Commit 6c3116c8 authored by snuverink_j's avatar snuverink_j
Browse files

fix tabline

parent 270288a3
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......@@ -327,30 +327,30 @@ See Table~\ref{fieldsolvercmd} for a summary of the Fieldsolver command.
\hline
\tabhead Command & Purpose \\
\hline
\tabline{FIELDSOLVER}{Specify a fieldsolver}
\tabline{FSTYPE}{Specify the type of field solver: \texttt{FFT}, \texttt{FFTPERIODIC}, \texttt{MG}, \texttt{FMG} (AMR only) and \texttt{NONE}
\index{FFT}\index{FFTPERIODIC}\index{MG}\index{AMR}\index{NONE}}
\tabline{PARFFTX}{If \texttt{TRUE}, the dimension $x$ is distributed among the processors}
\tabline{PARFFTY}{If \texttt{TRUE}, the dimension $y$ is distributed among the processors}
\tabline{PARFFTZ}{If \texttt{TRUE}, the dimension $z$ is distributed among the processors}
\tabline{MX}{Number of grid points in $x$ specifying rectangular grid}
\tabline{MY}{Number of grid points in $y$ specifying rectangular grid}
\tabline{MZ}{Number of grid points in $z$ specifying rectangular grid}
\tabline{BCFFTX}{Boundary condition in $x$ [\texttt{OPEN}]}
\tabline{BCFFTY}{Boundary condition in $y$ [\texttt{OPEN}]}
\tabline{BCFFTZ}{Boundary condition in $z$ [\texttt{OPEN,PERIODIC}]}
\tabline{GREENSF}{Defines the Greens function for the FFT Solver}
\tabline{BBOXINCR}{Enlargement of the bounding box in \%}
\tabline{GEOMETRY}{Geometry to be used as domain boundary}
\tabline{ITSOLVER}{Type of iterative solver}
\tabline{INTERPL}{Interpolation used for boundary points}
\tabline{TOL}{Tolerance for iterative solver}
\tabline{MAXITERS}{Maximum number of iterations of iterative solver}
\tabline{PRECMODE}{Behavior of the preconditioner}
\tabline{AMR\_MAXLEVEL}{Maximum adaptive mesh refinement level (single level if \texttt{AMR\_MAXLEVEL} is zero)}
\tabline{AMR\_MAXGRID}{Maximum grid size.\ It has to be smaller than \texttt{MX}, \texttt{MY}, \texttt{MZ} when
running in parallel}
\tabline{AMR\_TAGGING}{Mesh-refinement strategy}
\texttt{FIELDSOLVER} & Specify a fieldsolver \\
\texttt{FSTYPE} & Specify the type of field solver: \texttt{FFT}, \texttt{FFTPERIODIC}, \texttt{MG}, \texttt{FMG} (AMR only) and \texttt{NONE}
\index{FFT}\index{FFTPERIODIC}\index{MG}\index{AMR}\index{NONE} \\
\texttt{PARFFTX} & If \texttt{TRUE}, the dimension $x$ is distributed among the processors \\
\texttt{PARFFTY} & If \texttt{TRUE}, the dimension $y$ is distributed among the processors \\
\texttt{PARFFTZ} & If \texttt{TRUE}, the dimension $z$ is distributed among the processors \\
\texttt{MX} & Number of grid points in $x$ specifying rectangular grid \\
\texttt{MY} & Number of grid points in $y$ specifying rectangular grid \\
\texttt{MZ} & Number of grid points in $z$ specifying rectangular grid \\
\texttt{BCFFTX} & Boundary condition in $x$ [\texttt{OPEN}] \\
\texttt{BCFFTY} & Boundary condition in $y$ [\texttt{OPEN}] \\
\texttt{BCFFTZ} & Boundary condition in $z$ [\texttt{OPEN,PERIODIC}] \\
\texttt{GREENSF} & Defines the Greens function for the FFT Solver \\
\texttt{BBOXINCR} & Enlargement of the bounding box in \% \\
\texttt{GEOMETRY} & Geometry to be used as domain boundary \\
\texttt{ITSOLVER} & Type of iterative solver \\
\texttt{INTERPL} & Interpolation used for boundary points \\
\texttt{TOL} & Tolerance for iterative solver \\
\texttt{MAXITERS} & Maximum number of iterations of iterative solver \\
\texttt{PRECMODE} & Behavior of the preconditioner \\
\texttt{AMR\_MAXLEVEL} & Maximum adaptive mesh refinement level (single level if \texttt{AMR\_MAXLEVEL} is zero) \\
\texttt{AMR\_MAXGRID} & Maximum grid size.\ It has to be smaller than \texttt{MX}, \texttt{MY}, \texttt{MZ} when
running in parallel \\
\texttt{AMR\_TAGGING} & Mesh-refinement strategy \\
\hline
\end{tabular}
\end{center}
......
......@@ -20,12 +20,12 @@ At present the \texttt{GEOMETRY} command is still an \textbf{experimental featur
\hline
\tabhead Command & Purpose \\
\hline
\tabline{GEOMETRY}{Specify a geometry}
\tabline{FGEOM}{Specifies the \textsc{H5Fed} geometry file}
\tabline{LENGTH}{Specifies the length of the geometry}
\tabline{S}{Specifies the start of the geometry}
\tabline{A}{Specifies the semi-major axis of the elliptic base area}
\tabline{B}{Specifies the semi-minor axis of the elliptic base area}
\texttt{GEOMETRY} & Specify a geometry \\
\texttt{FGEOM} & Specifies the \textsc{H5Fed} geometry file \\
\texttt{LENGTH} & Specifies the length of the geometry \\
\texttt{S} & Specifies the start of the geometry \\
\texttt{A} & Specifies the semi-major axis of the elliptic base area \\
\texttt{B} & Specifies the semi-minor axis of the elliptic base area \\
\hline
\end{tabular}
\end{center}
......
