\chapter{The Graphical User Interface}\label{ctsim}\index{ctsim}%
-\setheader{{\it CHAPTER \thechapter}}{}{}{}{}{{\it CHAPTER \thechapter}}%
-\setfooter{\thepage}{}{}{}{\manver}{\thepage}%
+\setheader{{\it CHAPTER \thechapter}}{}{}{\ctsimheadtitle}{}{{\it CHAPTER \thechapter}}%
+\ctsimfooter%
-\section{Overview}
-\ctsim\ is the graphical shell for the CTSim project. It utilizes
-using the \urlref{wxWindows}{http://www.wxwindows.org} library for
+\section{Overview}\index{Graphical interface}
+\ctsim\ is the graphical shell for the CTSim project. This shell uses
+the \urlref{wxWindows}{http://www.wxwindows.org} library for
cross-platform compatibility. The graphical shell is compatible
with Microsoft Windows, \urlref{GTK}{http://www.gtk.org}, and
\urlref{Motif}{http://www.openmotif.org} graphical environments.
-This graphical includes all of the functionality of the
-command-line interface \helprefn{\ctsimtext}{ctsimtext} as well as
-great image processing and visualization features.
-
-\ctsim\ can open projection files, image files, phantom files, and
-plot files.
\usage \texttt{ctsim [files to open...]}
You can invoke \ctsim\ by itself on the command line, or include
-on the command-line any number of files that you want \ctsim\ to
-automatically open.
+any number of files that you want \ctsim\ to
+automatically open. \ctsim\ can open projection files, image
+files, phantom files, and plot files.
-\section{File Types Support}
-Phantom and plot files are stored as ASCII text. In contrast,
-image and projection files are stored in binary format. \ctsim
-incorporates logic so that binary files are cross-platform
-compatible between both little and big endian architectures.
+\section{File Types}\index{File types}
\subsection{Phantom}
Besides loading phantom files from the disk, the Herman and
Shepp-Logan phantoms are built-in to \ctsim. Phantom files can be
-read and stored on the disk. However, a text editor is required to
+read and stored on the disk. Phantom files are stored in a simple
+ASCII format. A text editor is required to
create and edit these files.
\subsection{Image}
Typically, all images are real except for images that have been
processed by Fourier transforms. As you might expect,
complex-valued images are twice the size of real-valued images
-since both a real and imaginary component need to be store.
+since both a real and imaginary component need to be store. When
+complex-valued images are viewed on the screen, only the real
+component is displayed.
Images files can also store any number of text labels. \ctsim\ uses
these labels for storing history information regarding
the creation and modifications of images.
-When complex-valued images are viewed on the screen, only the real
-component is displayed.
-
\subsection{Projection}
-Projection files are created from Phantom files during the
+Projection files are created from phantom files during the
projection process. Numerous options are available for the
creation of the these files. The files are stored in a binary
format with cross-platform compatibility on little and big endian
\subsection{Plot}
Plot files are created by \ctsim\ during analysis of image files.
They can be read and stored on the disk. They are stored as ASCII
-files for easy cross-platform support.
+files for easy cross-platform support and editing.
+
+\section{Global Menu Commands}
+These global commands are present on the menus of all windows.
+
+\subsection{File - Create Phantom}\label{IDH_DLG_PHANTOM}\index{Dialog!Create phantom}
+This command brings up a dialog box showing the phantoms that are preprogrammed
+into \ctsim. After selecting one of these phantoms, the new window with that
+phantom will be generated. The preprogrammed phantoms are:
+
+\begin{twocollist}
+\twocolitem{\textbf{Herman}}{The Herman head phantom\cite{HERMAN80}}
+\twocolitem{\textbf{Shepp-Logan}}{The head phantom of Shepp \& Logan\cite{SHEPP74}}
+\twocolitem{\textbf{Unit pulse}}{A phantom that has a value of \texttt{1} for the
+center of the phantom and \texttt{0} everywhere else.}
+\end{twocollist}
+
+\subsection{File - Create Filter}\label{IDH_DLG_FILTER}\index{Dialog!Create filter}
+This command brings up a dialog box showing the pre-programmed filters
+of \ctsim. This command will create a 2-dimensional image of the selected filter.
+The center of the filter is at the center of the image.
+
+These filters can be created in their natural frequency domain or in their spatial domain.
