replace_atrefi*_with_mtrefi

ec6708e1 · Michael Kohlhase · 973ada16 · ec6708e1 · ec6708e1 · ec6708e1
Commit ec6708e1 authored 5 years ago by Michael Kohlhase
--- a/source/Charge.en.tex
+++ b/source/Charge.en.tex
@@ -3,8 +3,8 @@
    The \defii{total}{charge} denoted by $\TotalCharge$ describes the net charge entering
    the right hand side of the Poisson equation. It is composed by the
    \trefii[DopingProfile]{doping}{profile} and the
-    \atrefii[DensityElectrons]{electron}{electron}{density} and
-    \atrefii[DensityHoles]{hole densities}{hole}{density} by
+    \mtrefi[DensityElectrons?electron-density]{electron} and
+    \mtrefi[DensityHoles?hole-density]{hole densities} by
    $\TotalCharge
    =\realtimes{-\ElementaryCharge,\realminus{\realplus{\DopingProfile,\DensityHoles},\DensityElectrons}}$.
  \end{definition}   

--- a/source/OneDimDevice.en.tex
+++ b/source/OneDimDevice.en.tex
 \begin{mhmodnl}{OneDimDevice}{en}
  \begin{definition}
    A \trefi[Device]{device} is called \defi{one-dimensional}, iff all of its
-    \atrefii[Device]{properties}{device}{property} \trefi[DeviceGeometry]{domain} are
+    \mtrefi[Device?device-property]{properties} \trefi[DeviceGeometry]{domain} are
    translation-invariant in two directions
  \end{definition}
 \end{mhmodnl}

--- a/source/TwoDimDevice.en.tex
+++ b/source/TwoDimDevice.en.tex
 \begin{mhmodnl}{TwoDimDevice}{en}
  \begin{definition}
    A \trefi[Device]{device} is called \defi{two-dimensional}, iff all of its
-    \atrefii[Device]{properties}{device}{property} \trefi[DeviceGeometry]{domain} are
+    \mtrefi[Device?device-property]{properties} \trefi[DeviceGeometry]{domain} are
    translation-invariant in one direction.
  \end{definition}
 \end{mhmodnl}

--- a/supplement/WIAS-preprint_2263_snippet/hbchapter.tex
+++ b/supplement/WIAS-preprint_2263_snippet/hbchapter.tex
@@ -152,8 +152,7 @@ constants.  The (absolute) \trefii[PoissonParameters]{dielectric}{permittivity}
 $\DielectricPermitivity =
 \realtimes{\VacuumDielectricPermitivity,\RelativeDielectricPermitivity}$ is given as the
 product of the \trefiii[PoissonParameters]{vacuum}{dielectric}{permittivity}
-$\VacuumDielectricPermitivity$ and the \atrefiii[PoissonParameters]{relative
-  permittivity}{relative}{dielectric}{permittivity} of the semiconductor
+$\VacuumDielectricPermitivity$ and the \mtrefi[PoissonParameters?relative-dielectric-permittivity]{relative permittivity} of the semiconductor
 $\RelativeDielectricPermitivity$ in static (low frequency) limit.  The carrier mobilities
 $\ElectronMobility$ and $\HoleMobility$, the conduction and valence band densities of
 states $\DOSConductionBand$ and $\DOSValenceBand$ as well as the conduction and valence band-edge energies $E_c$ and