因此,当其中一个方程很长时,我需要对齐一组方程。此外,我只需要对它们进行一次编号并进行标记(一次)。我认为我在对齐方面取得了成功;然而,编号一直给我带来麻烦,*而且\notag没有\nonumber帮助,这就是我的意思:
\begin{align}
\begin{split}\label{eq:26}
&-\kappa_0+\kappa_0\Gamma_{in2}= \frac{1+\Gamma_{in2}}{e^{j\kappa_1z_1}+\overrightarrow{\Gamma}_{12}e^{-j\kappa_1z_1}}\Big(\kappa_1\overrightarrow{\Gamma}_{12}e^{-j\kappa_1z_1}-\kappa_1e^{j\kappa_1z_1}\Big)
\end{split}\\
\begin{split}
\Big(&-\kappa_0+\kappa_0\Gamma_{in2}\Big)\Big(e^{j\kappa_1z_1}+\overrightarrow{\Gamma}_{12}e^{-j\kappa_1z_1}\Big)=\Big(1+\Gamma_{in2}\Big)\Big(\kappa_1\overrightarrow{\Gamma}_{12}e^{-j\kappa_1z_1}-\kappa_1e^{j\kappa_1z_1}\Big)
\end{split}\\
\begin{split}
\Gamma_{in2}\Big[\kappa_0e^{j\kappa_1z_1}+\kappa_0\overrightarrow{\Gamma}_{12}e^{-j\kappa_1z_1}-\kappa_1\overrightarrow{\Gamma}_{12}e^{-j\kappa_1z_1}+\kappa_1e^{-j\kappa_1z_1}\Big]=&\overrightarrow{\Gamma}_{12}e^{-j\kappa_1z_1}(\kappa_1+\kappa_0)\\
&+(\kappa_0-\kappa_1)e^{j\kappa_1z_1}\\
\end{split}\\
\begin{split}
\vdots
\end{split}\\
\begin{split}
&\Gamma_{in2}=\frac{\overrightarrow{\Gamma}_{12}e^{-j\kappa_1z_1}+\overrightarrow{\Gamma}_{01}e^{j\kappa_1z_1}}{\overrightarrow{\Gamma}_{12}\overrightarrow{\Gamma}_{01}e^{j\kappa_1z_1}+e^{-j\kappa_1z_1}}
\end{split}
\end{align}
That's my problem (\ref{eq:26})
提前致谢。
答案1
由于您想为整个方程组分配一个方程编号,我建议您使用一个equation环境,并在其中嵌套一个aligned环境。我还建议您对四个子方程进行左对齐。四个子方程中有两个需要换行符才能适合;我建议您将换行符放在相关=符号的正前方。
就我个人而言,我发现所有这些“外观”\overrightarrow都非常沉重和令人压抑;\vec可能效果一样好。
\documentclass{article}
\usepackage{amsmath} % for 'aligned' env.
\begin{document}
\setcounter{equation}{25} % just for this example
\begin{equation}\label{eq:26}
\begin{aligned}
% eq 1
&-\kappa_0+\kappa_0\Gamma_{\!\mathrm{in2}}
= \frac{1+\Gamma_{\!\mathrm{in2}}}{e^{j\kappa_1z_1}
+\vec{\Gamma}_{\!12}e^{-j\kappa_1z_1}}
(\kappa_1\vec{\Gamma}_{\!12}e^{-j\kappa_1z_1}-\kappa_1e^{j\kappa_1z_1})\\[2ex]
% eq 2
&(-\kappa_0+\kappa_0\Gamma_{\!\mathrm{in2}})(e^{j\kappa_1z_1}
+\vec{\Gamma}_{\!12}e^{-j\kappa_1z_1})\\
&\quad =(1+\Gamma_{\!\mathrm{in2}})(\kappa_1\vec{\Gamma}_{\!12}
e^{-j\kappa_1z_1} -\kappa_1e^{j\kappa_1z_1})\\[2ex]
% eq 3
&\Gamma_{\!\mathrm{in2}}\bigl[\kappa_0e^{j\kappa_1z_1}
+\kappa_0\vec{\Gamma}_{\!12}e^{-j\kappa_1z_1}
-\kappa_1\vec{\Gamma}_{\!12}e^{-j\kappa_1z_1}
+\kappa_1e^{-j\kappa_1z_1}\bigr] \\
&\quad =\vec{\Gamma}_{\!12}e^{-j\kappa_1z_1}(\kappa_1+\kappa_0)
+(\kappa_0-\kappa_1)e^{j\kappa_1z_1}\\
&\vdots\\
% eq 4
&\Gamma_{\!\mathrm{in2}}=\frac{\vec{\Gamma}_{\!12}e^{-j\kappa_1z_1}
+\vec{\Gamma}_{\!01}e^{j\kappa_1z_1}}{%
\vec{\Gamma}_{\!12}\vec{\Gamma}_{\!01}e^{j\kappa_1z_1}+e^{-j\kappa_1z_1}}
\end{aligned}
\end{equation}
That's my problem \eqref{eq:26}.
\end{document}