README - KAZE Features
Version: 1.8.0 Date: 11-12-2014
You can get the latest version of the code from github:
https://github.com/pablofdezalc/kaze
CHANGELOG
Version: 1.8.0 Changes:
- The code has been changed for compatibility with OpenCV 3.0. Note that in OpenCV 3.0, SURF and SIFT have been moved to opencv2/xfeatures2d.hpp.
If you want to compile kaze_compare, you will need to download and compile opencv_contrib:
https://github.com/Itseez/opencv_contrib
- Some speed-ups have been introduced
Version: 1.7.0 Changes:
- KAZEConfig.h added, now all the configuration options are defined in this file
- New descriptors interface using DESCRIPTOR_TYPE
- Matlab mex interface added
Version: 1.6.0 Changes:
- Code style has been changed substantially to match portability with other libraries
- Matching is now performed using OpenCV BruteForce matching
- KAZE Features now uses by default Fast Explicit Diffusion (FED) for discretizing the nonlinear diffusion equation. See use_fed command line option. With FED, KAZE is much faster than using AOS
For more information about FED, please check:
-
Fast Explicit Diffusion for Accelerated Features in Nonlinear Scale Spaces. Pablo F. Alcantarilla, J. Nuevo and Adrien Bartoli. In British Machine Vision Conference (BMVC), Bristol, UK, September 2013.
-
From box filtering to fast explicit diffusion. S. Grewenig, J. Weickert, and A. Bruhn. In Proceedings of the DAGM Symposium on Pattern Recognition, pages 533–542, 2010.
Version: 1.5.2 Changes:
- KAZE Features now support OpenMP parallelization. This improves speed with respect to previous version in 30%
- Boost library dependency has been removed
- Bug corrected: In the previous version, the Clipping_Descriptor function with 3 input parameters was missing. Thanks to Mario Maresca
Version: 1.5.1 Changes:
- Integrated modifications from 1.5 into the old Ipoint interface The old interface library is named kaze_features_1_5_1_old
- Corrected a bug in checking descriptors limits
Version: 1.5 Changes:
- Important: Remove of Ipoint class interface. Now the code uses cv::KeyPoint for computing features and cv::Mat to store the descriptors
- Remove of Check_Descriptors_Limits check. The check if a descriptor is out of the image is done now in Determinant_Hessian_Parallel
- Speeded-up computation of Scharr-kernel derivatives
- Use OpenCV functions for measuring time computations
- Bug corrected with the number of sublevels Do_Subpixel_Refinement
Version: 1.4 Changes:
- Bug corrected in Compute_K_Percentile. Thanks to Willem Sanberg Declaring the static array hist[nbins] has compilation problems with Microsoft Visual Studio Express 2010 Now, the array memory is allocated in runtime
- G-SURF descriptor pattern added as a possible option for the descriptor G-SURF descriptor is a novel family of descriptors that measure blurring and detail enhancing information at a certain scale level. G-SURF has been introduced recently in Pablo F. Alcantarilla, Luis M. Bergasa and Andrew J. Davison, Gauge-SURF Descriptors, Image and Vision Computing 31(1), 2013
- In version 1.3 the Check_Maximum_Neighbourhood was more strict in the sense that the detector response should be higher than the neighbors response plus a constant value. This produced in general less detected keypoints for some images. I modified the code back to the Check_Maximum_Neighbourhood from version 1.2 or below
- Bug corrected with the sample step and pattern size in SURF extended descriptor
Version: 1.3 Changes:
- Modifications of the CMakeLists.txt and code structure
- Several code improvements that make the algorithm faster. Thanks to Jesús Nuevo
- Small bug corrected with the sample step and pattern size in SURF descriptor
Version: 1.2 Changes:
- Small improvement in speed due to the use of pointer-based access instead of .at method in OpenCV Mat. Thanks to MartÃn Peris
- Bug in the default initialization of the descriptor has been corrected. Thanks to José Javier Yebes
- Bug in Subpixel Refinement has been corrected
Version: 1.1 Changes:
- The code has been cleaned up a bit and some functions that were not used were removed
- Added the option for extended descriptors. Now you can choose between 64 or 128 descriptors
- Results visualization can be turned on/off from command line with the show_results option
- kaze_compare program added that compares KAZE against SIFT, SURF (OpenCV)
- Now kaze_match and kaze_compare can work with images that have different resolution between them
What is this file?
This file explains how to make use of source code for computing KAZE features and two practical image matching applications.
Library Dependencies
The code is mainly based on the OpenCV library using the C++ interface.
In order to compile the code, the following libraries to be installed on your system:
- OpenCV version 2.4.0 or higher
- Cmake version 2.6 or higher
If you want to use OpenMP parallelization you will need to install OpenMP in your system In Linux you can do this by installing the gomp library
- Since version 1.5.2 KAZE features does not use Boost
You will also need doxygen in case you need to generate the documentation
Tested compilers
- GCC 4.2-4.7
Tested systems:
- Ubuntu 11.10, 12.04, 12.10
- Kubuntu 10.04
- Mac OS 10.6.8
Getting Started
Compiling:
$ mkdir build
$ cd build>
$ cmake ..
