opencv/doc/opencv1/py/imgproc_object_detection.rst

Object Detection
================

.. highlight:: python


.. index:: MatchTemplate

.. _MatchTemplate:

MatchTemplate
-------------


.. function:: MatchTemplate(image,templ,result,method)-> None

    Compares a template against overlapped image regions.


    :param image: Image where the search is running; should be 8-bit or 32-bit floating-point 
    
    :type image: :class:`CvArr`
    
    
    :param templ: Searched template; must be not greater than the source image and the same data type as the image 
    
    :type templ: :class:`CvArr`
    
    
    :param result: A map of comparison results; single-channel 32-bit floating-point.
        If  ``image``  is  :math:`W \times H`  and ``templ``  is  :math:`w \times h`  then  ``result``  must be  :math:`(W-w+1) \times (H-h+1)` 
    
    :type result: :class:`CvArr`
    
    
    :param method: Specifies the way the template must be compared with the image regions (see below) 
    
    :type method: int
    
    
The function is similar to
:ref:`CalcBackProjectPatch`
. It slides through 
``image``
, compares the
overlapped patches of size 
:math:`w \times h`
against 
``templ``
using the specified method and stores the comparison results to
``result``
. Here are the formulas for the different comparison
methods one may use (
:math:`I`
denotes 
``image``
, 
:math:`T`
``template``
,
:math:`R`
``result``
). The summation is done over template and/or the
image patch: 
:math:`x' = 0...w-1, y' = 0...h-1`


* method=CV\_TM\_SQDIFF
    
    
    .. math::
    
        R(x,y)= \sum _{x',y'} (T(x',y')-I(x+x',y+y'))^2  
    
    
* method=CV\_TM\_SQDIFF\_NORMED
    
    
    .. math::
    
        R(x,y)= \frac{\sum_{x',y'} (T(x',y')-I(x+x',y+y'))^2}{\sqrt{\sum_{x',y'}T(x',y')^2 \cdot \sum_{x',y'} I(x+x',y+y')^2}} 
    
    
* method=CV\_TM\_CCORR
    
    
    .. math::
    
        R(x,y)= \sum _{x',y'} (T(x',y')  \cdot I(x+x',y+y'))  
    
    
* method=CV\_TM\_CCORR\_NORMED
    
    
    .. math::
    
        R(x,y)= \frac{\sum_{x',y'} (T(x',y') \cdot I'(x+x',y+y'))}{\sqrt{\sum_{x',y'}T(x',y')^2 \cdot \sum_{x',y'} I(x+x',y+y')^2}} 
    
    
* method=CV\_TM\_CCOEFF
    
    
    .. math::
    
        R(x,y)= \sum _{x',y'} (T'(x',y')  \cdot I(x+x',y+y'))  
    
    
    where
    
    
    .. math::
    
        \begin{array}{l} T'(x',y')=T(x',y') - 1/(w  \cdot h)  \cdot \sum _{x'',y''} T(x'',y'') \\ I'(x+x',y+y')=I(x+x',y+y') - 1/(w  \cdot h)  \cdot \sum _{x'',y''} I(x+x'',y+y'') \end{array} 
    
    
* method=CV\_TM\_CCOEFF\_NORMED
    
    
    .. math::
    
        R(x,y)= \frac{ \sum_{x',y'} (T'(x',y') \cdot I'(x+x',y+y')) }{ \sqrt{\sum_{x',y'}T'(x',y')^2 \cdot \sum_{x',y'} I'(x+x',y+y')^2} } 
    
    
After the function finishes the comparison, the best matches can be found as global minimums (
``CV_TM_SQDIFF``
) or maximums (
``CV_TM_CCORR``
and 
``CV_TM_CCOEFF``
) using the 
:ref:`MinMaxLoc`
function. In the case of a color image, template summation in the numerator and each sum in the denominator is done over all of the channels (and separate mean values are used for each channel).
moved the new docs from docroot to doc 2011-05-10 00:35:11 +08:00			`Object Detection`
			`================`

