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In no event shall copyright holders or contributors be liable for any direct, indirect, incidental, special, exemplary, or consequential damages (including, but not limited to, procurement of substitute goods or services; loss of use, data, or profits; or business interruption) however caused and on any theory of liability, whether in contract, strict liability, or tort (including negligence or otherwise) arising in any way out of the use of this software, even if advised of the possibility of such damage. */ #ifndef __OPENCV_TEXT_HPP__ #define __OPENCV_TEXT_HPP__ #include "opencv2/text/erfilter.hpp" #include "opencv2/text/ocr.hpp" #include "opencv2/text/textDetector.hpp" /** @defgroup text Scene Text Detection and Recognition The opencv_text module provides different algorithms for text detection and recognition in natural scene images. @{ @defgroup text_detect Scene Text Detection Class-specific Extremal Regions for Scene Text Detection -------------------------------------------------------- The scene text detection algorithm described below has been initially proposed by Lukás Neumann & Jiri Matas @cite Neumann11. The main idea behind Class-specific Extremal Regions is similar to the MSER in that suitable Extremal Regions (ERs) are selected from the whole component tree of the image. However, this technique differs from MSER in that selection of suitable ERs is done by a sequential classifier trained for character detection, i.e. dropping the stability requirement of MSERs and selecting class-specific (not necessarily stable) regions. The component tree of an image is constructed by thresholding by an increasing value step-by-step from 0 to 255 and then linking the obtained connected components from successive levels in a hierarchy by their inclusion relation: ![image](pics/component_tree.png) The component tree may contain a huge number of regions even for a very simple image as shown in the previous image. This number can easily reach the order of 1 x 10\^6 regions for an average 1 Megapixel image. In order to efficiently select suitable regions among all the ERs the algorithm make use of a sequential classifier with two differentiated stages. In the first stage incrementally computable descriptors (area, perimeter, bounding box, and Euler's number) are computed (in O(1)) for each region r and used as features for a classifier which estimates the class-conditional probability p(r|character). Only the ERs which correspond to local maximum of the probability p(r|character) are selected (if their probability is above a global limit p_min and the difference between local maximum and local minimum is greater than a delta_min value). In the second stage, the ERs that passed the first stage are classified into character and non-character classes using more informative but also more computationally expensive features. (Hole area ratio, convex hull ratio, and the number of outer boundary inflexion points). This ER filtering process is done in different single-channel projections of the input image in order to increase the character localization recall. After the ER filtering is done on each input channel, character candidates must be grouped in high-level text blocks (i.e. words, text lines, paragraphs, ...). The opencv_text module implements two different grouping algorithms: the Exhaustive Search algorithm proposed in @cite Neumann12 for grouping horizontally aligned text, and the method proposed by Lluis Gomez and Dimosthenis Karatzas in @cite Gomez13 @cite Gomez14 for grouping arbitrary oriented text (see erGrouping). To see the text detector at work, have a look at the textdetection demo: @defgroup text_recognize Scene Text Recognition @} */ #endif