quotations
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@ -304,12 +304,12 @@ purposes) using the following algorithm:
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The original article describes a bend as:
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\begin{displayquote}[\cite{wang1998line}][]
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\begin{displaycquote}{wang1998line}
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A bend can be defined as that part of a line which contains a number of
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subsequent vertices, with the inflection angles on all vertices included in
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the bend being either positive or negative and the inflection of the bend's
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two end vertices being in opposite signs.
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\end{displayquote}
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\end{displaycquote}
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While it gives a good intuitive understanding of what the bend is, this section
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provides more technical details. Here are some non-obvious characteristics that
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@ -341,10 +341,10 @@ but with bends colored as polygons: each color is a distinctive bend.
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The gist of the section is in the original article:
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\begin{displayquote}[\cite{wang1998line}][]
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\begin{displaycquote}{wang1998line}
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But if the inflection that marks the end of a bend is quite small, people
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would not recognize this as the bend point of a bend
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\end{displayquote}
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\end{displaycquote}
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Figure~\ref{fig:fig5-gentle-inflection} visualizes original paper's Figure 5,
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when a single vertex is moved outwards the end of the bend.
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@ -501,6 +501,12 @@ This section introduces \textsc{adjusted size}, which trivially derives from
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Adjusted size becomes necessary later to compare bends with each other, and
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find out similar ones.
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\subsection{Isolated Bend}
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Bend itself and its extensions can be described by \textsc{average curvature},
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which is \textcquote{wang1998line}{geometrically defined as the ratio of
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inflection over the length of a curve.}
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\subsection{The Context of a Bend: Isolated and Similar Bends}
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To find out whether two bends are similar, they are compared by 3 components:
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@ -516,9 +522,13 @@ distance $d$ between those is calculated to differentiate between bends $p$ and
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$q$:
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\[
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d(p,q) = \sqrt{(adjsize_p - adjsize_q)^2 + (cmp_p - cmp_q)^2 + (baseline_p - baseline_q)^2}
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d(p,q) = \sqrt{(adjsize_p-adjsize_q)^2 +
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(cmp_p-cmp_q)^2 +
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(baseline_p-baseline_q)^2}
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\]
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The smaller the distance $d$, the more similar the bends are.
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\subsection{Elimination Operator}
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\subsection{Combination Operator}
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