+
+\begin{twocollist}
+\twocolitem{\textbf{Filter}}{Selects the filter to generate.}
+\twocolitem{\textbf{Domain}}{Selects either the \texttt{Frequency} or \texttt{Spatial} domains. The filters have the
+frequency domain as their natural domain.}
+\twocolitem{\textbf{X Size}}{Number of columns in the output image.}
+\twocolitem{\textbf{Y Size}}{Number of rows in the output image.}
+\twocolitem{\textbf{Hamming Parameter}}{ This parameter adjusts the smoothing of the Hamming
+filter and can range from \texttt{0} to \texttt{1}.
+At a setting of \texttt{1}, the Hamming filter is the same as the bandlimit filter.
+At a setting of \texttt{0.54}, the Hamming filter is the same as the Hanning
+window.}
+\twocolitem{\textbf{Bandwidth}}{Sets the bandwidth of the filter.}
+\twocolitem{\textbf{Axis (input) Scale}}{Sets the scale for the filter input. By default, the input to the filter is
+the distance in pixels from the center of the image. By changing this value, one can set a scale the input to the filter.
+For example, if the output image is \texttt{101} pixels and thus the center of the image is at \texttt{(50,50)}, then a pixel
+lying at point \texttt{100,50} would be 50 units from the center of the filter. By applying an \texttt{Axis scale} of
+\texttt{0.1}, then that point would be scaled to 5 units from the center of the filter.}
+\twocolitem{\textbf{Filter (output) Scale}}{Multiplies the output of the filter by this amount. By default, the filter has a maximum
+value of \texttt{1}.}
+\end{twocollist}
+
+\subsection{File - Preferences}\label{IDH_DLG_PREFERENCES}\index{Dialog!Preferences}
+This command displays a dialog box that allows users to control
+the behavior of \ctsim. These options are saved across \ctsim\ sessions.
+Under Microsoft Windows environments, they are stored in the registry.
+On UNIX and Linux environments, they are stored in the user's home
+directory with the filename of \texttt{.ctsim}.
+
+\begin{twocollist}
+\twocolitem{\textbf{Advanced options}}{By default, this is turned off in new installations.
+These advanced options are not required for normal simulations. When \texttt{Advanced
+Options} is set, \ctsim\ will display more options during scanning of phantoms and
+the reconstruction of projections.}
+
+\twocolitem{\textbf{Ask before deleting new documents}}{By default, this is turned on in
+new installations. With this option set, \ctsim\ will ask before closing
+documents that have been modified or never saved on disk. By turning off
+this option, \ctsim\ will never ask if you want to save a file -- you'll
+be responsible for saving any files that you create.}
+
+\end{twocollist}
+
+\subsection{File - Open}
+This command opens a file section dialog box. Of special consideration
+is the \texttt{File Type} combo box on the bottom of the dialog. You need
+to set the \texttt{File Type} combo box to to the type of file that you wish to open.
+
+\subsection{File - Save}
+This command saves the contents of the active window. If the window hasn't
+been named, a dialog box will open asking for the file name to use.
+
+\subsection{File - Close}
+As one would expect, this closes the active window.
+
+\subsection{File - Save As}
+Allows the saving of the contents of a window to any filename.
+
+\subsection{Help - Contents}
+This command displays the online help.
+
+\subsection{Help - About}
+This command shows the version number of \ctsim.
+
\section{Phantom Menus}
\item A list of all component phantom elements
\end{itemize}
-\subsection{Rasterize Dialog}
+\subsection{Rasterize Dialog}\label{IDH_DLG_RASTERIZE}\index{Dialog!Rasterize}
This creates an image file from a phantom. Technically, it
converts the phantom from a vector (infinite resolution) object
into a 2-dimension array of floating-point pixels. The parameters
to set are:
\begin{twocollist}
-\twocolitemruled{\textbf{Parameter}}{\textbf{Options}}
-\twocolitem{\texttt{X size}}{Number of columns in image file}
-\twocolitem{\texttt{Y size}}{Number of rows in image file}
-\twocolitem{\texttt{Samples per pixel}}{Numbers of samples taken
+\twocolitem{\textbf{X size}}{Number of columns in image file}
+\twocolitem{\textbf{Y size}}{Number of rows in image file}
+\twocolitem{\textbf{Samples per pixel}}{Numbers of samples taken
per pixel in both the x and y directions. For example, if the
\texttt{Samples per pixel} is set to \texttt{3}, then for every
-pixel in the image file 9 samples (3 x 3) are averaged.}
+pixel in the image file 9 samples \latexonly{($3\times3$)}\latexignore{(3 x 3)}
+are averaged.}
\end{twocollist}
-\subsection{Projection Dialog}
+\subsection{Projection Dialog}\label{IDH_DLG_PROJECTIONS}\index{Dialog!Projections}
This creates a projection file from a phantom. The options
available when collecting projections are:
\begin{twocollist}
-\twocolitem{\textbf{Geometry}}{
+\twocolitem{\textbf{Geometry}}{Selects the scanner geometry.
