Infrared scanner coordinate system transformation
Sloan Digital Sky Survey Telescope Technical Note
19971102
Walter
Siegmund
Contents
Introduction
The Sloan Digital Sky Survey (SDSS) has two components, an imaging
survey and a spectrographic survey. The desired photometric accuracy
of the imaging survey can only be achieve during excellent
photometric conditions. Because of the difficulty of visually
detecting thin patches of clouds under dark conditions, an infrared
(IR) scanner was constructed in 1993 to monitor nighttime cloud cover
at Apache Point Observatory. It has been used routinely since the end
of 1995 and has proved to be valuable for monitoring sky conditions
at the observatory.
The IR scanner confers the following benefits.
- Thin clouds are readily apparent in the images.
- Animation of a series of frames allow trends to be discerned.
Observations can be planned better and telescope time can be used
more efficiently.
- Under marginal conditions, deterioration can be detected and
the telescope enclosure can be closed before precipitaion falls on
the optics.
- The scanner image archive allows an astronomer to examine the
condition of the sky at the time of an observation as an aid in
the interpretation of the data.
Transformation equations
The scanner operates by moving two mirrors that are mounted in an
altitude-altitude configuration. The left diagram (Figure 1) shows
the scanner coordinate system. The right diagram is the familiar
azimuth-altitude coordinate system. Both are right-handed systems.
Azimuth is measured positive to the east from the south, i.e., the
same convention that is used in the Apache Point Observatory
telescope control computer.
Figure 1: IR scanner and horizon
(azimuth-altitude) coordinate systems. Positive axes and angles are
labeled.
By inspection,
X = Z'
Y = -X'
Z = -Y'
Consequently,
cos(
)•cos(
) = sin(a)
cos()•sin() = -cos(a)•cos(A)
sin() = -cos(a)•sin(A)
The loci of points at 15° intervals in azimuth and altitude
are plotted in scanner coordinates (Figure 2). This is the format
that an 80°x80° image would have. The distortion is modest
except near the east and west points of the horizon. The low
distortion makes it relatively easy to interpret the resulting
images. The images could be resampled to reduce distortion but this
has not proved necessary, so far.
The loci of points at 15° intervals in scanner coordinates
are plotted on an azimuth-altitude polar plot (Figure 3). This is the
view of an observer looking up at the zenith. The line scan direction
is vertical on the page. The frame scan direction is left-right.
Figure 2: Loci of points at 15°
intervals in azimuth and altitude are plotted in scanner coordinates.
This is the format of a scanner image displayed in a rectangular
format. Distortion is modest except near the east and west points on
the horizon.
Figure 2: Loci of points at 15°
intervals in scanner coordinates are shown on a azimuth-altitude
polar plot.
Conclusions
A simple set of coordinate transformations describe the
relationship of the infrared scanner and the altitude-azimuth sky
coordinate systems.
Date created: 11/02/1997
Last modified: 02/11/1998
siegmund@astro.washington.edu