mirror of
https://github.com/opencv/opencv.git
synced 2024-12-14 08:59:11 +08:00
149 lines
8.4 KiB
Markdown
149 lines
8.4 KiB
Markdown
Cascade Classifier {#tutorial_cascade_classifier}
|
||
==================
|
||
|
||
@tableofcontents
|
||
|
||
@prev_tutorial{tutorial_optical_flow}
|
||
@next_tutorial{tutorial_traincascade}
|
||
|
||
| | |
|
||
| -: | :- |
|
||
| Original author | Ana Huamán |
|
||
| Compatibility | OpenCV >= 3.0 |
|
||
|
||
Goal
|
||
----
|
||
|
||
In this tutorial,
|
||
|
||
- We will learn how the Haar cascade object detection works.
|
||
- We will see the basics of face detection and eye detection using the Haar Feature-based Cascade Classifiers
|
||
- We will use the @ref cv::CascadeClassifier class to detect objects in a video stream. Particularly, we
|
||
will use the functions:
|
||
- @ref cv::CascadeClassifier::load to load a .xml classifier file. It can be either a Haar or a LBP classifier
|
||
- @ref cv::CascadeClassifier::detectMultiScale to perform the detection.
|
||
|
||
Theory
|
||
------
|
||
|
||
Object Detection using Haar feature-based cascade classifiers is an effective object detection
|
||
method proposed by Paul Viola and Michael Jones in their paper, "Rapid Object Detection using a
|
||
Boosted Cascade of Simple Features" in 2001. It is a machine learning based approach where a cascade
|
||
function is trained from a lot of positive and negative images. It is then used to detect objects in
|
||
other images.
|
||
|
||
Here we will work with face detection. Initially, the algorithm needs a lot of positive images
|
||
(images of faces) and negative images (images without faces) to train the classifier. Then we need
|
||
to extract features from it. For this, Haar features shown in the below image are used. They are just
|
||
like our convolutional kernel. Each feature is a single value obtained by subtracting sum of pixels
|
||
under the white rectangle from sum of pixels under the black rectangle.
|
||
|
||
![image](images/haar_features.jpg)
|
||
|
||
Now, all possible sizes and locations of each kernel are used to calculate lots of features. (Just
|
||
imagine how much computation it needs? Even a 24x24 window results over 160000 features). For each
|
||
feature calculation, we need to find the sum of the pixels under white and black rectangles. To solve
|
||
this, they introduced the integral image. However large your image, it reduces the calculations for a
|
||
given pixel to an operation involving just four pixels. Nice, isn't it? It makes things super-fast.
|
||
|
||
But among all these features we calculated, most of them are irrelevant. For example, consider the
|
||
image below. The top row shows two good features. The first feature selected seems to focus on the
|
||
property that the region of the eyes is often darker than the region of the nose and cheeks. The
|
||
second feature selected relies on the property that the eyes are darker than the bridge of the nose.
|
||
But the same windows applied to cheeks or any other place is irrelevant. So how do we select the
|
||
best features out of 160000+ features? It is achieved by **Adaboost**.
|
||
|
||
![image](images/haar.png)
|
||
|
||
For this, we apply each and every feature on all the training images. For each feature, it finds the
|
||
best threshold which will classify the faces to positive and negative. Obviously, there will be
|
||
errors or misclassifications. We select the features with minimum error rate, which means they are
|
||
the features that most accurately classify the face and non-face images. (The process is not as simple as
|
||
this. Each image is given an equal weight in the beginning. After each classification, weights of
|
||
misclassified images are increased. Then the same process is done. New error rates are calculated.
|
||
Also new weights. The process is continued until the required accuracy or error rate is achieved or
|
||
the required number of features are found).
|
||
|
||
The final classifier is a weighted sum of these weak classifiers. It is called weak because it alone
|
||
can't classify the image, but together with others forms a strong classifier. The paper says even
|
||
200 features provide detection with 95% accuracy. Their final setup had around 6000 features.
|
||
(Imagine a reduction from 160000+ features to 6000 features. That is a big gain).
|
||
|
||
So now you take an image. Take each 24x24 window. Apply 6000 features to it. Check if it is face or
|
||
not. Wow.. Isn't it a little inefficient and time consuming? Yes, it is. The authors have a good
|
||
solution for that.
|
||
|
||
In an image, most of the image is non-face region. So it is a better idea to have a simple
|
||
method to check if a window is not a face region. If it is not, discard it in a single shot, and don't
|
||
process it again. Instead, focus on regions where there can be a face. This way, we spend more time
|
||
checking possible face regions.
