\DocumentMetadata{pdfstandard=A-2b, lang=en-GB} \documentclass[a4paper,12pt]{scrartcl} \usepackage{mathtools, array, varioref} \usepackage[british]{babel} %\usepackage[default,defaultsans]{lato} \usepackage{fontspec} \begin{filecontents}{Lato.fontspec} \defaultfontfeatures[Lato] { UprightFont = Lato-Regular.ttf , BoldFont = Lato-Bold.ttf , ItalicFont = Lato-Italic.ttf , BoldItalicFont = Lato-BoldItalic.ttf , } \end{filecontents} \setmainfont{Lato} \setsansfont{Lato} \usepackage{realscripts} \usepackage{fourier-orns} \usepackage{lete-sans-math} \setmonofont{Inconsolatazi4}[Scale=MatchLowercase, StylisticSet={2,3}] \usepackage{subfig} \captionsetup[subtable]{position=top} \usepackage{microtype} \usepackage{setspace} \setstretch{1.10} \usepackage{hyperref} \hypersetup{pdftitle={Lete Sans Math User’s Guide}, pdfauthor={Chenjing Bu \& Daniel Flipo}, bookmarksopen, colorlinks } \newcommand*{\hlabel}[1]{\phantomsection\label{#1}} \newcommand*{\LAotf}{Lete~Sans~Math} \newcommand*{\pkg}[1]{\texttt{#1}} \newcommand*{\file}[1]{\texttt{#1}} \newcommand*{\opt}[1]{\texttt{#1}} \newcommand*{\cmd}[1]{\texttt{\textbackslash #1}} \newcommand*{\scmd}[1]{\texttt{\small\textbackslash #1}} \newcommand*{\showtchar}[1]{\cmd{#1}~\csname #1\endcsname} \newcommand*{\showmchar}[1]{\cmd{#1}~$(\csname #1\endcsname)$} \newcommand*{\showmchardollar}[1]{\texttt{\$\cmd{#1}\$}~$(\csname #1\endcsname)$} \renewcommand{\labelitemi}{\lefthand} \title{\decofourleft\,\LAotf\,\decofourright} \author{Chenjing Bu --- Daniel Flipo\\ \url{https://github.com/abccsss/LeteSansMath}} \newcommand*{\version}{0.45} \setlength{\parindent}{0pt} \setlength{\parskip}{12pt plus 3pt minus 3pt} \begin{document} \maketitle \section{What is \LAotf{}?} \LAotf{} is an OpenType maths font meant to be used with the Lato fonts, or other sans-serif text fonts. It requires LuaTeX or XeTeX as engine and the \pkg{unicode-math} package\footnote{Please read the documentation \file{unicode-math.pdf}.}. Please note that the current version (\version) is \emph{experimental, do expect metrics and glyphs to change} until version 1.0 is reached. Comments, suggestions and bug reports are welcome! Some examples% \footnote{The second one is borrowed from the LaTeX Companion, 3\textsuperscript{rd} edition.}: \[ \int_0^1 \frac{1}{x^x} \, \symup{d} x = \sum_{n=1}^{\infty} \frac{1}{n^n} \] \begin{equation*} \begin{split} \iiiint\limits_{\symbf{Q}} f(w,x,y,z)\,\symup{d}w\,\symup{d}x\,\symup{d}y \,\symup{d}z &\leq \oint_{\symbf{\partial Q}} f' \left( \max \left\lbrace \frac{\lVert w \rVert}{\lvert w^{2} + x^{2} \rvert} ; \frac{\lVert z \rVert}{\lvert y^{2} + z^{2} \rvert} ; \frac{\lVert w \oplus z \rVert}{\lvert x \oplus y \rvert} \right\rbrace \right) \\ &\precapprox \biguplus_{\mathbb{Q} \Subset \bar{\symbf{Q}}} \left[ f^{\ast} \left( \frac{\left\lmoustache\mathbb{Q}(t)\right\rmoustache}{\sqrt{1 - t^{2}}} \right) \right]_{t=\alpha}^{t=\vartheta} - ( \Delta + \nu -v )^{3} \end{split} \end{equation*} \section{Usage} \subsection{Calling \cmd{setmathfont}} A basic call for \LAotf{} would be: \begin{verbatim} \usepackage{unicode-math} \setmathfont{LeteSansMath.otf} % Call by file name or \setmathfont{Lete Sans Math} % Call by font name \end{verbatim} this loads \LAotf{} as maths font% \footnote{Both calls work equally well with LuaTeX; with XeTeX a call by font name will fail unless the font is declared as a \emph{system font}.