\begin{itemize}\itemsep=0pt
- \item Parallel
- \item Equiangular
- \item Equilinear
+ \item \texttt{Parallel}
+ \item \texttt{Equiangular}
+ \item \texttt{Equilinear}
\end{itemize}}
\twocolitem{\textbf{Number of detectors}}{Sets the number of
detectors in the detector array.}
samples collected for each detector}
\twocolitem{\textbf{View Ratio}}{Sets the field of view as a ratio
-of the diameter of the phantom. For normal scanning, a value of
-1.0 is fine.}
+of the diameter of the phantom. For normal scanning, use a value of
+\texttt{1.0}.}
\twocolitem{\textbf{Scan Ratio}}{Sets the length of scanning as a
-ratio of the view diameter. For normal scanning, a value of 1.0 is
-fine.}
+ratio of the view diameter. For normal scanning, use a value of \texttt{1.0}.}
-\twocolitem{\textbf{Focal length ratio}}{Sets the distance of the
-radiation source and detectors from the center of the object as a
-ratio of the radius of the object.
-
-For parallel geometries, a value of 1.0 is fine. For other
-geometries, this should be at least 2.0 to avoid artifacts.}
+\twocolitem{\textbf{Focal length ratio}}{Sets the distance between the
+radiation source and the center of the phantom as a
+ratio of the radius of the phantom. For parallel geometries, a value
+of \texttt{1.0} is optimal. For other
+geometries, this should be at least \texttt{2.0} to avoid artifacts.}
\end{twocollist}
-\subsection{Advanced Options}
+\textbf{Advanced Options}
+
\begin{twocollist}
\twocolitem{\textbf{Rotation Angle}}{Sets the rotation amount as a
-multiple of pi. For parallel geometries use a rotation angle of 1
+multiple of \latexonly{$\pi$.}\latexignore{pi.} For parallel geometries use a rotation angle of \texttt{1}
and for equilinear and equiangular geometries use a rotation angle
-of 2. Using any other rotation angle will lead to artifacts.}
+of \texttt{2}. Using any other rotation angle will lead to artifacts.}
\end{twocollist}
Properties of image files include
\begin{itemize}\itemsep=0pt
\item Whether the image is real or complex valued
- \item Numeric statistics
- \item Image file labels
+ \item Numeric statistics (minimum, maximum, mean, median, mode, and standard deviation)
+ \item History labels (text descriptions of the processing for this image)
\end{itemize}
-\subsection{File - Export}
+\subsection{File - Export}\label{IDH_DLG_EXPORT}\index{Image!Export}
This command allows for exporting image files to a standard
graphics file format. This is helpful when you want to take an
image and import it into another application. The current
\helprefn{intensity scale}{intensityscale} is used when exporting
-the file. The support file formats are:
+the file. The supported graphic formats are:
-\begin{description}\itemsep=0pt
-\item[PNG]Portable Network Graphics format. This uses 8-bits or
-256 shades of gray.
+\begin{twocollist}
+\twocolitem{\textbf{PNG}}{Portable Network Graphics format. This uses 8-bits or
+256 shades of gray.}
+\twocolitem{\textbf{PNG-16}}{This is a 16-bit version of PNG which allows for
+65536 shades of gray.}
+\twocolitem{\textbf{PGM}}{Portable Graymap format. This is a common format used on
+UNIX systems.}
+\twocolitem{\textbf{PGM}}{ASCII version of PGM.}
+\end{twocollist}
-\item[PNG-16]This is a 16-bit version of PNG which allows for
-65536 shades of gray.
-\item[PGM]Portable Graymap format. This is a common format used on
-UNIX systems.
-\item[PGM]ASCII version of PGM.
