OpenCV  3.4.8
Open Source Computer Vision
Modules | Classes | Enumerations | Functions
Object Detection

Modules

 C API
 

Classes

class  cv::BaseCascadeClassifier
 
class  cv::CascadeClassifier
 Cascade classifier class for object detection. More...
 
struct  cv::DetectionROI
 struct for detection region of interest (ROI) More...
 
struct  cv::HOGDescriptor
 Implementation of HOG (Histogram of Oriented Gradients) descriptor and object detector. More...
 
class  cv::QRCodeDetector
 
class  cv::SimilarRects
 

Enumerations

enum  {
  cv::CASCADE_DO_CANNY_PRUNING = 1,
  cv::CASCADE_SCALE_IMAGE = 2,
  cv::CASCADE_FIND_BIGGEST_OBJECT = 4,
  cv::CASCADE_DO_ROUGH_SEARCH = 8
}
 

Functions

Ptr< BaseCascadeClassifier::MaskGeneratorcv::createFaceDetectionMaskGenerator ()
 
bool cv::decodeQRCode (InputArray in, InputArray points, std::string &decoded_info, OutputArray straight_qrcode=noArray())
 Decode QR code in image and return text that is encrypted in QR code. More...
 
bool cv::detectQRCode (InputArray in, std::vector< Point > &points, double eps_x=0.2, double eps_y=0.1)
 Detect QR code in image and return minimum area of quadrangle that describes QR code. More...
 
void cv::groupRectangles (std::vector< Rect > &rectList, int groupThreshold, double eps=0.2)
 Groups the object candidate rectangles. More...
 
void cv::groupRectangles (std::vector< Rect > &rectList, std::vector< int > &weights, int groupThreshold, double eps=0.2)
 
void cv::groupRectangles (std::vector< Rect > &rectList, int groupThreshold, double eps, std::vector< int > *weights, std::vector< double > *levelWeights)
 
void cv::groupRectangles (std::vector< Rect > &rectList, std::vector< int > &rejectLevels, std::vector< double > &levelWeights, int groupThreshold, double eps=0.2)
 
void cv::groupRectangles_meanshift (std::vector< Rect > &rectList, std::vector< double > &foundWeights, std::vector< double > &foundScales, double detectThreshold=0.0, Size winDetSize=Size(64, 128))
 

Detailed Description

Haar Feature-based Cascade Classifier for Object Detection

The object detector described below has been initially proposed by Paul Viola [212] and improved by Rainer Lienhart [123] .

First, a classifier (namely a cascade of boosted classifiers working with haar-like features) is trained with a few hundred sample views of a particular object (i.e., a face or a car), called positive examples, that are scaled to the same size (say, 20x20), and negative examples - arbitrary images of the same size.

After a classifier is trained, it can be applied to a region of interest (of the same size as used during the training) in an input image. The classifier outputs a "1" if the region is likely to show the object (i.e., face/car), and "0" otherwise. To search for the object in the whole image one can move the search window across the image and check every location using the classifier. The classifier is designed so that it can be easily "resized" in order to be able to find the objects of interest at different sizes, which is more efficient than resizing the image itself. So, to find an object of an unknown size in the image the scan procedure should be done several times at different scales.

The word "cascade" in the classifier name means that the resultant classifier consists of several simpler classifiers (stages) that are applied subsequently to a region of interest until at some stage the candidate is rejected or all the stages are passed. The word "boosted" means that the classifiers at every stage of the cascade are complex themselves and they are built out of basic classifiers using one of four different boosting techniques (weighted voting). Currently Discrete Adaboost, Real Adaboost, Gentle Adaboost and Logitboost are supported. The basic classifiers are decision-tree classifiers with at least 2 leaves. Haar-like features are the input to the basic classifiers, and are calculated as described below. The current algorithm uses the following Haar-like features:

haarfeatures.png
image

The feature used in a particular classifier is specified by its shape (1a, 2b etc.), position within the region of interest and the scale (this scale is not the same as the scale used at the detection stage, though these two scales are multiplied). For example, in the case of the third line feature (2c) the response is calculated as the difference between the sum of image pixels under the rectangle covering the whole feature (including the two white stripes and the black stripe in the middle) and the sum of the image pixels under the black stripe multiplied by 3 in order to compensate for the differences in the size of areas. The sums of pixel values over a rectangular regions are calculated rapidly using integral images (see below and the integral description).

To see the object detector at work, have a look at the facedetect demo: https://github.com/opencv/opencv/tree/3.4/samples/cpp/dbt_face_detection.cpp

The following reference is for the detection part only. There is a separate application called opencv_traincascade that can train a cascade of boosted classifiers from a set of samples.

