Yo suelo snotez
escribir notas al margen y funciona muy bien a menos que use el comando \chapter
. Si lo usé, el editor (TeXStudio) arroja un error al señalar el final de la línea del documento y dice "secuencia de control indefinida". \end{document}
'. También muestra un mensaje de advertencia: "Es posible que las etiquetas hayan cambiado". Vuelva a ejecutar para obtener las referencias cruzadas correctas.
Eliminar \chapter{Chapter}
el código siguiente hace que funcione muy bien
\documentclass[11pt, a4paper]{book}
\usepackage{xpatch}
\usepackage[x11names]{xcolor}
\usepackage{ragged2e}
\usepackage{ifthen}
\usepackage[a4paper]{geometry}
% BEGIN_FOLD
\geometry{twoside=true, showframe=true, inner=5mm, outer=5mm, includemp=true, bindingoffset=5mm, marginparsep=3.5mm, marginparwidth=60mm}
\geometry{top=20mm, vmarginratio=3:5, includehead=true, includefoot=true, headheight=8pt, headsep=14pt, footskip=5mm}
% END_FOLD
\usepackage{mdframed}
% BEGIN_FOLD
% ===== Begin skipbelow patch =====
\makeatletter
\xpatchcmd{\endmdframed}
{\aftergroup\endmdf@trivlist\color@endgroup}
{\endmdf@trivlist\color@endgroup\@doendpe}
{}{}
\makeatother
% ===== End skipbelow patch =====
% ===== Frames templates =====
\newcommand{\frameSideNote}{Side Note Frame}
\global \mdfdefinestyle{\frameSideNote}{
% Line
linecolor=DodgerBlue1, linewidth=0.5mm,
topline=false, bottomline=false,
skipabove=\baselineskip, skipbelow=0.5\baselineskip,
innertopmargin=0\baselineskip, innerbottommargin=0.3\baselineskip, innerleftmargin=0.5mm, innerrightmargin=0.5mm,
%
% Frame
frametitlerule=false,
frametitlefont=\footnotesize \bfseries, frametitlealignment=\justifying,
frametitleaboveskip=1.76mm, frametitlebelowskip=1.76mm,
nobreak=false, needspace=3\baselineskip
}
% END_FOLD
\usepackage{marginnote}
\usepackage{snotez}
% BEGIN_FOLD
\setsidenotes{marginnote=true}
\setsidenotes{text-format=\raggedright\normalsize}
\setsidenotes{perpage=false}
% Marker Settings
\setsidenotes{note-mark-sep=\hspace{1mm}}
\newcommand{\colorSideNoteMarker}{DodgerBlue2}
\setsidenotes{note-mark-format={
\textsuperscript{\textbf{\color{\colorSideNoteMarker} #1}}}%
}
\setsidenotes{text-mark-format={
\textsuperscript{\textbf{\color{\colorSideNoteMarker} #1}}}%
}
% ===== Begin defining a instructor side notes =====
\newboolean{InstructorMode}
\setboolean{InstructorMode}{true}
\newcommand{\sidenoteInstructor}[2][]{
\ifthenelse{\boolean{InstructorMode}}{
\sidenote[#1][]{#2}
}{}
}
% Options to turn the side notes on or off
\newcommand{\setInstructorModeOn}{\setboolean{InstructorMode}{true}}
\newcommand{\setInstructorModeOff}{\setboolean{InstructorMode}{false}}
% ===== End defining a instructor side notes =====
% END_FOLD
\begin{document}
\chapter{Chapter}
\cleardoublepage
\paragraph{Page with larger right margin}
This \sidenote{note without determining \texttt{voffset}} paper proposes an improved single-diode modeling approach for PV modules suitable for a broad range of the PV technologies available today, including modules \sidenote[\baselineskip][]{note with determining \texttt{voffset}} on tandem cell structures. After establishing the model (which has an overall of seven parameters), the paper devises a methodology to estimate its parameters using Standard Test Conditions (STC) data, Nominal Operating Cell Temperature (NOCT) data, and temperature coefficients values as provided in most manufacturers' datasheets. Simulation results and their comparison \marginnote{Right margin notes work well} with a previous work show a very accurate prediction of critical points in the current-voltage characteristics curve. \sidenoteInstructor{instructor side note} The precise prediction happens for both STC and NOCT conditions and the error in predicting maximum \sidenoteInstructor{instructor side note} power point lies \sidenoteInstructor[2\baselineskip]{instructor side note} within $1\%$ limit, and the error in its corresponding voltage and current is almost always within $2\%$ limit. Further, for both maximum power point and open-circuit voltage, the statistical variance
around manufacturer measurements
%
\sidenote{\begin{mdframed}[style=\frameSideNote, frametitle=My title]
My Note
\end{mdframed}}
%
due to temperature changes is demonstrated to be low for five various module technologies.
\paragraph{Page with larger right margin}
This paper proposes an improved single-diode modeling approach for PV modules suitable for a broad range of the PV technologies available today, including modules on tandem cell structures. After establishing the model (which has an overall of seven parameters), the paper devises a methodology to estimate its parameters using Standard Test Conditions (STC) data, Nominal Operating Cell Temperature (NOCT) data, \marginnote{Right margin notes work well} and temperature coefficients values as provided in most manufacturers' datasheets. Simulation results and their comparison with a previous work show a very accurate prediction of critical points in the current-voltage characteristics curve. The precise prediction happens for both STC and NOCT conditions and the error in predicting maximum power point lies within $1\%$ limit, and the error in its corresponding voltage and current is almost always within $2\%$ limit. Further, for both maximum power point
%
\sidenote[][]{\begin{mdframed}[style=\frameSideNote, frametitle=My title]
My Note
\end{mdframed}}
%
and open-circuit voltage, the statistical variance around manufacturer measurements due to temperature changes is demonstrated to be low for five various module technologies.