-\end{description}
+\subsection{View}\label{intensityscale}\index{Intensity scale}
+These commands are used change the intensity scale for viewing the image.
+These commands do not change the image data. When the minimum intensity is
+set, then the color pure black is assigned to that image intensity. Similarly,
+when the maximum intensity is set, the the color pure white is assigned to that
+image value.
+
+Changing the intensity scale is useful when examining different image features.
+In clinical medicine, the intensity scale is often changed to examine bone
+(high intensity) verses soft-tissue (medium intensity) features.
+
+\subsubsection{Set}\label{IDH_DLG_MINMAX}
+This command displays a dialog box that allows you to set the lower
+and upper intensities to display.
+
+\subsubsection{Auto}\label{IDH_DLG_AUTOSCALE}
+This command displays a dialog box that allows \ctsim\ to automatically
+make an intensity scale. The parameters that \ctsim\ needs to make this
+automatic scale are:
+
+\begin{twocollist}
+\twocolitem{\textbf{Center}}{This sets the center of the intensity scale. Currently,
+\ctsim\ allows you to use either the mean, mode, or median of the image
+as the center of the intensity scale.}
+
+\twocolitem{\textbf{Width}}{This sets the half-width of the intensity scale. The width
+is specified as a ratio of the standard deviation.}
+\end{twocollist}
+
+As an example, if \texttt{median} is selected as the center and
+\texttt{0.5} is selected as the width, the the minimum intensity will
+be \latexonly{$median - 0.5 \times standardDeviation$}\latexignore{\emph{median - 0.5 x standardDeviation}}
+and the maximum will be \latexonly{$median + 0.5 \times standardDeviation$.}\latexignore{\emph{
+median + 0.5 x standardDeviation}.}
-\subsection{View}\label{intensityscale}
-These options are for change the intensity scale for viewing the image.
-They do not change the image data.
-\subsubsection{Set}
-\subsubsection{Auto}
\subsubsection{Full}
-This resets the intensity scale to the full scale of the image.
+This command resets the intensity scale to the full scale of the image.
\subsection{Image}
These commands create a new image based upon the current image,
-and for some commands, also a comparison image.
+and for some commands, also upon a comparison image.
\subsubsection{Add, Subtract, Multiply, Divide}
+These are simple arithmetic operations. \ctsim\ will display a dialog
+box showing all of the currently opened image files that are the
+same size as the active image. After the selection of a compatible image,
+\ctsim\ will perform the arithmetic operation on the two images and
+make a new result image.
\subsubsection{Image Size}
+This command will generate a new image based on the current image. The new
+image can be scaled to any size. A dialog
+appears asking for the size of the new image. Bilinear interpolation
+is used when calculating the new image.
\subsubsection{3-D Conversion}
-Generates a 3-dimensional view of the current phantom.
+Generates a 3-dimensional view of the current phantom. This view can be
+rotated in three dimensions. The left and right arrow control the z-axis
+rotation, the up and down arrows control the x-axis rotation. The y-axis
+rotation is controlled by the \texttt{T} and \texttt{Y} keys. Other options
+are presented on the \texttt{View} menu and include:
+
+\begin{itemize}
+\item Surface plot versus wireframe plot.
+\item Smooth shading versus flat shading.
+\item Lighting on or off.
+\item Color scale on or off.
+\end{itemize}
-\subsection{Filter}
-These commands filter and modify the image.
+\subsection{Filter}\index{Image!Filter}
+These commands filter and modify the image
\subsubsection{Arithmetic}
+These commands operate on the image on a pixel-by-pixel basis. The commands
+support both real and complex-valued images. The available arithmetic commards are:
+
+\begin{twocollist}
+ \twocolitem{\textbf{Invert}}{Negate pixel values.}
+ \twocolitem{\textbf{Log}}{Take natural logrithm of pixel values.}
+ \twocolitem{\textbf{Exp}}{Take natural exponent of pixel values.}
+ \twocolitem{\textbf{Square}}{Take square of pixel values.}
+ \twocolitem{\textbf{Square root}}{Take square root of pixel values.}
+\end{twocollist}
+
\subsubsection{Frequency Based}
+This commands allow the Fourier and inverse Fourier transformations of
+images. By default, the transformations will automatically convert
+images between Fourier to natural orders as expected. For example, \texttt{2-D FFT}
+will transform the points into natural order after the Fourier transform.
