Signo integral de látex muy corto.

Question

El espaciado que muestra no se debe \displaystyle(o al menos no directamente) a que tiene columnas equilibradas, por lo que tex está estirando el espacio en blanco para que tengan la misma longitud. Si usa multicols*columnas desequilibradas y \newcolumnno usa \columnbreak, obtendrá

\documentclass{article}
\usepackage[letterpaper, margin=0.05in]{geometry}
\usepackage{multicol}
\usepackage{graphicx}
\usepackage{amsmath}
\usepackage{array}
\usepackage{xcolor,colortbl}
\usepackage{bigints}
\newcommand{\dee}{\mathop{\mathrm{d}\!}}

\begin{document}
\begin{multicols*}{2}
  \section{Known Derivatives}
        \begin{enumerate}
            \item $\displaystyle \dfrac{\dee}{\dee x} k= 0$
            \item $\displaystyle \dfrac{\dee}{\dee x} x= 1$
            \item $\displaystyle \dfrac{\dee}{\dee x} x^2 = 2x$
            \item $\displaystyle \dfrac{\dee}{\dee x} x^3 = 3x^2$
            \item $\displaystyle \dfrac{\dee}{\dee x} x^n = nx^{n-1}$
            \item $\displaystyle \dfrac{\dee}{\dee x} e^x = e^x$
            \item $\displaystyle \dfrac{\dee}{\dee x} e^{kx} = ke^{kx}$
            \item $\displaystyle \dfrac{\dee}{\dee x} \ln(x) = \dfrac{\dee}{\dee x} \log_e(x) = \dfrac{1}{x}$
            \item $\displaystyle \dfrac{\dee}{\dee x} \sin x = \cos x$
            \item $\displaystyle \dfrac{\dee}{\dee x} \cos x = -\sin x$
            \item $\displaystyle \dfrac{\dee}{\dee x} \cos k x = -k \sin kx$
            \item $\displaystyle \dfrac{\dee}{\dee x} \tan x = \dfrac{\dee}{\dee x} \dfrac{\sin x}{\cos x} =\sec^2 x $
            \item $\displaystyle \dfrac{\dee}{\dee x} \tan kx = k\sec^2kx$
            \item $\displaystyle \dfrac{\dee}{\dee x} \csc x = \dfrac{\dee}{\dee x} \dfrac{1}{\sin x} = - \csc x \cot x$
            \item $\displaystyle \dfrac{\dee}{\dee x} \sec x = \dfrac{\dee}{\dee x} = \sec x \tan x$
            \item $\displaystyle \dfrac{\dee}{\dee x} \cot x = \dfrac{\cos x}{\sin x} = - \csc^2 x$
            \item $\displaystyle \dfrac{\dee}{\dee x} \arcsin x = \dfrac{1}{\sqrt{1-x^2}}$
            \item $\displaystyle \dfrac{\dee}{\dee x} \arccos x = -\dfrac{1}{\sqrt{1-x^2}}$
            \item $\displaystyle \dfrac{\dee}{\dee x} \arctan x = \dfrac{1}{1+x^2}$
        \end{enumerate}
    \newcolumn
    \section{Known Integrals}
    \begin{enumerate}
        \item $\displaystyle \int [af(x)+bg(x)] \dee x = a\int f(x)\ \dee{x}+b\int g(x)\ \dee{x}\ +\ C$
        \item $\displaystyle \int [f(x)+g(x)] \dee x = \int f(x)\ \dee{x}+\int g(x)\ \dee{x}\ +\ C$
        \item $\displaystyle \int [f(x)-g(x)] \dee x = \int f(x)\ \dee{x}-\int g(x)\ \dee{x}\ +\ C$
        \item $\displaystyle \int af(x) \dee x = a\int f(x)\ \dee{x}\ +\ C$
        \item $\displaystyle \int u(x)v'(x) \dee x = u(x)v(x)-\int u'(x)v(x)\ \dee{x}\ +\ C$
        \item $\displaystyle \int f\big(y(x)\big)y'(x) \dee x = F\big(y(x)\big)\\\hbox{ where }F(y)=\int f(y)\ \dee{y}$
        \item $\displaystyle \int a \dee x = ax\ +\ C$
        \item $\displaystyle \int x^a \dee x = \frac{x^{a+1}}{a+1}+C\hbox{ if }a\ne-1$
        \item $\displaystyle \int \dfrac{1}{x} \dee x = \ln|x|+C$
        \item $\displaystyle \int [g(x)^ag'(x)] \dee x= \frac{g(x)^{a+1}}{a+1}+C\hbox{ if }a\ne -1$
        \item $\displaystyle \int \dee x$
    \end{enumerate}
\end{multicols*}
\end{document}