} with the default options, see subsections~\vref{ssection-um}, \vref{ssection-cv} and~\vref{ssection-ss} for customisation. %\enlargethispage*{1.0\baselineskip} Please note that the text fonts have to be chosen separately, f.i.: \label{sec:setfont} \begin{verbatim} \setsansfont{Lato}[Extension = .ttf, UprightFont = *-Regular, BoldFont = *-Bold, ItalicFont = *-Italic, BoldItalicFont = *-BoldItalic] \end{verbatim} otherwise you would get Latin Modern for text fonts. \subsection{Calling \pkg{lete-sans-math.sty} (recommended)} As an alternative to load \LAotf{} you can type:\\[.5\baselineskip] \verb+\usepackage[ +\textit{options} \footnote{Possible \textit{options} are \opt{tight}, \opt{Scale=} or any of the options described in sections~\ref{ssection-um}, \ref{ssection-cv} and \ref{ssection-ss}.}% \verb+ ]{lete-sans-math}+\\[.5\baselineskip] it loads \pkg{unicode-math} with the default options, sets \LAotf{} as maths font and does a bit more: \begin{enumerate} \item it checks at \verb+\begin{document}+ if packages \pkg{amssymb} or \pkg{latexsym} are loaded and issues warnings in case they are; \item it provides aliases for glyphs named differently in Unicode, so that all \pkg{latexsym} or AMS commands are also available; \item it defines specific maths characters like \showmchar{BbbDelta}, \showmchar{parallelslant}, \showmchar{shortparallelslant}, etc.; \item it provides an option \opt{tight} which reduces spacing (\cmd{thinmuskip}, \cmd{medmuskip} and \cmd{thickmuskip}) in maths mode. \end{enumerate} Please note that the \pkg{lete-sans-math} package does not load any text fonts. The Lato text fonts can be loaded directly (see section~\ref{sec:setfont}), or via the \pkg{lato} package% \footnote{The \pkg{lato} package loads all available weights, \texttt{Hairline} to \texttt{Black}, hence loading takes significantly longer…} ---see this package’s documentation, file \file{lato.pdf}, for all the available options: \\ \verb+\usepackage[default]{lato}+\\ will load the Lato text fonts as main (roman) font while \\ \verb+\usepackage[defaultsans]{lato}+\\ will load the Lato text fonts as sans font (use both options if necessary). Consider loading \pkg{realscripts.sty} which redefines \verb+\textsuperscript+ to output the \emph{real} superscripts available with the Lato fonts: M\textsuperscript{r}, M\textsuperscript{lle}, N\textsuperscript{2} instead of \emph{faked} ones, M\fakesuperscript{r}, M\fakesuperscript{lle}, N\fakesuperscript{2}. The \pkg{lete-sans-math} also provides a \opt{Scale=}\textsl{} option meant to be used to load the \LAotf{} font together with text fonts other than Lato, while keeping the advantages 1. to~4. pointed in the preceding list, f.i. \verb+\usepackage[Scale=0.98]{lete-sans-math}+ \section{What is provided?} \LAotf{} provides all common \pkg{unicode-math} glyphs plus all glyphs available in the \pkg{amssymb} and \pkg{latexsym} packages. Therefore, the latter two packages \emph{should not} be loaded as they might override \LAotf{} glyphs. A full list of available glyphs is shown in file \file{unimath-lete.pdf} which also shows the coverage of other sans-serif maths fonts compared to the serif maths fonts NewComputerModern and Cambria. \subsection{Upright or slanted?