|
||
|
||
For this they introduced the concept of **Cascade of Classifiers**. Instead of applying all 6000
|
||
features on a window, the features are grouped into different stages of classifiers and applied one-by-one.
|
||
(Normally the first few stages will contain very many fewer features). If a window fails the first
|
||
stage, discard it. We don't consider the remaining features on it. If it passes, apply the second stage
|
||
of features and continue the process. The window which passes all stages is a face region. How is
|
||
that plan!
|
||
|
||
The authors' detector had 6000+ features with 38 stages with 1, 10, 25, 25 and 50 features in the first five
|
||
stages. (The two features in the above image are actually obtained as the best two features from
|
||
Adaboost). According to the authors, on average 10 features out of 6000+ are evaluated per
|
||
sub-window.
|
||
|
||
So this is a simple intuitive explanation of how Viola-Jones face detection works. Read the paper for
|
||
more details or check out the references in the Additional Resources section.
|
||
|
||
Haar-cascade Detection in OpenCV
|
||
--------------------------------
|
||
OpenCV provides a training method (see @ref tutorial_traincascade) or pretrained models, that can be read using the @ref cv::CascadeClassifier::load method.
|
||
The pretrained models are located in the data folder in the OpenCV installation or can be found [here](https://github.com/opencv/opencv/tree/5.x/data).
|
||
|
||
The following code example will use pretrained Haar cascade models to detect faces and eyes in an image.
|
||
First, a @ref cv::CascadeClassifier is created and the necessary XML file is loaded using the @ref cv::CascadeClassifier::load method.
|
||
Afterwards, the detection is done using the @ref cv::CascadeClassifier::detectMultiScale method, which returns boundary rectangles for the detected faces or eyes.
|
||
|
||
@add_toggle_cpp
|
||
This tutorial code's is shown lines below. You can also download it from
|
||
[here](https://github.com/opencv/opencv/tree/5.x/samples/cpp/tutorial_code/objectDetection/objectDetection.cpp)
|
||
@include samples/cpp/tutorial_code/objectDetection/objectDetection.cpp
|
||
@end_toggle
|
||
|
||
@add_toggle_java
|
||
This tutorial code's is shown lines below. You can also download it from
|
||
[here](https://github.com/opencv/opencv/tree/5.x/samples/java/tutorial_code/objectDetection/cascade_classifier/ObjectDetectionDemo.java)
|
||
@include samples/java/tutorial_code/objectDetection/cascade_classifier/ObjectDetectionDemo.java
|
||
@end_toggle
|
||
|
||
@add_toggle_python
|
||
This tutorial code's is shown lines below. You can also download it from
|
||
[here](https://github.com/opencv/opencv/tree/5.x/samples/python/tutorial_code/objectDetection/cascade_classifier/objectDetection.py)
|
||
@include samples/python/tutorial_code/objectDetection/cascade_classifier/objectDetection.py
|
||
@end_toggle
|
||
|
||
Result
|
||
------
|
||
|
||
-# Here is the result of running the code above and using as input the video stream of a built-in
|
||
webcam:
|
||
|
||
![](images/Cascade_Classifier_Tutorial_Result_Haar.jpg)
|
||
|
||
Be sure the program will find the path of files *haarcascade_frontalface_alt.xml* and
|
||
*haarcascade_eye_tree_eyeglasses.xml*. They are located in
|
||
*opencv/data/haarcascades*
|
||
|
||
-# This is the result of using the file *lbpcascade_frontalface.xml* (LBP trained) for the face
|
||
detection. For the eyes we keep using the file used in the tutorial.
|
||
|
||
![](images/Cascade_Classifier_Tutorial_Result_LBP.jpg)
|
||
|
||
Additional Resources
|
||
--------------------
|
||
|
||
-# Paul Viola and Michael J. Jones. Robust real-time face detection. International Journal of Computer Vision, 57(2):137–154, 2004. @cite Viola04
|
||
-# Rainer Lienhart and Jochen Maydt. An extended set of haar-like features for rapid object detection. In Image Processing. 2002. Proceedings. 2002 International Conference on, volume 1, pages I–900. IEEE, 2002. @cite Lienhart02
|
||
-# Video Lecture on [Face Detection and Tracking](https://www.youtube.com/watch?v=WfdYYNamHZ8)
|
||
-# An interesting interview regarding Face Detection by [Adam
|
||
Harvey](https://web.archive.org/web/20171204220159/http://www.makematics.com/research/viola-jones/)
|
||
-# [OpenCV Face Detection: Visualized](https://vimeo.com/12774628) on Vimeo by Adam Harvey
|