Added rst Tutorial for Filter 2D

2011-06-27 04:01:01 +00:00 · 2011-06-27 04:01:01 +00:00 · ae649e8c30
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--- a/doc/tutorials/imgproc/imgtrans/filter_2d/filter_2d.rst
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 .. _filter_2d:
 Making your own linear filters!
 ********************************
 Goal
 =====
 In this tutorial you will learn how to:
 * Use the OpenCV function :filter2d:`filter2D <>` to create your own linear filters.  
 Theory
 ============
 .. note::
   The explanation below belongs to the book **Learning OpenCV** by Bradski and Kaehler.
 Convolution
 ------------
 In a very general sense, convolution is an operation between every part of an image and an operator (kernel). 
 What is a kernel?
 ------------------
 A kernel is essentially a fixed size array of numerical coefficeints along with an *anchor point* in that array, which is tipically located at the center. 
 .. image:: images/filter_2d_tutorial_kernel_theory.png
        :alt: kernel example
        :align: center 
 How does convolution with a kernel work?
 -----------------------------------------
 Assume you want to know the resulting value of a particular location in the image. The value of the convolution is calculated in the following way:
 #. Place the kernel anchor on top of a determined pixel, with the rest of the kernel overlaying the corresponding local pixels in the image.
 #. Multiply the kernel coefficients by the corresponding image pixel values and sum the result. 
 #. Place the result to the location of the *anchor* in the input image.
 #. Repeat the process for all pixels by scanning the kernel over the entire image.
 Expressing the procedure above in the form of an equation we would have:
 .. math::
   H(x,y) = \sum_{i=0}^{M_{i} - 1} \sum_{j=0}^{M_{j}-1} I(x+i - a_{i}, y + j - a_{j})K(i,j)
 Fortunately, OpenCV provides you with the function :filter2d:`filter2D <>` so you do not have to code all these operations. 
 Code
 ======
 #. **What does this program do?**
   * Loads an image
   * Performs a *normalized box filter*. For instance, for a kernel of size :math:`size = 3`, the kernel would be:
     .. math::
        K = \dfrac{1}{3 \cdot 3} \begin{bmatrix}
        1 & 1 & 1  \\
        1 & 1 & 1  \\
        1 & 1 & 1 
        \end{bmatrix} 
     The program will perform the filter operation with kernels of sizes 3, 5, 7, 9 and 11.
   * The filter output (with each kernel) will be shown during 500 milliseconds
 #. The tutorial code's is shown lines below. You can also download it from `here <https://code.ros.org/svn/opencv/trunk/opencv/samples/cpp/tutorial_code/ImgTrans/filter2D_demo.cpp>`_
 .. code-block:: cpp 
   #include "opencv2/imgproc/imgproc.hpp"
   #include "opencv2/highgui/highgui.hpp"
   #include <stdlib.h>
   #include <stdio.h>
   using namespace cv;
   /** @function main */
   int main ( int argc, char** argv )
   {
     /// Declare variables
     Mat src, dst;
     Mat kernel;
     Point anchor;
     double delta;
     int ddepth;  
     int kernel_size;
     char* window_name = "filter2D Demo";
     int c;
     /// Load an image
     src = imread( argv[1] );
     if( !src.data )
     { return -1; }
     /// Create window
     namedWindow( window_name, CV_WINDOW_AUTOSIZE );
     /// Initialize arguments for the filter
     anchor = Point( -1, -1 );
     delta = 0;
     ddepth = -1;
     /// Loop - Will filter the image with different kernel sizes each 0.5 seconds
     int ind = 0;
     while( true )
       {
         c = waitKey(500);
         /// Press 'ESC' to exit the program
         if( (char)c == 27 )
           { break; }
         /// Update kernel size for a normalized box filter
         kernel_size = 3 + 2*( ind%5 );
         kernel = Mat::ones( kernel_size, kernel_size, CV_32F )/ (float)(kernel_size*kernel_size);
         /// Apply filter
         filter2D(src, dst, ddepth , kernel, anchor, delta, BORDER_DEFAULT );
         imshow( window_name, dst );
         ind++;
       }
     return 0;
   }
 Explanation
 =============
 #. We begin with the usual steps:
   * Load an image
     .. code-block:: cpp
     	src = imread( argv[1] );
     	if( !src.data )
     	  { return -1; }
   * Create a window to display the result
     .. code-block:: cpp
     	namedWindow( window_name, CV_WINDOW_AUTOSIZE );
 #. Initialize the arguments for the linear filter
   .. code-block:: cpp
      anchor = Point( -1, -1 );
      delta = 0;
      ddepth = -1;
 #. Perform an infinite loop updating the kernel size and applying our linear filter to the input image. Let's analyze that more in detail:
 #. First we define the kernel our filter is going to use. Here it is:
   .. code-block:: cpp
      kernel_size = 3 + 2*( ind%5 );
      kernel = Mat::ones( kernel_size, kernel_size, CV_32F )/ (float)(kernel_size*kernel_size);
   The first line is to update the *kernel_size* to odd values in the range: :math:`[3,11]`. The second line actually builds the kernel by setting its value to a matrix filled with :math:`1's` and normalizing it by dividing it between the number of elements. 