} \label{ssection-um} Package \pkg{unicode-math} follows \TeX{} conventions for Latin and Greek letters: in maths mode, the default option (\opt{math-style=TeX}) prints Latin letters $a$…$z$ $A$…$Z$ and lowercase Greek letters $\alpha$…$\omega$ slanted (italic) while uppercase Greek letters $\Alpha \Beta \Gamma$…$\Omega$ are printed upright. This can be changed by option \opt{math-style} as shown in table~\vref{math-style}. \begin{table}[ht] \centering \caption{Effects of the \opt{math-style} package option.} \hlabel{math-style} \begin{tabular}{@{}>{\ttfamily}lcc@{}} \hline \rmfamily Package option & Latin & Greek \\ \hline math-style=ISO & $(a,z,B,X)$ & $\symit{(\alpha,\beta,\Gamma,\Xi)}$ \\ math-style=TeX & $(a,z,B,X)$ & $(\symit\alpha,\symit\beta,\symup\Gamma,\symup\Xi)$ \\ math-style=french & $(a,z,\symup B,\symup X)$ & $(\symup\alpha,\symup\beta,\symup\Gamma,\symup\Xi)$ \\ math-style=upright & $(\symup a,\symup z,\symup B,\symup X)$ & $(\symup\alpha,\symup\beta,\symup\Gamma,\symup\Xi)$ \\ \hline \end{tabular} \end{table} Bold letters are printed upright except lowercase Greek letters which are slanted (the default option is \opt{bold-style=TeX}). This can be changed by option \opt{bold-style} as shown in table~\vref{bold-style}. \begin{table}[ht] \centering \caption{Effects of the \opt{bold-style} package option.} \hlabel{bold-style} \begin{tabular}{@{}>{\ttfamily}lcc@{}} \hline \rmfamily Package option & Latin & Greek \\ \hline bold-style=ISO & $(\symbfit a, \symbfit z, \symbfit B, \symbfit X)$ & $(\symbfit\alpha, \symbfit\beta, \symbfit\Gamma, \symbfit\Xi)$ \\ bold-style=TeX & $(\symbfup a,\symbfup z,\symbfup B,\symbfup X)$ & $(\symbfit\alpha, \symbfit\beta,\symbfup \Gamma,\symbfup \Xi)$ \\ bold-style=upright & $(\symbfup a,\symbfup z,\symbfup B,\symbfup X)$ & $(\symbfup \alpha,\symbfup \beta,\symbfup \Gamma,\symbfup \Xi)$ \\ \hline \end{tabular} \end{table} Other possible customisation: $\nabla$ is printed upright and $\partial$ is printed slanted by default, but \opt{nabla=italic} and \opt{partial=upright} can change this. All these options are offered by the \pkg{unicode-math} package, they can be added to the \cmd{setmathfont} call as well% \footnote{IMHO it is easier to add \emph{all options} to the \cmd{setmathfont} command.}, for example: \verb+\setmathfont{LeteSansMath.otf}[math-style=french,partial=upright]+ will print for the code \verb|\[ \frac{\partial f}{\partial x} = \alpha \symbf{V} + a\nabla\Gamma|\\ \verb| + \symbf{\beta}\symbf{M} \]| \setmathfont{LeteSansMath.otf}[math-style=french,partial=upright] \[\frac{\partial f}{\partial x} = \alpha \symbf{V} + a\nabla\Gamma + \symbf{\beta}\symbf{M} \] while the default settings would print \setmathfont{LeteSansMath.otf}[math-style=TeX,partial=italic] \[\frac{\partial f}{\partial x} = \alpha \symbf{V} + a\nabla\Gamma + \symbf{\beta}\symbf{M} \] Both shapes remain available anytime: \verb+$\uppi,\itpi$+ prints $\uppi, \itpi$. If your text editor is able to handle Greek letters or maths symbols, they can be entered in the code instead control sequences (i.e. $\symup{α}$, $\symup{β}$, $\symup{Γ}$,… for \cmd{alpha}, \cmd{beta}, \cmd{Gamma},…). \subsection{Character variants} \label{ssection-cv} \LAotf{} provides nine ``Character Variants'' options, listed on table~\vref{cv}, to choose between different glyphs for Greek characters and some others. For instance, to get \cmd{epsilon} and \cmd{phi} typeset as $\varepsilon$ and $\varphi$ instead of $\epsilon$ and $\phi$, you can add option \verb+CharacterVariant={3,6}+ to the \cmd{setmathfont} call: \verb+\setmathfont{LeteSansMath.otf}[CharacterVariant={3,6}]+ \begin{table}[ht] \centering \caption{Character variants.