Note
In the new C++ interface it is also possible to use LBP (local binary pattern) features in addition to Haar-like features. .. [Viola01] Paul Viola and Michael J. Jones. Rapid Object Detection using a Boosted Cascade of Simple Features. IEEE CVPR, 2001. The paper is available online at http://research.microsoft.com/en-us/um/people/viola/Pubs/Detect/violaJones_CVPR2001.pdf

Enumeration Type Documentation

§ anonymous enum

anonymous enum

#include <opencv2/objdetect.hpp>

Enumerator
CASCADE_DO_CANNY_PRUNING 
Python: cv.CASCADE_DO_CANNY_PRUNING
CASCADE_SCALE_IMAGE 
Python: cv.CASCADE_SCALE_IMAGE
CASCADE_FIND_BIGGEST_OBJECT 
Python: cv.CASCADE_FIND_BIGGEST_OBJECT
CASCADE_DO_ROUGH_SEARCH 
Python: cv.CASCADE_DO_ROUGH_SEARCH

Function Documentation

§ createFaceDetectionMaskGenerator()

Ptr<BaseCascadeClassifier::MaskGenerator> cv::createFaceDetectionMaskGenerator ( )

§ decodeQRCode()

bool cv::decodeQRCode ( InputArray  in,
InputArray  points,
std::string &  decoded_info,
OutputArray  straight_qrcode = noArray() 
)

#include <opencv2/objdetect.hpp>

Decode QR code in image and return text that is encrypted in QR code.

Parameters
inMatrix of the type CV_8UC1 containing an image where QR code are detected.
pointsInput vector of vertices of a quadrangle of minimal area that describes QR code.
decoded_infoString information that is encrypted in QR code.
straight_qrcodeMatrix of the type CV_8UC1 containing an binary straight QR code.

§ detectQRCode()

bool cv::detectQRCode ( InputArray  in,
std::vector< Point > &  points,
double  eps_x = 0.2,
double  eps_y = 0.1 
)

#include <opencv2/objdetect.hpp>

Detect QR code in image and return minimum area of quadrangle that describes QR code.

Parameters
inMatrix of the type CV_8UC1 containing an image where QR code are detected.
pointsOutput vector of vertices of a quadrangle of minimal area that describes QR code.
eps_xEpsilon neighborhood, which allows you to determine the horizontal pattern of the scheme 1:1:3:1:1 according to QR code standard.
eps_yEpsilon neighborhood, which allows you to determine the vertical pattern of the scheme 1:1:3:1:1 according to QR code standard.

§ groupRectangles() [1/4]

void cv::groupRectangles ( std::vector< Rect > &  rectList,
int  groupThreshold,
double  eps = 0.2 
)
Python:
rectList, weights=cv.groupRectangles(rectList, groupThreshold[, eps])

#include <opencv2/objdetect.hpp>

Groups the object candidate rectangles.

Parameters
rectListInput/output vector of rectangles. Output vector includes retained and grouped rectangles. (The Python list is not modified in place.)
groupThresholdMinimum possible number of rectangles minus 1. The threshold is used in a group of rectangles to retain it.
epsRelative difference between sides of the rectangles to merge them into a group.

The function is a wrapper for the generic function partition . It clusters all the input rectangles using the rectangle equivalence criteria that combines rectangles with similar sizes and similar locations. The similarity is defined by eps. When eps=0 , no clustering is done at all. If \(\texttt{eps}\rightarrow +\inf\) , all the rectangles are put in one cluster. Then, the small clusters containing less than or equal to groupThreshold rectangles are rejected. In each other cluster, the average rectangle is computed and put into the output rectangle list.

§ groupRectangles() [2/4]

void cv::groupRectangles ( std::vector< Rect > &  rectList,
std::vector< int > &  weights,
int  groupThreshold,
double  eps = 0.2 
)
Python:
rectList, weights=cv.groupRectangles(rectList, groupThreshold[, eps])

#include <opencv2/objdetect.hpp>

This is an overloaded member function, provided for convenience. It differs from the above function only in what argument(s) it accepts.

§ groupRectangles() [3/4]

void cv::groupRectangles ( std::vector< Rect > &  rectList,
int  groupThreshold,
double  eps,
std::vector< int > *  weights,
std::vector< double > *  levelWeights 
)
Python:
rectList, weights=cv.groupRectangles(rectList, groupThreshold[, eps])

#include <opencv2/objdetect.hpp>

This is an overloaded member function, provided for convenience. It differs from the above function only in what argument(s) it accepts.

§ groupRectangles() [4/4]

void cv::groupRectangles ( std::vector< Rect > &  rectList,
std::vector< int > &  rejectLevels,
std::vector< double > &  levelWeights,
int  groupThreshold,
double  eps = 0.2 
)
Python:
rectList, weights=cv.groupRectangles(rectList, groupThreshold[, eps])

#include <opencv2/objdetect.hpp>

This is an overloaded member function, provided for convenience. It differs from the above function only in what argument(s) it accepts.

§ groupRectangles_meanshift()

void cv::groupRectangles_meanshift ( std::vector< Rect > &  rectList,
std::vector< double > &  foundWeights,
std::vector< double > &  foundScales,
double  detectThreshold = 0.0,
Size  winDetSize = Size(64, 128) 
)

#include <opencv2/objdetect.hpp>

This is an overloaded member function, provided for convenience. It differs from the above function only in what argument(s) it accepts.