 #. After setting the kernel, we can generate the filter by using the function :filter2d:`filter2D <>`:
   .. code-block:: cpp
      filter2D(src, dst, ddepth , kernel, anchor, delta, BORDER_DEFAULT );
   The arguments denote:
   a. *src*: Source image
   #. *dst*: Destination image
   #. *ddepth*: The depth of *dst*. A negative value (such as :math:`-1`) indicates that the depth is the same as the source.
   #. *kernel*: The kernel to be scanned through the image
   #. *anchor*: The position of the anchor relative to its kernel. The location *Point(-1, -1)* indicates the center by default.
   #. *delta*: A value to be added to each pixel during the convolution. By default it is :math:`0`
   #. *BORDER_DEFAULT*: We let this value by default (more details in the following tutorial)
 #. Our program will effectuate a *while* loop, each 500 ms the kernel size of our filter will be updated in the range indicated.
 Results
 ========
 #. After compiling the code above, you  can execute it giving as argument the path of an image. The result should be a window that shows an image blurred by a normalized filter. Each 0.5 seconds the kernel size should change, as can be seen in the series of snapshots below:
   .. image:: images/filter_2d_tutorial_result.png
           :alt: kernel example
           :align: center
--- a/doc/tutorials/imgproc/imgtrans/filter_2d/images/filter_2d_tutorial_kernel_theory.png
+++ b/doc/tutorials/imgproc/imgtrans/filter_2d/images/filter_2d_tutorial_kernel_theory.png
--- a/doc/tutorials/imgproc/imgtrans/filter_2d/images/filter_2d_tutorial_result.png
+++ b/doc/tutorials/imgproc/imgtrans/filter_2d/images/filter_2d_tutorial_result.png
--- a/doc/tutorials/imgproc/table_of_content_imgproc/images/imgtrans/Filter_2D_Tutorial_Cover.jpg
+++ b/doc/tutorials/imgproc/table_of_content_imgproc/images/imgtrans/Filter_2D_Tutorial_Cover.jpg
--- a/doc/tutorials/imgproc/table_of_content_imgproc/table_of_content_imgproc.rst
+++ b/doc/tutorials/imgproc/table_of_content_imgproc/table_of_content_imgproc.rst
@ -103,3 +103,26 @@ In this section you will learn about the image processing (manipulation) functio
  .. |Threshold| image:: images/Threshold_Tutorial_Cover.png
                      :height: 100pt
                      :width:  100pt
 .. ************************
 .. ImgTrans
 .. ************************
 * :ref:`filter_2d`
  ===================== ==============================================
   |Filter_2D|          *Title:* **Making your own linear filters**
                        *Compatibility:* > OpenCV 2.0
                        *Author:* |Author_AnaH|
                        Where we learn to design our own filters by using OpenCV functions
  ===================== ==============================================
  .. |Filter_2D| image:: images/imgtrans/Filter_2D_Tutorial_Cover.jpg
                      :height: 100pt
                      :width:  100pt