} \hlabel{cv} \begin{tabular}{@{}>{\ttfamily}lccl@{}} \hline & Default & Variant & Name\\ \hline cv01 & $\hslash$ & $\mithbar$ & \cmd{hslash} \\ cv02 & $\emptyset$ & $\varemptyset$ & \cmd{emptyset} \\ cv03 & $\epsilon$ & $\varepsilon$ & \cmd{epsilon} \\ cv04 & $\kappa$ & $\varkappa$ & \cmd{kappa} \\ cv05 & $\pi$ & $\varpi$ & \cmd{pi} \\ cv06 & $\phi$ & $\varphi$ & \cmd{phi} \\ cv07 & $\rho$ & $\varrho$ & \cmd{rho} \\ cv08 & $\sigma$ & $\varsigma$ & \cmd{sigma} \\ cv09 & $\theta$ & $\vartheta$ & \cmd{theta} \\ cv10 & $\Theta$ & $\varTheta$ & \cmd{Theta}\\ cv11 & $g$ & $\mitvarg$ & g \\ \hline \end{tabular} \end{table} This works for all shapes and weights of these characters: f.i.\ % \verb+$\symbf{\epsilon}$+, \verb+$\symbf{\phi}$+ are output as \setmathfont{LeteSansMath.otf}[CharacterVariant={3,6}]$\symbf{\epsilon}$, $\symbf{\phi}$ instead of \setmathfont{LeteSansMath.otf}$\symbf{\epsilon}$, $\symbf{\phi}$. If \opt{math-style=french} has been chosen, \verb+\epsilon+ and \verb+\phi+ are output as $\symup{\varepsilon}$ and $\symup{\varphi}$ (upright). Please note that curly braces are mandatory whenever more than one ``Character Variant'' is selected. Note about \cmd{hbar}: \pkg{amsmath} provides two different glyphs (italic $h$ with horizontal or diagonal stroke) while \pkg{unicode-math} defines \cmd{hbar} as \cmd{hslash} (U+210F). \pkg{lete-sans-math} follows \pkg{unicode-math}; the italic $h$ with horizontal stroke can be printed using \cmd{hslash} or \cmd{hbar} together with character variant \texttt{cv01} or with \cmd{mithbar} (replacement for AMS’ command \cmd{hbar}). \subsection{Stylistic sets} \label{ssection-ss} \LAotf{} provides five ``Stylistic Sets'' options to choose between different glyphs for families of maths symbols. \verb+StylisticSet=4+, alias% \footnote{These \texttt{Style} aliases are provided by \file{lete-sans-math.sty}.} \verb+Style=leqslant+, converts inequalities into their slanted variants, see table~\vref{ss04}. \verb+StylisticSet=5+, alias \verb+Style=smaller+, converts some symbols into their smaller variants, see table~\vref{ss05}. \begin{table}[ht] \centering \caption{Stylistic Sets 4 and 5} \subfloat[\texttt{Style=leqslant\quad (+ss04)}]{\hlabel{ss04}% \begin{tabular}[t]{@{}lcc@{}} \hline Command & Default & Variant \\ \hline \cmd{leq} & $\leq$ & $\leqslant$ \\ \cmd{geq} & $\geq$ & $\geqslant$ \\ \cmd{nleq} & $\nleq$ & $\nleqslant$ \\ \cmd{ngeq} & $\ngeq$ & $\ngeqslant$ \\ \cmd{leqq} & $\leqq$ & $\leqqslant$ \\ \cmd{geqq} & $\geqq$ & $\geqqslant$ \\ \cmd{nleqq} & $\nleqq$ & $\nleqqslant$ \\ \cmd{ngeqq} & $\ngeqq$ & $\ngeqqslant$ \\ \cmd{eqless} & $\eqless$ & $\eqslantless$ \\ \cmd{eqgtr} & $\eqgtr$ & $\eqslantgtr$ \\ \cmd{lesseqgtr} & $\lesseqgtr$ & $\lesseqslantgtr$ \\ \cmd{gtreqless} & $\gtreqless$ & $\gtreqslantless$ \\ \cmd{lesseqqgtr} & $\lesseqqgtr$ & $\lesseqqslantgtr$ \\ \cmd{gtreqqless} & $\gtreqqless$ & $\gtreqqslantless$ \\ \hline \end{tabular} }\hspace{10mm} % eof subfloat \subfloat[\texttt{Style=smaller\quad (+ss05)}]{\hlabel{ss05}% \begin{tabular}[t]{@{}lcc@{}} \hline Command & Default & Variant \\ \hline \cmd{in} & $\in$ & $\smallin$ \\ \cmd{ni} & $\ni$ & $\smallni$ \\ \cmd{mid} & $\mid$ & $\shortmid$ \\ \cmd{nmid} & $\nmid$ & $\nshortmid$ \\ \cmd{parallel} & $\parallel$ & $\shortparallel$ \\ \cmd{nparallel} & $\nparallel$ & $\nshortparallel$ \\ \cmd{parallelslant} & $\parallelslant$ & $\shortparallelslant$ \\ \cmd{nparallelslant} & $\nparallelslant$ & $\nshortparallelslant$ \\ \hline \end{tabular} }% eof subfloat \end{table} %\pagebreak[4] \verb+StylisticSet=6+, alias \verb+Style=subsetneq+, converts some inclusion symbols, as shown in table~\vref{ss06}. \verb+StylisticSet=7+, alias \verb+Style=parallelslant+, converts ``parallel'' symbols into their slanted variants, see table~\vref{ss07}. \begin{table}[ht] \centering \caption{Stylistic Sets 6 and 7} \subfloat[\texttt{Style=subsetneq\quad (+ss06)}]{\hlabel{ss06}% \begin{tabular}[t]{@{}lcc@{}} \hline Command & Default & Variant \\ \hline \cmd{subsetneq} & $\subsetneq$ & $\varsubsetneq$ \\ \cmd{supsetneq} & $\supsetneq$ & $\varsupsetneq$ \\ \cmd{subsetneqq} & $\subsetneqq$ & $\varsubsetneqq$ \\ \cmd{supsetneqq} & $\supsetneqq$ & $\varsupsetneqq$ \\ \hline \end{tabular} }\hspace{10mm} % eof subfloat \subfloat[\texttt{Style=parallelslant\quad (+ss07)}]{\hlabel{ss07}% \begin{tabular}[t]{@{}lcc@{}} \hline Command & Default & Variant \\ \hline \cmd{parallel} & $\parallel$ & $\parallelslant$ \\ \cmd{nparallel} & $\nparallel$ & $\nparallelslant$ \\ \cmd{shortparallel} & $\shortparallel$ & $\shortparallelslant$ \\ \cmd{nshortparallel} & $\nshortparallel$ & $\nshortparallelslant$ \\ \hline \end{tabular} } % eof subfloat \end{table} To enable Stylistic Sets 4 and 8 for \LAotf{}, you should enter \verb+\setmathfont{LeteSansMath.otf}[StylisticSet={4,8}] or+\\ \verb+\usepackage[Style={leqslant,upint}]{lete-sans-math}+ then, \verb+\[x\leq y \quad \int_{a}^{b} f(x) \;\symup{d}x\]+ will print as \setmathfont{LeteSansMath.otf}[StylisticSet={4,8}] \[x\leq y \quad \int_{a}^{b} f(x) \;\symup{d}x\] instead of \setmathfont{LeteSansMath.otf} \[x\leq y \quad \int_{a}^{b} f(x) \;\symup{d}x\] %\pagebreak[4] \verb+StylisticSet=8+, alias% \footnote{These \texttt{Style} aliases are provided by \file{lete-sans-math.sty}.} \verb+Style=upint+, converts integrals signs into their upright variants, see table~\vref{ss08}. \begin{table}[ht] \let\DS\displaystyle \centering \caption{Style=upint\quad (+ss08)}\hlabel{ss08} \begin{tabular}[t]{@{}l*{8}c@{}} \hline Command &\cmd{int} &\cmd{iint} &\cmd{iiint} &\cmd{iiiint} &\cmd{oint} &\cmd{oiint} &\cmd{oiiint} \\ \hline Default\rule[-15pt]{0pt}{35pt} &$\DS\int$ &$\DS\iint$ &$\DS\iiint$ &$\DS\iiiint$ &$\DS\oint$ &$\DS\oiint$ &$\DS\oiiint$ \\[\baselineskip] \setmathfont{LeteSansMath.otf}[Style=upint] Upright\rule[-15pt]{0pt}{30pt} &$\DS\int$ &$\DS\iint$ &$\DS\iiint$ &$\DS\iiiint$ &$\DS\oint$ &$\DS\oiint$ &$\DS\oiiint$ \\ \hline \end{tabular}\\[\baselineskip] \setmathfont{LeteSansMath.otf} \begin{tabular}[t]{@{}l*{4}c@{}} \hline Command &\scmd{intclockwise} &\scmd{awint} &\scmd{varointclockwise} &\scmd{ointctrclockwise} \\ \hline Default\rule[-15pt]{0pt}{35pt} &$\DS\intclockwise$ &$\DS\awint$ &$\DS\varointclockwise$ &$\DS\ointctrclockwise$ \\ \setmathfont{LeteSansMath.otf}[Style=upint] Upright\rule[-15pt]{0pt}{30pt} &$\DS\intclockwise$ &$\DS\awint$ &$\DS\varointclockwise$ &$\DS\ointctrclockwise$ \\ \hline \end{tabular} \end{table} \setmathfont{LeteSansMath.otf} \subsection{Other font features} \label{ssec-other-features} To get oldstyle numbers in maths, the feature \texttt{+onum} is available: \verb+\setmathfont{LeteSansMath.otf}[Numbers=OldStyle] or+\\ \verb+\usepackage[Style=fulloldstyle]{lete-sans-math}+ \setmathfont{LeteSansMath.otf}[Numbers=OldStyle] $0123456789, \symbf{0123456789}$ \setmathfont{LeteSansMath.otf} \subsection{Standard LaTeX maths commands} \label{ssec-math-commands} All standard LaTeX maths commands, all \pkg{amssymb} commands and all \pkg{latexsym} commands are supported, for some of them loading \pkg{lete-sans-math.sty} is required. Various wide accents and extensible arrows are also supported: \begin{itemize} \item \cmd{wideoverbar} and \cmd{mathunderbar}% \footnote{\cmd{overline} and \cmd{underline} are not font related, they are based on \cmd{rule}.} \[\wideoverbar{x}\quad \wideoverbar{xy}\quad \wideoverbar{xyz}\quad \wideoverbar{A\cup B}\quad \wideoverbar{A\cup (B\cap C)\cup D}\quad \mathunderbar{m+n+p}\] \item \cmd{widehat} and \cmd{widetilde} \[\widehat{x}\; \widehat{xx} \;\widehat{xxx} \;\widehat{xxxx}\; \widehat{xxxxx} \;\widehat{xxxxxx} \;\widetilde{x}\; \widetilde{xx}\; \widetilde{xxx} \;\widetilde{xxxx} \;\widetilde{xxxxx}\; \widetilde{xxxxxx}\] \item \cmd{widecheck} and \cmd{widebreve} \[\widecheck{x}\quad \widecheck{xxxx}\quad \widecheck{xxxxxx}\quad \widebreve{x}\quad \widebreve{xxxx}\quad \widebreve{xxxxxx}\] \item \cmd{overparen} and \cmd{underparen} \[\overparen{x}\quad \overparen{xy}\quad \overparen{xyz}\quad \mathring{\overparen{A\cup B}}\quad \overparen{A\cup (B\cap C)\cup D}^{\smwhtcircle}\quad \overparen{x+y}^{2}\quad \overparen{a+b+...+z}^{26}\] \[\underparen{x}\quad \underparen{xz} \quad \underparen{xyz} \quad \underparen{x+z}_{2}\quad \underparen{a+b+...+z}_{26}\] \item \cmd{overbrace} and \cmd{underbrace} \[\overbrace{a}\quad \overbrace{ab}\quad \overbrace{abc}\quad \overbrace{abcd}\quad \overbrace{abcde}\quad \overbrace{a+b+c}^{3}\quad \overbrace{ a+b+. . . +z }^{26}\] \[\underbrace{a}\quad\underbrace{ab}\quad\underbrace{abc}\quad \underbrace{abcd}\quad \underbrace{abcde}\quad \underbrace{a+b+c}_{3} \quad \underbrace{ a+b+...+z }_{26}\] \item \cmd{overbracket} and \cmd{underbracket} \[\overbracket{a}\quad \overbracket{ab}\quad \overbracket{abc}\quad \overbracket{abcd}\quad \overbracket{abcde}\quad \overbracket{a+b+c}^{3}\quad \overbracket{ a+b+. . . +z }^{26}\] \[\underbracket{a}\quad\underbracket{ab}\quad\underbracket{abc}\quad \underbracket{abcd}\quad \underbracket{abcde}\quad \underbracket{a+b+c}_{3} \quad \underbracket{ a+b+...