. It calculates four parameters (two
for the anti-symmetric matrix and two for the shift vector), although the result
is stored in a MapAffine object for convenience.
* MapperGradAffine: Gradient based alignment for an affine motion model. The
number of parameters is six and the result is stored in a MapAffine object.
* MapperGradProj: Gradient based alignment for calculating projective
transformations. The number of parameters is eight and the result is stored in a
MapProject object.
* MapperPyramid: It implements hyerarchical motion estimation using a Gaussian
pyramid. Its constructor accepts as argument any other object that implements
the Mapper interface, and it is that mapper the one called by MapperPyramid for
each scale of the pyramid.
If the motion between the images is not very small, the normal way of using
these classes is to create a MapperGrad* object and use it as input to create a
MapperPyramid, which in turn is called to perform the calculation. However, if
the motion between the images is small enough, we can use directly the
MapperGrad* classes. Another possibility is to use first a feature based method
to perform a coarse registration and then do a refinement through MapperPyramid
or directly a MapperGrad* object. The "calculate" method of the mappers accepts
an initial estimation of the motion as input.
When deciding which MapperGrad to use we must take into account that mappers
with more parameters can handle more complex motions, but involve more
calculations and are therefore slower. Also, if we are confident on the motion
model that is followed by the sequence, increasing the number of parameters
beyond what we need will decrease the accuracy: it is better to use the least
number of degrees of freedom that we can.
In the file map_test.cpp some examples on how to use this module can be seen.
There is a test function for each MapperGrad*. A motion is simulated on an input
image and then we register the moved image using a MapperPyramid created with
the right MapperGrad*. The difference images of the pictures before and after
registering are displayed, and the ground truth parameters and the calculated
ones are printed. Additionally, two images from a real video are registered
using first SURF features and then MapperGradProj+MapperPyramid. The difference
between the images and the difference of the registered images using the two
methods are displayed. It can be seen in the differences shown that using a
pixel based difference we can achieve more accuracy.
To test the module you must have OpenCV and cmake installed. You must set the
environment variable OpenCV_DIR to the directory where OpenCV is installed
(where OpenCVConfig.cmake is found) and then execute
C:\path\to\reg> cmake .
in the folder where the module is located to generate the solution/Makefile
file. After that, you can compile the map_test executable. To run it you must
make sure that the OS can find the OpenCV libraries, adding its location to
either PATH (Windows) or LD_LIBRARY_PATH (Linux) environment variables.
As a final note, this is an initial release: all operations are made using
double floating point numbers and no big effort has been made to optimize the
code. Hopefully some optimizations and improvements will be implemented in the
future. The code has been tested with Visual Studio Express 2010 using win32
OpenCV libraries, but it should be possible to compile and use it easily on
other platforms.