1999-02-14 19:07:13 +00:00
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%
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% `coord.tex' -- describes the coordinate systems and transforms used
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% by the FG scenery management subsystem
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%
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% Written by Curtis Olson. Started July, 1997.
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%
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% $Id$
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\documentclass[12pt]{article}
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% \usepackage{times}
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% \usepackage{mathptm}
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\usepackage{anysize}
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\papersize{11in}{8.5in}
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\marginsize{1in}{1in}{1in}{1in}
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\usepackage{epsfig}
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\usepackage{setspace}
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\onehalfspacing
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\usepackage{url}
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\begin{document}
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\title{
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Flight Gear Internal Scenery Coordinate Systems and
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Representations.
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}
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\author{
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Curtis L. Olson\\
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(\texttt{curt@me.umn.edu})
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}
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\maketitle
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\section{Coordinate Systems}
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\subsection{Geocentric Coordinates}
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Geocentric coordinates are the polar coordinates centered at the
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center of the earth. Points are defined by the geocentric longitude,
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geocentric latitude, and distance from the \textit{center} of the
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earth. Note, due to the non-spherical nature of the earth, the
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geocentric latitude is not exactly the same as the traditional
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latitude you would see on a map.
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\subsection{Geodetic Coordinates}
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Geodetic coordinates are represented by longitude, latitude, and
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elevation above sea level. These are the coordinates you would read
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off a map, or see on your GPS. However, the geodetic latitude does
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not precisely correspond to the angle (in polar coordinates) from the
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center of the earth which the geocentric coordinate system reports.
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\subsection{Geocentric vs. Geodetic coordinates}
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The difference between geodetic and geocentric coordinates is subtle
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and must be understood. The problem arose because people started
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mapping the earth using latitude and longitude back when they thought
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the Earth was round (or a perfect sphere.) It's not though. It is
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more of an ellipse.
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Early map makers defined the standard \textit{geodetic} latitude as
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the angle between the local up vector and the equator. This is shown
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in figure \ref{fig:geodesy}. The point $\mathbf{B}$ marks our current
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position. The line $\mathbf{ABC}$ is tangent to the ellipse at point
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$\mathbf{B}$ and represents the local ``horizontal.'' The line
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$\mathbf{BF}$ represents the local ``up'' vector. Thus, in
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traditional map maker terms, the current latitude is the angle defined
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by $\angle \mathbf{DBF}$.
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However, as you can see from the figure, the line $\mathbf{BF}$ does
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not extend through the center of the earth. Instead, the line
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$\mathbf{BE}$ extends through the center of the earth. So in
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\textit{geocentric} coordinates, our latitude would be reported as the
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angle $\angle \mathbf{DBE}$.
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\begin{figure}[hbt]
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\centerline{
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\psfig{file=geodesy.eps}
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}
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\caption{Geocentric vs. Geodetic coordinates}
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\label{fig:geodesy}
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\end{figure}
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The LaRCsim flight model operates in geocentric coordinates
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internally, but reports the current position in both coordinate
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systems.
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\subsection{World Geodetic System 1984 (WGS 84)}
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The world is not a perfect sphere. WGS-84 defines a standard model
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for dealing with this. The LaRCsim flight model code already uses the
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WGS-84 standard in its calculations.
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For those that are interested here are a couple of URLS for more
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information:
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\noindent
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\url{http://acro.harvard.edu/SSA/BGA/wg84figs.html} \\
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\url{http://www.afmc.wpafb.af.mil/organizations/HQ-AFMC/IN/mist/dma/wgs1984.htm}
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\\
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\url{http://www.nima.mil/publications/guides/dtf/datums.html}
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To maintain simulation accuracy, the WGS-84 model should be used when
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translating geodetic coordinates (via geocentric coordinates) into the
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FG Cartesian coordinate system. The code to do this can probably be
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borrowed from the LaRCsim code. It is located in
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\texttt{ls\_geodesy.c}.
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\subsection{Cartesian Coordinates}
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Internally, all flight gear scenery is represented using a Cartesian
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coordinate system. The origin of this coordinate system is the center
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of the earth. The X axis runs along a line from the center of the
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earth out to the equator at the zero meridian. The Z axis runs along
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a line between the north and south poles with north being positive.
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The Y axis is parallel to a line running through the center of the
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earth out through the equator somewhere in the Indian Ocean. Figure
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\ref{fig:coords} shows the orientation of the X, Y, and Z axes in
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relationship to the earth.
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\begin{figure}[hbt]
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\centerline{
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\psfig{file=coord.eps}
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}
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\caption{Flight Gear Coordinate System}
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\label{fig:coords}
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\end{figure}
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\newpage
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\subsection{Converting between coordinate systems}
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Different aspects of the simulation will need to deal with positions
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represented in the various coordinate systems. Typically map data is
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presented in the geodetic coordinate system. The LaRCsim code uses
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the geocentric coordinate system. FG will use a Cartesian coordinate
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system for representing scenery internally. Potential add on items
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such as GPS's will need to know positions in the geodetic coordinate
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system, etc.
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FG will need to be able to convert positions between any of these
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coordinate systems. LaRCsim comes with code to convert back and forth
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between geodetic and geocentric coordinates. So, we only need to
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convert between geocentric and cartesian coordinates to complete the
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picture. Converting from geocentric to cartesian coordinates is done
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1999-02-15 00:49:18 +00:00
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by using the following formula:
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1999-02-14 19:07:13 +00:00
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1999-02-15 00:49:18 +00:00
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\noindent
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\[ x = cos(lon_\mathit{geocentric}) * cos(lat_\mathit{geocentric}) *
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radius_\mathit{geocentric} \]
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\[ y = sin(lon_\mathit{geocentric}) * cos(lat_\mathit{geocentric}) *
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radius_\mathit{geocentric} \]
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\[ z = sin(lat_\mathit{geocentric}) * radius_\mathit{geocentric} \]
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1999-02-14 19:07:13 +00:00
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1999-02-15 00:49:18 +00:00
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Here is the formula to convert from cartesian coordinates back into
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geocentric coordinates:
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1999-02-14 19:07:13 +00:00
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1999-02-15 00:49:18 +00:00
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\noindent
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\[ lon = atan2( y, x ) \]
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\[ lat = \frac{\pi}{2} - atan2( \sqrt{x*x + y*y}, z ) \]
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\[ radius = \sqrt{x*x + y*y + z*z} \]
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1999-02-14 19:07:13 +00:00
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\end{document}
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