+z }_{26}\] \item \cmd{overrightarrow} and \cmd{overleftarrow} \[\overrightarrow{v}\quad \overrightarrow{M}\quad \overrightarrow{vv} \quad \overrightarrow{AB}\quad \overrightarrow{ABC} \quad \overrightarrow{ABCD} \quad \overrightarrow{ABCDEFGH}. \] \[\overleftarrow{v}\quad \overleftarrow{M}\quad \overleftarrow{vv} \quad \overleftarrow{AB}\quad \overleftarrow{ABC} \quad \overleftarrow{ABCD} \quad \overleftarrow{ABCDEFGH}\] \item \cmd{overrightharpoon} and \cmd{overleftharpoon} \[\overrightharpoon{v}\quad \overrightharpoon{M}\quad \overrightharpoon{vv} \quad \overrightharpoon{AB}\quad \overrightharpoon{ABC} \quad \overrightharpoon{ABCD} \quad \overrightharpoon{ABCDEFGH}. \] \[\overleftharpoon{v}\quad \overleftharpoon{M}\quad \overleftharpoon{vv} \quad \overleftharpoon{AB}\quad \overleftharpoon{ABC} \quad \overleftharpoon{ABCD} \quad \overleftharpoon{ABCDEFGH}\] \item \cmd{underrightarrow} and \cmd{underleftarrow} \[\underrightarrow{v}\quad \underrightarrow{M}\quad \underrightarrow{vv} \quad \underrightarrow{AB}\quad \underrightarrow{ABC} \quad \underrightarrow{ABCD} \quad \underrightarrow{ABCDEFGH}. \] \[\underleftarrow{v}\quad \underleftarrow{M}\quad \underleftarrow{vv} \quad \underleftarrow{AB}\quad \underleftarrow{ABC} \quad \underleftarrow{ABCD} \quad \underleftarrow{ABCDEFGH}\] \item \cmd{underrightharpoon} and \cmd{underleftharpoondown} \[\underrightharpoondown{v}\quad \underrightharpoondown{M}\quad \underrightharpoondown{vv}\quad \underrightharpoondown{AB}\quad \underrightharpoondown{ABC}\quad \underrightharpoondown{ABCD}\quad \underrightharpoondown{ABCDEFGH}. \] \[\underleftharpoondown{v}\quad \underleftharpoondown{M}\quad \underleftharpoondown{vv}\quad \underleftharpoondown{AB}\quad \underleftharpoondown{ABC}\quad \underleftharpoondown{ABCD} \quad \underleftharpoondown{ABCDEFGH}. \] \end{itemize} All the extensible arrows provided by the \pkg{mathtools} package are available in the \LAotf{} font (loading \pkg{lete-sans-math.sty} is required), f.i.: \[X \xLeftrightarrow{\text{above}} Y \xhookrightarrow[\text{under}]{} Z\xmapsto{\text{above}} W\] A wide range of extensible vertical delimiters is provided: \[ \left/ \begin{pmatrix} a_{1} \\ a_{2} \\ a_{3} \end{pmatrix} \begin{bmatrix} a_{1} \\ a_{2} \\ a_{3} \end{bmatrix} \begin{Bmatrix} a_{1} \\ a_{2} \\ a_{3} \end{Bmatrix} \begin{vmatrix} a_{1} \\ a_{2} \\ a_{3} \end{vmatrix} \begin{Vmatrix} a_{1} \\ a_{2} \\ a_{3} \end{Vmatrix} \left\lVvert\begin{array}{c} a_{1} \\ a_{2} \\ a_{3} \end{array}\right\Vvert \left\lceil \begin{array}{c} a_{1} \\ a_{2} \\ a_{3} \end{array}\right\rceil \left\lfloor\begin{array}{c} a_{1} \\ a_{2} \\ a_{3} \end{array}\right\rfloor \left\lBrack\begin{array}{c} a_{1} \\ a_{2} \\ a_{3} \end{array}\right\rBrack \left\langle\begin{array}{c} a_{1} \\ a_{2} \\ a_{3} \end{array}\right\rangle \left\lAngle\begin{array}{c} a_{1} \\ a_{2} \\ a_{3} \end{array}\right\rAngle \right\backslash \] \subsection{Mathematical alphabets} \label{ssec-math-alphabets} \begin{itemize} \item All Latin and Greek characters are available in italic, upright, bold and bold italic via the \verb+\symit{}+, \verb+\symup{}+, \verb+\symbf{}+ and \verb+\symbfit{}+ commands. \item Calligraphic alphabet (\cmd{symscr} or \cmd{symcal} or \cmd{mathcal} command), uppercase: $\symscr{ABCDEFGHIJKLMNOPQRSTUVWXYZ}$ also in boldface (\cmd{symbfscr},\cmd{symbfcal} or \cmd{mathbfcal} command): $\symbfscr{ABCDEFGHIJKLMNOPQRSTUVWXYZ}$ \item Blackboard-bold alphabet (\cmd{symbb} or \cmd{mathbb} command): $\symbb{ABCDEFGHIJKLMNOPQRSTUVWXYZ}$\\ $\symbb{abcdefghijklmnopqrstuvwxyz\quad 0123456789}$ \item Fraktur alphabet is borrowed from