\end{document}
Respuesta1
Lo resolví. Solo usa \setsidenotes{perpage=true}
, o\setsidenotes{perpage=false} \counterwithout{sidenote}{chapter}
MWE
\documentclass[11pt, a4paper]{book}
\usepackage{xpatch}
\usepackage[x11names]{xcolor}
\usepackage{ragged2e}
\usepackage{ifthen}
\usepackage[a4paper]{geometry}
% BEGIN_FOLD
\geometry{twoside=true, showframe=true, inner=5mm, outer=5mm, includemp=true, bindingoffset=5mm, marginparsep=3.5mm, marginparwidth=60mm}
\geometry{top=20mm, vmarginratio=3:5, includehead=true, includefoot=true, headheight=8pt, headsep=14pt, footskip=5mm}
% END_FOLD
\usepackage{mdframed}
% BEGIN_FOLD
% ===== Begin skipbelow patch =====
\makeatletter
\xpatchcmd{\endmdframed}
{\aftergroup\endmdf@trivlist\color@endgroup}
{\endmdf@trivlist\color@endgroup\@doendpe}
{}{}
\makeatother
% ===== End skipbelow patch =====
% ===== Frames templates =====
\newcommand{\frameSideNote}{Side Note Frame}
\global \mdfdefinestyle{\frameSideNote}{
% Line
linecolor=DodgerBlue1, linewidth=0.5mm,
topline=false, bottomline=false,
skipabove=\baselineskip, skipbelow=0.5\baselineskip,
innertopmargin=0\baselineskip, innerbottommargin=0.3\baselineskip, innerleftmargin=0.5mm, innerrightmargin=0.5mm,
%
% Frame
frametitlerule=false,
frametitlefont=\footnotesize \bfseries, frametitlealignment=\justifying,
frametitleaboveskip=1.76mm, frametitlebelowskip=1.76mm,
nobreak=false, needspace=3\baselineskip
}
% END_FOLD
\usepackage{marginnote}
\usepackage{snotez}
% BEGIN_FOLD
\setsidenotes{marginnote=true}
\setsidenotes{text-format=\raggedright\normalsize}
% ===== Solution =====
% 1. either set
\setsidenotes{perpage=true}
% 2. or set
% \setsidenotes{perpage=false} \counterwithout{sidenote}{chapter}
% Marker Settings
\setsidenotes{note-mark-sep=\hspace{1mm}}
\newcommand{\colorSideNoteMarker}{DodgerBlue2}
\setsidenotes{note-mark-format={
\textsuperscript{\textbf{\color{\colorSideNoteMarker} #1}}}%
}
\setsidenotes{text-mark-format={
\textsuperscript{\textbf{\color{\colorSideNoteMarker} #1}}}%
}
% ===== Begin defining a instructor side notes =====
\newboolean{InstructorMode}
\setboolean{InstructorMode}{true}
\newcommand{\sidenoteInstructor}[2][]{
\ifthenelse{\boolean{InstructorMode}}{
\sidenote[#1][]{#2}
}{}
}
% Options to turn the side notes on or off
\newcommand{\setInstructorModeOn}{\setboolean{InstructorMode}{true}}
\newcommand{\setInstructorModeOff}{\setboolean{InstructorMode}{false}}
% ===== End defining a instructor side notes =====
% END_FOLD
\begin{document}
\chapter{Chapter}
\paragraph{Page with larger right margin}
This \sidenote{note without determining \texttt{voffset}} paper proposes an improved single-diode modeling approach for PV modules suitable for a broad range of the PV technologies available today, including modules \sidenote[\baselineskip][]{note with determining \texttt{voffset}} on tandem cell structures. After establishing the model (which has an overall of seven parameters), the paper devises a methodology to estimate its parameters using Standard Test Conditions (STC) data, Nominal Operating Cell Temperature (NOCT) data, and temperature coefficients values as provided in most manufacturers' datasheets. Simulation results and their comparison \marginnote{Right margin notes work well} with a previous work show a very accurate prediction of critical points in the current-voltage characteristics curve. \sidenoteInstructor{instructor side note} The precise prediction happens for both STC and NOCT conditions and the error in predicting maximum \sidenoteInstructor{instructor side note} power point lies \sidenoteInstructor[2\baselineskip]{instructor side note} within $1\%$ limit, and the error in its corresponding voltage and current is almost always within $2\%$ limit. Further, for both maximum power point and open-circuit voltage, the statistical variance
around manufacturer measurements
%
\sidenote{\begin{mdframed}[style=\frameSideNote, frametitle=My title]
My Note
\end{mdframed}}
%
due to temperature changes is demonstrated to be low for five various module technologies.
\paragraph{Page with larger right margin}
This paper proposes an improved single-diode modeling approach for PV modules suitable for a broad range of the PV technologies available today, including modules on tandem cell structures. After establishing the model (which has an overall of seven parameters), the paper devises a methodology to estimate its parameters using Standard Test Conditions (STC) data, Nominal Operating Cell Temperature (NOCT) data, \marginnote{Right margin notes work well} and temperature coefficients values as provided in most manufacturers' datasheets. Simulation results and their comparison with a previous work show a very accurate prediction of critical points in the current-voltage characteristics curve. The precise prediction happens for both STC and NOCT conditions and the error in predicting maximum power point lies within $1\%$ limit, and the error in its corresponding voltage and current is almost always within $2\%$ limit. Further, for both maximum power point
%
\sidenote[][]{\begin{mdframed}[style=\frameSideNote, frametitle=My title]
My Note
\end{mdframed}}
%
and open-circuit voltage, the statistical variance around manufacturer measurements due to temperature changes is demonstrated to be low for five various module technologies.
\end{document}