Answer 1

El espaciado que muestra no se debe \displaystyle(o al menos no directamente) a que tiene columnas equilibradas, por lo que tex está estirando el espacio en blanco para que tengan la misma longitud. Si usa multicols*columnas desequilibradas y \newcolumnno usa \columnbreak, obtendrá

\documentclass{article}
\usepackage[letterpaper, margin=0.05in]{geometry}
\usepackage{multicol}
\usepackage{graphicx}
\usepackage{amsmath}
\usepackage{array}
\usepackage{xcolor,colortbl}
\usepackage{bigints}
\newcommand{\dee}{\mathop{\mathrm{d}\!}}

\begin{document}
\begin{multicols*}{2}
  \section{Known Derivatives}
        \begin{enumerate}
            \item $\displaystyle \dfrac{\dee}{\dee x} k= 0$
            \item $\displaystyle \dfrac{\dee}{\dee x} x= 1$
            \item $\displaystyle \dfrac{\dee}{\dee x} x^2 = 2x$
            \item $\displaystyle \dfrac{\dee}{\dee x} x^3 = 3x^2$
            \item $\displaystyle \dfrac{\dee}{\dee x} x^n = nx^{n-1}$
            \item $\displaystyle \dfrac{\dee}{\dee x} e^x = e^x$
            \item $\displaystyle \dfrac{\dee}{\dee x} e^{kx} = ke^{kx}$
            \item $\displaystyle \dfrac{\dee}{\dee x} \ln(x) = \dfrac{\dee}{\dee x} \log_e(x) = \dfrac{1}{x}$
            \item $\displaystyle \dfrac{\dee}{\dee x} \sin x = \cos x$
            \item $\displaystyle \dfrac{\dee}{\dee x} \cos x = -\sin x$
            \item $\displaystyle \dfrac{\dee}{\dee x} \cos k x = -k \sin kx$
            \item $\displaystyle \dfrac{\dee}{\dee x} \tan x = \dfrac{\dee}{\dee x} \dfrac{\sin x}{\cos x} =\sec^2 x $
            \item $\displaystyle \dfrac{\dee}{\dee x} \tan kx = k\sec^2kx$
            \item $\displaystyle \dfrac{\dee}{\dee x} \csc x = \dfrac{\dee}{\dee x} \dfrac{1}{\sin x} = - \csc x \cot x$
            \item $\displaystyle \dfrac{\dee}{\dee x} \sec x = \dfrac{\dee}{\dee x} = \sec x \tan x$
            \item $\displaystyle \dfrac{\dee}{\dee x} \cot x = \dfrac{\cos x}{\sin x} = - \csc^2 x$
            \item $\displaystyle \dfrac{\dee}{\dee x} \arcsin x = \dfrac{1}{\sqrt{1-x^2}}$
            \item $\displaystyle \dfrac{\dee}{\dee x} \arccos x = -\dfrac{1}{\sqrt{1-x^2}}$
            \item $\displaystyle \dfrac{\dee}{\dee x} \arctan x = \dfrac{1}{1+x^2}$
        \end{enumerate}
    \newcolumn
    \section{Known Integrals}
    \begin{enumerate}
        \item $\displaystyle \int [af(x)+bg(x)] \dee x = a\int f(x)\ \dee{x}+b\int g(x)\ \dee{x}\ +\ C$
        \item $\displaystyle \int [f(x)+g(x)] \dee x = \int f(x)\ \dee{x}+\int g(x)\ \dee{x}\ +\ C$
        \item $\displaystyle \int [f(x)-g(x)] \dee x = \int f(x)\ \dee{x}-\int g(x)\ \dee{x}\ +\ C$
        \item $\displaystyle \int af(x) \dee x = a\int f(x)\ \dee{x}\ +\ C$
        \item $\displaystyle \int u(x)v'(x) \dee x = u(x)v(x)-\int u'(x)v(x)\ \dee{x}\ +\ C$
        \item $\displaystyle \int f\big(y(x)\big)y'(x) \dee x = F\big(y(x)\big)\\\hbox{ where }F(y)=\int f(y)\ \dee{y}$
        \item $\displaystyle \int a \dee x = ax\ +\ C$
        \item $\displaystyle \int x^a \dee x = \frac{x^{a+1}}{a+1}+C\hbox{ if }a\ne-1$
        \item $\displaystyle \int \dfrac{1}{x} \dee x = \ln|x|+C$
        \item $\displaystyle \int [g(x)^ag'(x)] \dee x= \frac{g(x)^{a+1}}{a+1}+C\hbox{ if }a\ne -1$
        \item $\displaystyle \int \dee x$
    \end{enumerate}
\end{multicols*}
\end{document}

Signo integral de látex muy corto.

Respuesta1

información relacionada