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1 \documentclass{article}
2 \def\kdots{,\ldots,}
3 \title{Not the Font-En-Tja font}
4 \author{HWN \& JCN}
5 \begin{document}
6 \maketitle
9 \section{Introduction}
11 This document are some design notes of the Feta font. Feta (not an
12 abbreviation of Font-En-Tja) is a font of music symbols. All MetaFont
13 sources are original. The symbols are modelled after various editions
14 of music, notably
15 \begin{itemize}
16 \item B\"arenreiter
17 \item Hofmeister
18 \item Breitkopf
19 \item Durand \& C'ie
20 \end{itemize}
22 The best references on Music engraving are Wanske\cite{wanske} and
23 Ross\cite{ross} quite some of their insights were used. Although it
24 is a matter of taste, I'd say that B\"arenreiter has the finest
25 typography of all.
28 \section{Bezier curves for slurs}
30 Objective: slurs in music are curved objects designating that notes
31 should fluently bound. They are drawn as smooth curves, with their
32 center thicker and the endings tapered.
34 There are some variants: the simplest slur shape only has the width as
35 parameter. Then we give some suggestions for tuning the shapes. The
36 simple slur algorithm is used for drawing ties as well.
40 \subsection{Simple slurs}
42 Long slurs are flat, whereas short slurs look like small circle arcs.
43 Details are given in Wanske\cite{ross} and Ross\cite{wanske}. The
44 shape of a slur can be given as a Bezier curve with four control
45 points:
47 \begin{eqnarray*}
48 B(t) &=& (1-t)^3c_1 +3(1-t)^2tc_2 + 3(1-t)t^2c_3 + t^3c_4.
49 \end{eqnarray*}
51 We will assume that the slur connects two notes of the same
52 pitch. Different slurs can be created by rotating the derived shape.
53 We will also assume that the slur has a vertical axis of symmetry
54 through its center. The left point will be the origin. So we have
55 the following equations for the control points $c_1\kdots c_4$.
57 \begin{eqnarray*}
58 c_1&=& (0,0)\\
59 c_2&=& (i, h)\\
60 c_3&=& (b-i, h)\\
61 c_4&=& (b, 0)
62 \end{eqnarray*}
64 The quantity $b$ is given, it is the width of the slur. The
65 conditions on the shape of the slur for small and large $b$ transform
67 \begin{eqnarray*}
68 h \to h_{\infty} , &&\quad b \to \infty\\
69 h \approx r_{0} b, &&\quad b \to 0.
70 \end{eqnarray*}
71 To tackle this, we will assume that $h = F(b)$, for some kind of
72 $F(\cdot)$. One function that satisfies the above conditions is
74 F(b) = h_{\infty} \frac{2}{\pi} \arctan \left( \frac{\pi r_0}{2
75 h_{\infty}} b \right).
78 For satisfying results we choose $h_{\infty} = 2\cdot \texttt{interline}$
79 and $r_0 = \frac 13$.
81 \subsection{Height correction}
83 Aside from being a smooth curve, slurs should avoid crossing
84 enclosed notes and their stems.
86 An easy way to achieve this is to extend the slur's height,
87 so that the slur will curve just above any disturbing notes.
89 The parameter $i$ determines the flatness of the curve. Satisfying
90 results have been obtained with $i = h$.
92 The formula can be generalised to allow for corrections in the shape,
93 \begin{eqnarray*}
94 c_1&=& (0,0)\\
95 c_2&=& (i', h')\\
96 c_3&=& (b-i', h')\\
97 c_4&=& (b, 0)
98 \end{eqnarray*}
99 Where
101 i' = h(b) (1 + i_{corr}), \quad h' = h(b) (1 + h_{corr}).
104 The default values for these corrections are $0$. A $h_{corr}$ that is
105 negative, makes the curve flatter in the center. A $h_{corr}$ that is
106 positive make the curve higher.
108 At every encompassed note's x position the difference $\delta _y$
109 between the slur's height and the note is calculated. The greatest
110 $\delta _y$ is used to calculate $h_{corr}$ is by lineair extrapolation.
112 However, this simple method produces satisfactory results only for
113 small and symmetric disturbances.
116 \subsection{Tangent method correction}
118 A somewhat more elaborate\footnote{While staying in the realm
119 of emperic computer science} way of having a slur avoid
120 disturbing notes is by first defining the slur's ideal shape
121 and then using the height correction. The ideal shape of a
122 slur can be guessed by calculating the tangents of the disturbing
123 notes:
124 % a picture wouldn't hurt...
125 \begin{eqnarray*}
126 y_{disturb,l} &=& \rm{rc}_l x\\
127 y_{disturb,r} &=& \rm{rc}_r + c_{3,x},
128 \end{eqnarray*}
129 where
130 \begin{eqnarray*}
131 \rm{rc}_l &=& \frac{y_{disturb,l} - y_{encompass,1}}
132 {x_{disturb,l} - x_{encompass,1}}\dot x\\
133 \rm{rc}_r &=& \frac{y_{encompass,n} - y_{disturb,r}}
134 {x_{encompass,n} - x_{disturb,r}} \dot x + c_{3,x}.
135 \end{eqnarray*}
137 We assume that having the control points $c_2$ and $c_3$ located
138 on tangent$_1$ and tangent$_2$ resp.
139 % t: tangent
140 \begin{eqnarray*}
141 y_{tangent,l} &=& \alpha \rm{rc}_l x\\
142 y_{tangent,r} &=& \alpha \rm{rc}_r + c_{3,x}.
143 \end{eqnarray*}
145 Beautiful slurs have rather strong curvature at the extreme
146 control points. That's why we'll have $\alpha > 1$.
147 Satisfactory resulsts have been obtained with
149 \alpha \approx 2.4.
152 The positions of control points $c_2$ and $c_3$ are obtained
153 by solving with the height-line
154 \begin{eqnarray*}
155 y_h &=& \rm{rc}_h + c_h.
156 \end{eqnarray*}
158 The top-line runs through the points disturb$_{left}$ and
159 disturb$_{right}$. In the case that
161 z_{disturb,l} = z_{disturb,r},
163 we'll have
165 \angle(y_{tangent,l},y_h) = \angle(y_{tangent,r},y_h).
170 \section{Sizes}
172 Traditional engraving uses a set of 9 standardised sizes for Staffs
173 (running from 0 to 8).
175 We have tried to measure these (helped by a magnifying glass), and
176 found the staffsizes in table~\ref{fonts:staff-size}. One should note that
177 these are estimates, so I think there could be a measuring error of ~
178 .5 pt. Moreover [Ross] states that not all engravers use exactly
179 those sizes.
181 \begin{table}[h]
182 \begin{center}
183 \begin{tabular}{lll}
184 Staffsize &Numbers &Name\\
185 \hline\\
186 26.2pt &No. 0\\
187 22.6pt &No. 1 &Giant/English\\
188 21.3pt &No. 2 &Giant/English\\
189 19.9pt &No. 3 &Regular, Ordinary, Common\\
190 19.1pt &No. 4 &Peter\\
191 17.1pt &No. 5 &Large middle\\
192 15.9pt &No. 6 &Small middle\\
193 13.7pt &No. 7 &Cadenza\\
194 11.1pt &No. 8 &Pearl\\
196 \end{tabular}
197 \caption{Foo}
198 \label{fonts:staff-size}
199 \end{center}
200 \end{table}
202 Ross states that the dies (the stamps to make the symbols) come in
203 12 different sizes.
205 \bibliographystyle{plain}
206 \bibliography{engraving}
210 \end{document}