			`.. highlight:: python`



			`.. index:: MatchTemplate`

			`.. _MatchTemplate:`

			`MatchTemplate`
			`-------------`

converted user guide & tutorials from tex to rst; added them into the whole documentation tree; added html_docs target. 2011-05-11 06:09:07 +08:00
moved the new docs from docroot to doc 2011-05-10 00:35:11 +08:00

			`.. function:: MatchTemplate(image,templ,result,method)-> None`

			`Compares a template against overlapped image regions.`






			`:param image: Image where the search is running; should be 8-bit or 32-bit floating-point`

			:type image: :class:`CvArr`


			`:param templ: Searched template; must be not greater than the source image and the same data type as the image`

			:type templ: :class:`CvArr`


			`:param result: A map of comparison results; single-channel 32-bit floating-point.`
			If ``image`` is :math:`W \times H` and ``templ`` is :math:`w \times h` then ``result`` must be :math:`(W-w+1) \times (H-h+1)`

			:type result: :class:`CvArr`


			`:param method: Specifies the way the template must be compared with the image regions (see below)`

			`:type method: int`



			`The function is similar to`
			:ref:`CalcBackProjectPatch`
			`. It slides through`
			``image``
			`, compares the`
			`overlapped patches of size`
			:math:`w \times h`
			`against`
			``templ``
			`using the specified method and stores the comparison results to`
			``result``
			`. Here are the formulas for the different comparison`
			`methods one may use (`
			:math:`I`
			`denotes`
			``image``
			`,`
			:math:`T`
			``template``
			`,`
			:math:`R`
			``result``
			`). The summation is done over template and/or the`
			`image patch:`
			:math:`x' = 0...w-1, y' = 0...h-1`




			`* method=CV\_TM\_SQDIFF`


			`.. math::`

			`R(x,y)= \sum _{x',y'} (T(x',y')-I(x+x',y+y'))^2`




			`* method=CV\_TM\_SQDIFF\_NORMED`


			`.. math::`

			`R(x,y)= \frac{\sum_{x',y'} (T(x',y')-I(x+x',y+y'))^2}{\sqrt{\sum_{x',y'}T(x',y')^2 \cdot \sum_{x',y'} I(x+x',y+y')^2}}`




			`* method=CV\_TM\_CCORR`


			`.. math::`

			`R(x,y)= \sum _{x',y'} (T(x',y') \cdot I(x+x',y+y'))`




			`* method=CV\_TM\_CCORR\_NORMED`


			`.. math::`

			`R(x,y)= \frac{\sum_{x',y'} (T(x',y') \cdot I'(x+x',y+y'))}{\sqrt{\sum_{x',y'}T(x',y')^2 \cdot \sum_{x',y'} I(x+x',y+y')^2}}`




			`* method=CV\_TM\_CCOEFF`


			`.. math::`

			`R(x,y)= \sum _{x',y'} (T'(x',y') \cdot I(x+x',y+y'))`


			`where`


			`.. math::`

			`\begin{array}{l} T'(x',y')=T(x',y') - 1/(w \cdot h) \cdot \sum _{x'',y''} T(x'',y'') \\ I'(x+x',y+y')=I(x+x',y+y') - 1/(w \cdot h) \cdot \sum _{x'',y''} I(x+x'',y+y'') \end{array}`




			`* method=CV\_TM\_CCOEFF\_NORMED`


			`.. math::`

			`R(x,y)= \frac{ \sum_{x',y'} (T'(x',y') \cdot I'(x+x',y+y')) }{ \sqrt{\sum_{x',y'}T'(x',y')^2 \cdot \sum_{x',y'} I'(x+x',y+y')^2} }`




			`After the function finishes the comparison, the best matches can be found as global minimums (`
			``CV_TM_SQDIFF``
			`) or maximums (`
			``CV_TM_CCORR``
			`and`
			``CV_TM_CCOEFF``
			`) using the`
			:ref:`MinMaxLoc`
			`function. In the case of a color image, template summation in the numerator and each sum in the denominator is done over all of the channels (and separate mean values are used for each channel).`