more structure

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Motiejus Jakštys 2021-05-19 22:57:48 +03:00 committed by Motiejus Jakštys
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@ -294,9 +294,12 @@ valuable characterization of the river.
Sometimes low-water rivers in slender slopes have many bends next to each
other. In low resolutions (either in small-DPI screens or paper, or when the
river is sufficiently zoomed out, or both), the small bends will amalgamate to
a unintelligible blob. Figure~\onpage{fig:amalgamate1} and
figure~\onpage{fig:amalgamate2} are real-world examples where a river, normally
1 or 2 pixels wide, creates a few pixels wide blob due to a number of bends.
a unintelligible blob. Figure~\onpage{fig:pixel-amalgamation} illustrates two
real-world examples where a bendy river, normally 1 or 2 pixels wide, creates a
wide area, of which the shapes of the bend are unintelligible. In this example,
classical algorithms would remove these bends altogether. A cartographer would
retain a few of those distinctive bends, but would increase the distance
between the bends, remove some of the bends, or both.
\begin{figure}[h]
\includegraphics[width=\textwidth]{amalgamate1}
@ -304,9 +307,9 @@ figure~\onpage{fig:amalgamate2} are real-world examples where a river, normally
\label{fig:pixel-amalgamation}
\end{figure}
Therefore, a more robust
generalization algorithm is worthwhile for lookout.
For the reasons discussed in this section, the "classical" {\DP} and {\VW} are
not well suited for natural river generalization, and a more robust line
generalization algorithm is worthwhile for to look for.
\subsubsection{Modern approaches}
@ -519,6 +522,12 @@ This type of illustration works quite well, since polygons created from bends
are almost never overlapping, and discriminating different backgrounds is
easier than discriminating different line shapes or colors.
\subsection{Merging pieces of the river into one}
NOTE: explain how different river segments are merged into a single line. This
is not explained in the {\WM} paper, but is a necessary prerequisite. This is
implemented in \texttt{aggregate-rivers.sql}.
\subsection{Definition of a Bend}
\label{sec:definition-of-a-bend}
@ -694,7 +703,6 @@ takes to run this piece of the algorithm drops by $80\%$.
\subsection{Attributes of a Single Bend}
\textsc{Compactness Index} is "the ratio of the area of the polygon over the
circle whose circumference length is the same as the length of the
circumference of the polygon" \cite{wang1998line}. Given a bend, its
@ -780,26 +788,50 @@ The smaller the distance $d$, the more similar the bends are.
\subsection{Elimination Operator}
NOTE: not implemented.
\subsection{Combination Operator}
NOTE: not implemented.
\subsection{Exaggeration Operator}
NOTE: not implemented.
\section{Program Implementation}
NOTE: this should provide a higher-level overview of the written code:
\begin{itemize}
\item State machine (which functions call when).
\item Algorithmic complexity.
\item Expected runtime given the number of bends/vertices, some performance
experiments.
\end{itemize}
\section{Results of Experiments}
NOTE: this can only be filled after the algorithm implementation is complete.
\section{Conclusions}
\label{sec:conclusions}
NOTE: write when all the sections before this are be complete.
\section{Related Work and future suggestions}
\label{sec:related_work}
NOTE: write after section~\ref{sec:conclusions} is complete.
\printbibliography
\begin{appendices}
\section{Code listings}
This section contains code listings of a subset of files tightly related to the
{\WM} algorithm.
\subsection{Re-generating this paper}
\label{sec:code-regenerate}
@ -810,8 +842,11 @@ Like explained in section~\ref{sec:reproducing-the-paper}, illustrations in
\inputcode{bash}{extract-and-generate}
\subsection{Algorithm code listings}
\subsection{\texttt{ST\_SimplifyWV}}
\inputcode{postgresql}{wm.sql}
\subsection{\texttt{aggregate\_rivers}}
\inputcode{postgresql}{aggregate-rivers.sql}
\end{appendices}
\end{document}