......@@ -12,22 +12,19 @@
\hline
\tabhead Command & Purpose \\
\hline
\tabline{TRACK}{Enter tracking mode}
\tabline{LINE}{Label of \texttt{LINE} or \texttt{SEQUENCE}}
\tabline{BEAM}{Label of \texttt{BEAM}}
\tabline{T0}{Initial time}
\tabline{DT}{Array of time step sizes for tracking}
\tabline{MAXSTEPS}{Array of maximal number of time steps}
\tabline{ZSTART}{z-location [m], from where to run simulation}
\tabline{ZSTOP}{Array of z-location [m], after which the simulation switches to the next set of \texttt{DT}, \texttt{MAXSTEPS} and \texttt{ZSTOP}}
\tabline{STEPSPERTURN}{Number of time steps per revolution period}
\tabline{TIMEINTEGRATOR}{Defines the time integrator used in \textit{OPAL-cycl}}
\tabline{name=expression}{Parameter relation}
% \tabline{NOISE}{& Define power supply ripple}
\ifthenelse{\boolean{ShowMap}}{\tabline{START}{Define initial conditions}
\tabline{TSAVE}{Save end conditions}}{}
\tabline{RUN}{Run particles for specified number of turns or steps}
\tabline{ENDTRACK}{Leave tracking mode}
\texttt{TRACK} & Enter tracking mode \\
\texttt{LINE} & Label of \texttt{LINE} or \texttt{SEQUENCE} \\
\texttt{BEAM} & Label of \texttt{BEAM} \\
\texttt{T0} & Initial time \\
\texttt{DT} & Array of time step sizes for tracking \\
\texttt{MAXSTEPS} & Array of maximal number of time steps \\
\texttt{ZSTART} & z-location [m], from where to run simulation \\
\texttt{ZSTOP} & Array of z-location [m], after which the simulation switches to the next set of \texttt{DT}, \texttt{MAXSTEPS} and \texttt{ZSTOP} \\
\texttt{STEPSPERTURN} & Number of time steps per revolution period \\
\texttt{TIMEINTEGRATOR} & Defines the time integrator used in \textit{OPAL-cycl} \\
\texttt{name=expression} & Parameter relation \\
\texttt{RUN} & Run particles for specified number of turns or steps \\
\texttt{ENDTRACK} & Leave tracking mode \\
\hline
\end{tabular}
\end{center}
......
......@@ -109,18 +109,18 @@ label:WAKE, TYPE=string, NBIN=real, FILTERS=string-array;
\hline
\tabhead Command & Purpose \\
\hline
\tabline{WAKE}{Specify a wakefield}
\tabline{TYPE}{\sloppy Specify the wake function [\texttt{1D-CSR}, \texttt{1D-CSR-IGF}, \texttt{LONG-SHORT-RANGE}, \texttt{TRANSV-SHORT-RANGE}, \texttt{LONG-TRANSV-SHORT-RANGE}]}
\tabline{NBIN}{Number of bins used in the calculation of the line density}
\tabline{CONST\_LENGTH}{\texttt{TRUE} if the length of the bunch is considered to be constant}
\tabline{CONDUCT}{Conductivity [\texttt{AC}, \texttt{DC}]}
\tabline{Z0}{Impedance of the beam pipe in [$\Omega$]}
\tabline{FORM}{The form of the beam pipe [\texttt{ROUND}]}
\tabline{RADIUS}{The radius of the beam pipe in [m]}
\tabline{SIGMA}{Material constant dependent on the beam pipe material in [$\Omega^{-1} m$]}
\tabline{TAU}{Material constant dependent on the beam pipe material in [$s$]}
\tabline{FNAME}{Specify a file that provides a wake function}
\tabline{FILTER}{The names of the filters that should be applied}
\texttt{WAKE} & Specify a wakefield \\
\texttt{TYPE} & \sloppy Specify the wake function [\texttt{1D-CSR}, \texttt{1D-CSR-IGF}, \texttt{LONG-SHORT-RANGE}, \texttt{TRANSV-SHORT-RANGE}, \texttt{LONG-TRANSV-SHORT-RANGE}] \\
\texttt{NBIN} & Number of bins used in the calculation of the line density \\
\texttt{CONST\_LENGTH} & \texttt{TRUE} if the length of the bunch is considered to be constant \\
\texttt{CONDUCT} & Conductivity [\texttt{AC}, \texttt{DC}] \\
\texttt{Z0} & Impedance of the beam pipe in [$\Omega$] \\
\texttt{FORM} & The form of the beam pipe [\texttt{ROUND}] \\
\texttt{RADIUS} & The radius of the beam pipe in [m] \\
\texttt{SIGMA} & Material constant dependent on the beam pipe material in [$\Omega^{-1} m$] \\
\texttt{TAU} & Material constant dependent on the beam pipe material in [$s$] \\
\texttt{FNAME} & Specify a file that provides a wake function \\
\texttt{FILTER} & The names of the filters that should be applied \\
\hline
\end{tabular}
\end{center}
......
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