$ make
Additionally you can also install the library in /usr/local/kaze/lib
by typing:
$ sudo make install
If the compilation is successful you should see three executables in the folder bin:
kaze_features
kaze_match
kaze_compare
Additionally, the library libKAZE[.a, .lib]
will be created in the lib
folder.
If there is any error in the compilation, perhaps some libraries are missing. Please check the Library dependencies section.
Examples: To see how the code works, examine the two examples provided.
Documentation
In the working folder type:
doxygen
The documentation will be generated in the doc
folder.
Computing KAZE Features
For running the program you need to type in the command line the following arguments:
./kaze_features img.jpg [options]
The options are not mandatory. In case you do not specify additional options, default arguments will be used. Here is a description of the additional options:
--verbose
if verbosity is required--help
for showing the command line options--soffset
the base scale offset (sigma units)--omax
the coarsest nonlinear scale space level (sigma units)--nsublevels
number of sublevels per octave--dthreshold
Feature detector threshold response for accepting points--descriptor
Descriptor Type 0 -> SURF, 1 -> M-SURF, 2 -> G-SURF--use_fed
0 -> AOS, 1 -> FED--upright
0 -> Rotation Invariant, 1 -> No Rotation Invariant--extended 0
-> Normal Descriptor (64), 1 -> Extended Descriptor (128)--show_results
1 in case we want to show detection results. 0 otherwise
Important Things:
- Check config.h in case you would like to change the value of some default settings
- The k constrast factor is computed as the 70% percentile of the gradient histogram of a smoothed version of the original image. Normally, this empirical value gives good results, but depending on the input image the diffusion will not be good enough. Therefore I highly recommend you to visualize the output images from save_scale_space and test with other k factors if the results are not satisfactory
Image Matching Example with KAZE Features
The code contains one program to perform image matching between two images. If the ground truth transformation is not provided, the program estimates a fundamental matrix using RANSAC between the set of correspondences between the two images.
For running the program you need to type in the command line the following arguments:
./kaze_match img1.jpg img2.pgm homography.txt [options]
The datasets folder contains the Iguazu dataset described in the paper and additional datasets from Mykolajczyk et al. evaluation. The Iguazu dataset was generated by adding Gaussian noise of increasing standard deviation.
For example, with the default configuration parameters used in the current code version you should get the following results:
./kaze_match ../../datasets/iguazu/img1.pgm
../../datasets/iguazu/img4.pgm
../../datasets/iguazu/H1to4p
Number of Keypoints Image 1: 1825
Number of Keypoints Image 2: 1634
KAZE Features Extraction Time (ms): 992.943
Matching Descriptors Time (ms): 14.2714
Number of Matches: 981
Number of Inliers: 854
Number of Outliers: 127
Inliers Ratio: 87.054
Image Matching Comparison between KAZE, SIFT and SURF (OpenCV)
The code contains one program to perform image matching between two images, showing a comparison between KAZE features, SIFT and SURF. All these implementations are based on the OpenCV library.
The program assumes that the ground truth transformation is provided
For running the program you need to type in the command line the following arguments:
./kaze_compare img1.jpg img2.pgm homography.txt [options]
For example, running kaze_compare with the first and third images from the boat dataset you should get the following results:
./kaze_compare ../../datasets/boat/img1.pgm
../../datasets/boat/img3.pgm
../../datasets/boat/H1to3p
SIFT Results
**************************************
Number of Keypoints Image 1: 2000
Number of Keypoints Image 2: 2000
Number of Matches: 746
Number of Inliers: 690
Number of Outliers: 56
Inliers Ratio: 92.4933
SIFT Features Extraction Time (ms): 1087.91
SURF Results
**************************************
Number of Keypoints Image 1: 4021
Number of Keypoints Image 2: 3162
Number of Matches: 725
Number of Inliers: 499
Number of Outliers: 226
Inliers Ratio: 68.8276
SURF Features Extraction Time (ms): 133.709
KAZE Results
**************************************
Number of Keypoints Image 1: 4795
Number of Keypoints Image 2: 4061
Number of Matches: 1908
Number of Inliers: 1710
Number of Outliers: 198
Inliers Ratio: 89.6226
KAZE Features Extraction Time (ms): 869.032
One of the interesting reasons why you should use KAZE features is because is open source and you can use that freely even in commercial applications, which is not the case of SIFT and SURF. The code is released under the BSD license. In general, KAZE results are superior to the other OpenCV methods (in terms of number of inliers and ratio), while being more slower to compute. Future work will try to speed-up the process as much as possible while keeping good performance
Citation
If you use this code as part of your work, please cite the following paper:
- KAZE Features. Pablo F. Alcantarilla, Adrien Bartoli and Andrew J. Davison. In European Conference on Computer Vision (ECCV), Fiorenze, Italy. October 2012.
Contact Info
Important: If you work in a research institution, university, company or you are a freelance and you are using KAZE or A-KAZE in your work, please send me an email!! I would like to know the people that are using KAZE around the world!!"
In case you have any question, find any bug in the code or want to share some improvements, please contact me:
Pablo F. Alcantarilla email: [email protected]