+Similarly the inverse, \texttt{2-D IFFT}, will reorder the points from
+natural order to Fourier order before applying the inverse Fourier transformation.
+
+As you would expect, images that undergo frequency filtering will be complex-valued
+images. Normally, only the real component is shown by \ctsim. However, \ctsim\ does
+have options for converting a complex-valued image into a real-valued image via
+the \texttt{Magnitude} and \texttt{Phase} filtering commands.
+
\subsection{Analyze}
These commands are used for analyzing an image.
\subsubsection{Plotting}
+The commands plot rows and columns of images. There are also commands
+that perform FFT and IFFT transformations prior to plotting.
+
+\subsubsection{Image Comparison}\label{IDH_DLG_COMPARISON}\index{Image!Comparison}
+This command performs statistical comparisons between two images. An option
+also exists for generating a difference image from the two input images.
-\subsubsection{Image Comparison}
+There are also commands for comparison plotting of rows and columns from two images.
+This is quite helpful when comparing a phantom to a reconstruction.
+
+The three distance measures are:
+
+\begin{twocollist}
+\twocolitem{\textbf{$d$}}{The normalized root mean squared distance measure.}
+\twocolitem{\textbf{$r$}}{The normalized mean absolute distance measure.}
+\twocolitem{\textbf{$e$}}{The worst case distance measure over a \latexonly{$2\times2$}\latexignore{\emph{2 x 2}} pixel area.}
+\end{twocollist}
\section{Projection Menus}
\subsection{File - Properties}
+The displayed properties include:
-\subsection{Process - Convert Polar Dialog}\label{convertpolardialog}
-The parameters are \texttt{xsize}, \texttt{ysize}, and \texttt{interpolation}.
-The \texttt{xsize} and \texttt{ysize} parameters set the size of the
-resulting image file. The \texttt{interpolation} parameter selects the
-interpolation method. Currently, the \texttt{bilinear} option provides
-the highest quality interpolation.
+\begin{itemize}
+\item Number of detectors in the projections.
+\item Number of views.
+\item The variables used when generating the projections from the phantom.
+\end{itemize}
+
+\subsection{Process - Convert Polar Dialog}\label{IDH_DLG_POLAR}\index{Polar conversion}
+Creates an image file with the polar conversion of the projection data. The options to set are:
+
+\begin{twocollist}
+\twocolitem{\textbf{X Size}}{Number of columns in output image.}
+\twocolitem{\textbf{Y Ssize}}{Number of rows in output image.}
+\twocolitem{\textbf{Interpolation}}{Selects the interpolation method.
+Currently, the \texttt{bilinear} option provides the highest
+quality interpolation.}
+\end{twocollist}
\subsection{Process - Convert FFT Polar Dialog}
-The parameters for this option are the same as \helprefn{Convert
+The parameters for this option are the same as the \helprefn{Convert
Polar Dialog}{convertpolardialog}. For this command, though, the
projections are Fourier transformed prior to conversion to polar
image.
-\subsection{Reconstruct - Filtered Backprojection Dialog}
+\subsection{Reconstruct - Filtered Backprojection Dialog}\label{IDH_DLG_RECONSTRUCTION}\index{Dialog!Reconstruction}
This dialog sets the parameters for reconstructing an image from projections
-using the Filtered Backprojection technique.
-
+using the filtered backprojection technique. The parameters available are:
\begin{twocollist}
-\twocolitemruled{\textbf{Parameter}}{\textbf{Options}}
\twocolitem{\textbf{Filter}}{Selects which filter to apply to each
projection. To properly reconstruct an image, this filter should
-be multiplied by the absolute value of distance from zero
-frequency.
+be consist of the the absolute value of distance from zero
+frequency optionally multiplied by a smoothing filter. The optimal
+filters to use are:
\begin{itemize}\itemsep=0pt
-\item abs\_bandlimit
-\item abs\_cosine
-\item abs\_hamming
+\item \texttt{abs\_bandlimit}
+\item \texttt{abs\_cosine}
+\item \texttt{abs\_hamming}
+\item \texttt{abs\_hanning}
\end{itemize}
} \twocolitem{\textbf{Hamming parameter}}{Sets the alpha level for
-Hamming window. At setting of 0.54, this equals the Hanning
+Hamming window. This parameter adjusts the smoothing of the Hamming
+filter and can range from \texttt{0} to \texttt{1}.
