\documentclass[a4paper]{article} \usepackage{hyperref} \title{Using local binary patterns to read license plates in photographs} \date{November 17th, 2011} % Paragraph indentation \setlength{\parindent}{0pt} \setlength{\parskip}{1ex plus 0.5ex minus 0.2ex} \begin{document} \maketitle \section*{Project members} Gijs van der Voort\\ Richard Torenvliet\\ Jayke Meijer\\ Tadde\"us Kroes\\ Fabi\'en Tesselaar \tableofcontents \setcounter{secnumdepth}{1} \section{Problem description} License plates are used for uniquely identifying motorized vehicles and are made to be read by humans from great distances and in all kinds of weather conditions. Reading license plates with a computer is much more difficult. Our dataset contains photographs of license plates from various angles and distances. This means that not only do we have to implement a method to read the actual characters, but also have to determine the location of the license plate and its transformation due to different angles. We will focus our research on reading the transformed characters on the license plate, of which we know where the letters are located. This is because Microsoft recently published a new and effective method to find the location of text in an image. In short our program must be able to do the following: \begin{enumerate} \item Use perspective transformation to obtain an upfront view of license plate. \item Reduce noise where possible. \item Extract each character using the location points in the info file. \item Transform character to a normal form. \item Create a local binary pattern histogram vector. \item Match the found vector with a learning set. \end{enumerate} \section{Solution} Now that the problem is defined, the next step is stating a solution. This will come in a few steps as well. \subsection{Transformation} A simple perspective transformation will be sufficient to transform and resize the plate to a normalized format. The corner positions of license plates in the dataset are supplied together with the dataset. \subsection{Reducing noise} Small amounts of noise will probably be suppressed by usage of a Gaussian filter. A real problem occurs in very dirty license plates, where branches and dirt over a letter could radically change the local binary pattern. A question we can ask ourselves here, is whether we want to concentrate ourselves on these exceptional cases. By law, license plates have to be readable. Therefore, we will first direct our attention at getting a higher score in the 'regular' test set before addressing these cases. Considered the fact that the LBP algorithm divides a letter into a lot of cells, there is a good change that a great number of cells will still match the learning set, and thus still return the correct character as a best match. Therefore, we expect the algorithm to be very robust when dealing with noisy images. \subsection{Extracting a letter} Because we are already given the locations of the characters, we only need to transform those locations using the same perspective transformation used to create a front facing license plate. The next step is to transform the characters to a normalized manner. The size of the letter W is used as a standard to normalize the width of all the characters, because W is the widest character of the alphabet. We plan to also normalize the height of characters, the best manner for this is still to be determined. \begin{enumerate} \item Crop the image in such a way that the character precisely fits the image. \item Scale the image to a standard height. \item Extend the image on either the left or right side to a certain width. \end{enumerate} The resulting image will always have the same size, the character contained will always be of the same height, and the character will alway be positioned at either the left of right side of the image. \subsection{Local binary patterns} Once we have separate digits and characters, we intent to use Local Binary Patterns to determine what character or digit we are dealing with. Local Binary Patters are a way to classify a texture based on the distribution of edge directions in the image. Since letters on a license plate consist mainly of straight lines and simple curves, LBP should be suited to identify these. To our knowledge, LBP has yet not been used in this manner before. Therefore, it will be the first thing to implement, to see if it lives up to the expectations. When the proof of concept is there, it can be used in the final program. Important to note is that due to the normalization of characters before applying LBP. Therefore, no further normalization is needed on the histograms. Given the LBP of a character, a Support Vector Machine can be used to classify the character to a character in a learning set. The SVM uses \subsection{Matching the database} Given the LBP of a character, a Support Vector Machine can be used to classify the character to a character in a learning set. The SVM uses the collection of histograms of an image as a feature vector. The SVM can be trained with a subsection of the given dataset called the ''Learning set''. Once trained, the entire classifier can be saved as a Pickle object\footnote{See \url{http://docs.python.org/library/pickle.html}} for later usage. \end{document}