Gleb wrote:
I consider designing a low-cost AO system for a small telescope.
It
seems we have all necessary resources: we produce deformable mirrors
and
wavefront sensors, we also produce closed-loop AO systems with up to
59
channels, so integration wouldn't be too complicated as all
structural parts
are available.
On the other hand we have little experience with astronomy and
therefore any
advice would help.
The preliminary tech requirements:
1. To be mounted in 1.25 inch ocular socket (2" socket??). To be
used with
telescopes with diameter in the range 25cm to 1m.
2. Aberration free afocal mirror system, transparent in the visible
and
near IR and fully operational even with AO switched off. To achieve
this,
we'll use a system with a field of a couple of mm (in the primary
focus)
for a foacl ratio of 1/10. The field and F# are compromized to reduce
the
complexity of the optics, but the field will be limited anyway by
the
anisoplanatism of the AO and the F# must be small for a HR imaging
3. To have al least 19 degrees of freedom (depending on the seeing
can be
good to correct up to ~13 Zernike terms to about 10% of the
uncorrected
value). 37 degrees of freedom is also possible but I'm not sure a
small
scope really will collect enough light to correct that many terms in
real
time.
4. To operate on a natural star with magnitude of at least 4 (with
a 25cm
telescope), using 50% of light for running the AO and 50% for
registration.
5. To be easy in setting up and running. To use single +12V power
supply
and three cables connecting the system with the deformable mirror
controller and the dedicated control laptop PC.
6. The total weight of the optical correction unit mounted to the
telescope
not to exceed 1kg. Mirror controller incl power supply - also 1 kg,
add some
extra for cables and laptop.
The system is supposed to provide a diffraction-limited imaging in a
rather
bad seeing conditions. It will allow stable imaging of bright objects
such
as stars, double stars and planets. Another advantage of using such
a
system is that it will correct the aberrations of the telescope,
improving
the quality of optics, for instance making the period of mirror
cooling also
available for observations. In fact, correction of the static
aberrations
can be done on a bright star once, and then the system can be used
in
static correction mode.
The project is technically feasible (although quite expensive in its
development stage), but I still have my doubts regarding its
usefulness:
1. Small field and ability to work on only bright objects will
limit the
usability to very bright double stars and planets. Are (amateur)
astronomers
really interested in this?
2. Although we plan to have it transparent, the system will limit the
field
of view and reduce the amount of light available for observation. The
light
loss will be compensated by the resolution gain, but the effect can
be
limited or even negligible for a small telescope.
3. The system will require an additional laptop computer to run the
AO and
will add to the complexity of the telescope setup.
4. It can be quite expensive, especially in the beginning, though
if there
is a market, the price can be very acceptable.
I would appreciate any comments on the above mentioned topics.
Gleb Vdovin
OKO Tech
PO Box 581, 2600 AN Delft, The Netherlands
http://www.okotech.com
There definitely is a market for this. There are people who will spend
$30 000+ for an APO imaging setup (OTA, mount, camera, etc.) and twice
that for an RC. There are two pieces of advice I can offer:
First, keep the final cost of the system under $10 000.
Second, you should try to make it work with F8 systems because most off
the shelf Ritcheys are in this range. If it only woks with F10 or
longer then you will exclude most of your prime market.
Best of luck
Ian Anderson
www.customopticalsystems.com