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mj-msc.tex
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mj-msc.tex
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\documentclass[a4paper]{report}
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\documentclass[a4paper]{article}
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\usepackage[T1]{fontenc}
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%\usepackage[bitstream-charter]{mathdesign}
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@ -78,7 +78,7 @@ Current open-source line generalization solutions have their roots in
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\newpage
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\chapter{Introduction}
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\section{Introduction}
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\label{sec:introduction}
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When creating small-scale maps, often the detail of the data source is greater
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@ -118,13 +118,13 @@ Given the discussed complexities, a fine line between under-generalization
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found. Therein lies the complexity of generalization algorithms: all have
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different trade-offs.
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\chapter{Literature review}
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\section{Literature review}
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\label{sec:literature-review}
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A number of cartographic line generalization algorithms have been researched.
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The "classical" ones are {\DP} and {\VW}.
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\section{{\DP} and {\VW}}
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\subsection{{\DP} and {\VW}}
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\cite{douglas1973algorithms} and \cite{visvalingam1993line} are "classical"
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line generalization computer graphics algorithms. They are relatively simple to
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@ -152,7 +152,7 @@ generalization.
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<TODO: expand on deficiencies>
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\section{Modern approaches}
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\subsection{Modern approaches}
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Due to their simplicity and ubiquity, {\DP} and {\VW} have been established as
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go-to algorithms for line generalization. During recent years, alternatives
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@ -181,7 +181,7 @@ open-source tools is an important foundation for future cartographic
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experimentation and development, thus it it benefits the cartographic society
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as a whole.
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\chapter{Methodology}
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\section{Methodology}
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\label{sec:methodology}
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The original \cite{wang1998line} leaves something to be desired for a practical
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@ -199,7 +199,7 @@ every step of the algorithm.
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Algorithms discussed in this paper assume Euclidean geometry.
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\section{Vocabulary and terminology}
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\subsection{Vocabulary and terminology}
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This section defines vocabulary and terms as defined in the rest of the paper.
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@ -227,7 +227,7 @@ This section defines vocabulary and terms as defined in the rest of the paper.
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\end{description}
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\section{Automated tests}
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\subsection{Automated tests}
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\label{sec:automated-tests}
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As part of the algorithm realization, an automated test suite has been
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@ -251,7 +251,7 @@ The full test suite can be executed with a single command, and completes in a
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few seconds. Having an easily accessible test suite boosts confidence that no
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unexpected bugs have snug in while modifying the algorithm.
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\chapter{Description of the implementation}
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\section{Description of the implementation}
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Like alluded in section~\onpage{sec:introduction}, \cite{wang1998line} paper
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skims over certain details, which are important to implement the algorithm.
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@ -271,7 +271,7 @@ purposes) using the following algorithm:
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\item Color the polygons using distinct colors.
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\end{itemize}
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\section{Definition of a Bend}
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\subsection{Definition of a Bend}
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\label{sec:definition-of-a-bend}
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The original article describes a bend as:
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@ -310,7 +310,7 @@ but with bends colored as polygons: each color is a distinctive bend.
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\label{fig:fig8-definition-of-a-bend}
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\end{figure}
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\section{Gentle Inflection at End of a Bend}
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\subsection{Gentle Inflection at End of a Bend}
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The gist of the section is in the original article:
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@ -378,41 +378,40 @@ some bends that should be mutated. This implementation does it in the following
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The current implementation is the most straightforward, but not optimal:
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reversing of lines and bends could be avoided by walking backwards the lines.
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In this case, steps \ref{rev1} and \ref{rev2} could be remove. That would save
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both memory and computation time.
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In this case, steps \ref{rev1} and \ref{rev2} could be spared, thus saving
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memory and computation time.
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The "quite small angle", as mentioned in the article, was arbitrarily chosen to
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$\smallAngle$.
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The "quite small angle" was arbitrarily chosen to $\smallAngle$.
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\section{Self-line Crossing When Cutting a Bend}
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\subsection{Self-line Crossing When Cutting a Bend}
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\section{Attributes of a Single Bend}
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\subsection{Attributes of a Single Bend}
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\section{Shape of a Bend}
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\subsection{Shape of a Bend}
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\section{The Context of a Bend: Isolated and Similar Bends}
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\subsection{The Context of a Bend: Isolated and Similar Bends}
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\section{Elimination Operator}
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\subsection{Elimination Operator}
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\section{Combination Operator}
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\subsection{Combination Operator}
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\section{Exaggeration Operator}
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\subsection{Exaggeration Operator}
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\chapter{Program Implementation}
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\section{Program Implementation}
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\chapter{Results of Experiments}
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\section{Results of Experiments}
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\chapter{Conclusions}
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\section{Conclusions}
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\label{sec:conclusions}
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\chapter{Related Work and future suggestions}
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\section{Related Work and future suggestions}
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\label{sec:related_work}
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\printbibliography
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\begin{appendices}
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\chapter{Code listings}
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\section{Code listings}
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We strongly believe in the ability to reproduce the results is critical for any
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scientific work. To make it possible for this paper, all source files and
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