Figure 4a. The defocus in arcseconds of blur on the image
plane is shown as a function of time for the night of August 14.
Arrows mark the times at which the telescope focus was manually
changed. The labels show the magnitude of the changes made. The
squares show measurements of the defocus just prior to and after
manual focus changes. The first focus change actually decreased the
telescope image quality while the second made a significant
improvement. Below I will show clear indications of errors in the
secondary motions which are probably contributing significantly to
focus errrors in the telescope.
These measured image blurs can be converted into secondary focus
motions required to place the telescope into optimal focus. The
following graph shows these data with this conversion applied. In
addition, in the following graph I have also taken the manual focus
changes into account by subtracting the focus position as determined
from the TCC log from each measurement. All of the data are therefore
shown as if the telescope had been kept at a focus position of 0
during the entire period.
Figure 4b. In this graph the defocus blurs shown in Figure
4a have been converted to secondary focus corrections required to
optimize the telescope focus. As discussed above, all of the defocus
corrections have been adjusted to correspond to a fixed telescope
focus of 0. As in Figure 4a, the circles show the measurements taken
during the period in which no focus adjustments were made. The
squares correspond to the measurements shown as squares in Figure 4a.
The defocus shift between the circles and squares is an indication
of errors in the focus motions of the secondary. In this example,
these errors appear to be on the order of 20 µm, which
corresponds to 20,000 µ-steps in the secondary encoder readings.
It has been known for some time now that we problems this large in
the secondary actuators. Because of these errors, we do not include
the squares when fitting the defocus data.
The inset shows the results of a least squares fit to the circles.
The form of the fit is chosen to match the corresponding TCC
secondary piston coefficients. On this night, only small changes of
focus (10 µm) are seen as a function of telescope altitude. A
linear fit to these same data gives a slope of 0.175 µm/degree.