+At a setting of \texttt{1}, the Hamming filter is the same as the bandlimit filter.
+At a setting of \texttt{0.54}, the Hamming filter is the same as the Hanning
window.}
+\end{twocollist}
+\begin{twocollist}
\twocolitem{\textbf{Filter Method}}{Selects the filtering method.
For large numbers of detectors, \texttt{rfftw} is optimal. For
-smaller numbers of detectors, \texttt{convolution} might be a bit
+smaller numbers of detectors, \texttt{convolution} can be
faster.
\begin{itemize}\itemsep=0pt
-\item convolution
-\item fourier
-\item fourier\_table
-\item fftw
-\item rfftw
+\item \texttt{convolution}
+\item \texttt{fourier} - Uses simple Fourier transform.
+\item \texttt{fourier-table} - Optimizes Fourier transform by precalculating trigometric functions.
+\item \texttt{fftw} - Uses complex-valued Fourier transform with the \emph{fftw} library.
+\item \texttt{rfftw} - Uses optimized real/half-complex Fourier transform.
\end{itemize}
}
-
\twocolitem{\textbf{Interpolation}}{Interpolation technique.
-\texttt{cubic} is optimal when many projections are taken and the
-data is smooth. Otherwise, \texttt{linear} gives better results.
-Linear is also much faster than cubic interpolation.
+\texttt{cubic} is optimal when the
+data is smooth. Smooth data is obtained by taking many projections and/or
+using a smoothing filter. In the absence of smooth data, \texttt{linear} gives better results and
+is also many times faster than cubic interpolation.
\begin{itemize}\itemsep=0pt
\item nearest
}
\end{twocollist}
-\subsection{Advanced Options}
+\textbf{Advanced Options}
These options are only visible if \emph{Advanced Options} has been
-selected in the \texttt{File/Preferences} dialog. These parameters
+selected in the \texttt{File - Preferences} dialog. These parameters
default to optimal settings and don't need to be adjusted except
by expert users.
\twocolitem{\textbf{Backprojection}}{Selects the backprojection
technique. A setting of \texttt{idiff} is optimal.
\begin{itemize}\itemsep=0pt
-\item trig
-\item table
-\item diff
-\item idiff
+\item \texttt{trig} - Use trigometric functions at each image point.
+\item \texttt{table} - Use precalculated trigometric tables.
+\item \texttt{diff} - Use difference method to iterate within image.
+\item \texttt{idiff} - Use integer iteration techique.
\end{itemize}
}
\twocolitem{\textbf{Filter Generation}}{Selects the filter
generation. With convolution, \texttt{direct} is the proper method
to select. With any of the frequency methods,
-\texttt{inverse-fourier}is the best method.
+\texttt{inverse-fourier} is the best method.
\begin{itemize}\itemsep=0pt
-\item direct
-\item inverse-fourier
+\item \texttt{direct}
+\item \texttt{inverse-fourier}
\end{itemize}
}
\twocolitem{\textbf{Zeropad}}{Zeropad factor when using
-frequency-based filtering. A setting of \texttt{1} is optimal.}
+frequency-based filtering. A setting of \texttt{1} is optimal whereas
+a setting of \texttt{0} disables zero padding. Settings greater than \texttt{1}
+perform larger amounts of zero padding but without any significant benefit.}
\end{twocollist}
\section{Plot Menus}
\subsection{File - Properties}
+The displayed properties include:
-\subsection{File - Save}
-Plot files can be saved. They are saved in an ASCII text format.
+\begin{itemize}\itemsep=0pt
+\item the number of curves in the plot and the number of points per curve.
+\item the EZPlot commands used to format the plot are displayed.
+\item history labels from the originating image(s) and the plot function.
+\end{itemize}
\subsection{View Menu}
-These commands set the scaling for the y-axis.
+These commands set the scaling for the y-axis. They are analogous
+to the options used for setting the intensity scale for images.
+
\subsubsection{Set}
+This command sets the upper and lower limits for the y-axis.
+
\subsubsection{Auto}
+This command automatically sets the upper and lower limits for the
+y-axis. Please refer to the \texttt{View - Auto} documentation for
+image files for the details.
+
\subsubsection{Full}
+The command resets the upper and lower limits of the y-axis to the
+minimum and maximum values of the curves.
projects / ctsim.git / blobdiff