Latin Modern, medium and bold (\cmd{symfrak}, or \cmd{symbffrak} commands): $\symfrak{ABCDEFGHIJKLMNOPQRSTUVWXYZ\; abcdefghijklmnopqrstuvwxyz}$\\ $\symbffrak{ABCDEFGHIJKLMNOPQRSTUVWXYZ}$\\ \hphantom{$\symfrak{ABCDEFGHIJKLMNOPQRSTUVWXYZ\;}$}% $\symbffrak{abcdefghijklmnopqrstuvwxyz}$ but this can overwritten, i.e. \verb+\setmathfont{Asana-Math.otf}[range=frak,Scale=MatchUppercase]+\\ \verb+$\symfrak{ABCDEFGHIJKL...XYZ abcdefghijkl...xyz}$+ %\verb+\setmathfont{Asana-Math.otf}[range=frak,Scale=MatchUppercase]+\\ %\verb+$\symfrak{ABCDEFGHIJKLMNOPQRSTUVWXYZ abcdefghijklmnopqrstuvwxyz}$+ \item Typewriter alphabet is sans-serif: $\symtt{0123456789}$ $\symtt{ABCDEFGHIJKLMNOPQRSTUVWXYZ abcdefghijklmnopqrstuvwxyz}$ but it can be borrowed from another maths font. %\verb+\setmathfont{STIXTwoMath-Regular.otf}[range=tt,+\\ %\verb+ Scale=MatchUppercase]+\\ %\verb+$\symtt{ABCDE...XYZ abcde...xyz}$+ %\verb+\setmathfont{STIXTwoMath-Regular.otf}[range=tt,Scale=MatchUppercase]+\\ %\verb+$\symtt{ABCDEFGHIJKLMNOPQRSTUVWXYZ abcdefghijklmnopqrstuvwxyz}$+ \end{itemize} Like Latin Modern, \pkg{lete-sans-math} provides only four lowercase Latin letters in script (or calligraphic) shape: $\mscre$, $\mscrg$, $\ell$, $\mscro$ (\verb+\mscre+, \verb+\mscrg+, \verb+\ell+, \verb+\mscro+). All others (range \verb+"1D4B6+ to \verb+"1D4CF+) have to be borrowed from another maths font if needed, i.e. \verb+\setmathfont{LibertinusMath-Regular.otf}%+\\ \verb+ [range="1D4B6-"1D4CF, Scale=MatchLowercase]+ \subsection{Bold variant} \setmathfont{LeteSansMath.otf}[BoldFont=LeteSansMath-Bold.otf] In case short maths formulas have to be printed in section titles, a \emph{limited} bold variant is provided. Example of usage:\quad \textbf{\boldmath Einstein’s equation $E=mc^2$} \verb+\setmathfont{LeteSansMath-Bold.otf}[version=bold, +\textit{options}\verb+]+\\ \verb+\section{\mathversion{bold} Einstein’s equation $E=mc^2$}+ It is also possible to use the \verb+\boldmath+ command% \footnote{The \cmd{boldmath} command works out of the box when \pkg{lete-sans-math.sty} is loaded.}: \verb+\setmathfont{LeteSansMath.otf}[BoldFont=LeteSansMath-Bold.otf]+\\ \verb+\section{\boldmath Einstein’s equation $E=mc^2$}+ \subsection{Missing symbols} \LAotf{} is fairly complete (see file \file{unimath-lete.pdf}), if you happen to need some of the few missing glyphs you can borrow them from a more complete font, say \file{New Computer Modern}. For instance if you need Italic Blackboard Bold (U+2145 to U+2149) you could try: \verb+\setmathfont{NewCMMath-Book.otf}[range={"2145-"2149},Scale=1.05]+ Let’s mention \pkg{albatross}, a useful tool to find out the list of fonts providing a given glyph: f.i. type in a terminal ``\texttt{albatross U+2145}'', see the manpage or \file{albatross-manual.pdf}. \section{Acknowledgements} Many thanks to \href{https:www.typoland.com}{Łukasz Dziedzic} for providing the Lato text fonts in OpenType format. We are grateful to George Williams and his co-workers for providing and maintaining FontForge and to Ulrik Vieth for his illuminating paper published in TUGboat~2009 Volume~30 about OpenType Maths. \bigskip \begin{center}\Huge \decotwo \end{center} \end{document} %%% Local Variables: %%% mode: latex %%% TeX-engine: luatex %%% TeX-master: t %%% coding: utf-8 %%% End: