Rotation range for the 2.5-m telescope
Sloan Digital Sky Survey Telescope Technical Note
19990127
Steve Kent
Contents
Introduction
This document and the attached postscript figure document an
analysis that I did to determine the optimum midpoint and required
ranges for both the rotator and azimuth for the 2.5 M telescope.
[Only the rotator is discussed here, since the azimuth wrap is
already installed]. These quantities are constrained by the
desire to conduct long drift scans on the sky without
interruption.
Details
I simulate a series of drift scans on the sky for tracks that
cover the northern survey area. These tracks cover the range in
survey latitude of -60 to +60 degrees, spaced by 10 degrees. Each
track covers -90 to +90 degrees of survey latitude. This range
extends up to the survey boundaries. For each survey latitude, tracks
are computed for a range of starting times spaced by 1 hour. The
start time is parameterized by the hour angle of the Survey Center (=
NGP) at the start of the scan. Along each track the azimuth,
elevation, and position angle of the CCD is computed at 1 minute
intervals. Also computed is the hour angle of the Survey Center at
that time and the distance from the Survey Center.
A few restrictions on tracks are made. First, tracks are not
followed below an elevation of 30 degrees. Second, if the azimuth
rotation rate or rotator rotation rate exceed a critical value, the
track is also not followed. Third, if a track is broken into multiple
segments due to the fact that a portion falls outside these allowed
limits, then the track is divided into discontinuous segments, and
limits are determined for each segment independently. I use a maximum
tracking rate of 3 times the sidereal rate (or 45 degrees per hour).
This limit is imposed to maintain astrometric accuracy, not because
of any telescope physical limitations.
For good measure, a set of tracks are computed for ``retrograde''
scanning. Such scans have been proposed for QA purposes. I have not
computed tracks for scans along other arbitrary great circles. We
will likely observe along some tracks that cut perpendicular to the
main survey pattern, but they will not be done frequently.
Conventions and orientations
The conventions are documented in SDSS Telescope Technical Note
19981113, "Plug-plate
coordinate system". For my calculations, I define position angle
to be that of the +y axis on the camera (which points towards the
leading edge of the camera). The sense of rotation is defined such
that if the telescope is pointed to the horizon and one is looking at
the back of the telescope, the position angle increases in the
counterclockwise direction. If one looks at the projection of the y
axis on the sky, then the conventional astronomical position angle
(defined such that N is 0 degrees, E is 90 degrees) of this axis also
increases. The zero point is defined such that at zero degrees, the
projection of the +y axis onto the sky points towards the zenith.
With this convention, the camera is oriented at zero degrees at the
instrument change position. [The leading edge of the camera
emerges first when the camera comes out of the doghouse].
Results
The attached figure shows the range in rotator angles that are
followed along a single continuous scan of one track. Values for
which the elevation is lower than 30 degrees are excluded; we will
likely not scan below that elevation. Each horizontal line
corresponds to one survey latitude and one particular starting time.
The vertical axis is just a label assigned to each track and had no
other significance. Since the rotator has a range of more than 360
degrees, the starting position angle has been adjusted modulo 360
degrees so that the midpoint of the position range is centered around
90 degrees. The detailed rules for determining which side of the wrap
one should put a scan were derived empirically.
It is seen that a range in rotator angle of -150 to +331 will
accommodate all proposed tracks. This corresponds to a midpoint of 91
degrees with a range of +/-- 240 degrees. The prograde scans (which
are the most common by far) are constrained to a smaller range: -140
to +270.
One could also center the wrap at other angles; in fact, centering
it at 4.5 degrees reduces the range to +/- 234 degrees. The prograde
scans use the full range of travel, however.
The rotator design is intended to provide a full range of +/- 270
degrees. If the range needs to be contrained, later, due to unforseen
problems, the 90 degree centering is to be preferred.
Figure: Position angle range
required for each of about 600 simulated tracks on the sky. The
vertical axis is an arbitrary number. Track up to about 200 are
prograde; the remainder are retrograde. The vertical lines give
limits assuming that the rotator wrap is centered at 90 degrees.
Bottom Line
Set the rotator to the instrument change position. Point the
telescope to the horizon and face the back of the telescope. Rotate
the rotator counterclockwise 90 degrees. Center the wrap there.
Date created: 1/27/99
Last modified: 1/27/99
Copyright © 1999, Steve Kent
Steve Kent
skent@fnal.gov