Hi Dave,
The following article will show you how a "three axis stabilization wheels" works on a satellite in order to keep the antennas constantly pointed toward the earth.
Unfortunately due to the explosion many systems failed aboard of AO40 and the above wheels never were running.
Only the magnetorquing system was used on AO40 to keep the Z axis spinning and get the best compromise between the solar panels illumination and the antenna pointing to the earth.
http://www.amsat.org/amsat/sats/phase3d/wheels/index.html
73" de
i8CVS Domenico
----- Original Message ----- From: "D. Mynatt" dave@mynatt.biz To: "i8cvs" domenico.i8cvs@tin.it; "G0MRF David Bowman" g0mrf@aol.com; "AMSAT-BB" amsat-bb@amsat.org Sent: Friday, July 04, 2008 6:03 PM Subject: Re: [amsat-bb] Re: NASA's American Student Moon Orbiter...
Probably a dumb question born of ignorance, but why isn't there more than
1
antenna on a sat, so that it's always pointing towards earth? Is Ion propulsion for stabilization using solar power too far away to be
practical
stabilization system?
----- Original Message ----- From: "i8cvs" domenico.i8cvs@tin.it To: "G0MRF David Bowman" g0mrf@aol.com; "AMSAT-BB" amsat-bb@amsat.org Sent: Friday, July 04, 2008 7:42 AM Subject: [amsat-bb] Re: NASA's American Student Moon Orbiter...
----- Original Message ----- From: G0MRF@aol.com To: amsat-bb@amsat.org Sent: Friday, July 04, 2008 3:44 AM Subject: [amsat-bb] Re: NASA's American Student Moon Orbiter...
In a message dated 04/07/2008 01:16:33 GMT Standard Time, domenico.i8cvs@tin.it writes:
Hi Ed, KL7UW
If we put AO40 at a distance of 400.000 km instead of 60.000 km from the earth the increase of isotropic attenuation at 2400 MHz is about 16 dB etc etc etc.........
Hi Ed / Dom
On the other hand, if you were to reduce path loss by using 70cm as the uplink band and 2m as the downlink the numbers begin to look quite possible.
Hi David, G0MRF
Decreasing the frequency the absolute value of the isotropic attenuation decreases but the difference in path loss between 400.000 km and 60.000
km
is the same 16.5 dB at any frequency so that to compensate for the above attenuation using lower frequencies you need bigger antennas both on the satellite and at the ground station.
Also, if the satellite is orbiting the moon, then it's quite likely
that
the attitude will be such that the experimental end of the satellite is pointing at the moons surface. This probably also means that the communication antennas are not pointing at the earth, so high gain will not be possible. Maybe 3 or 4dB is the limit.
This is why it does not make sense to put a transponder orbiting around the moon just for the simple reason that it's very much more simple and cheap to put it into a HEO earth orbit.
So how about 10W of 2m on the satellite and a passband that's say 5kHz wide? Not good for SSB, but passable for CW or reasonable speed coherent BPSK
Regards
David
Only considering the 2 meters downlink suppose to put AO40 at 400.000 km with the antennas pointing at the earth with low squint angle let say less than 10 degrees. The gain of the AO40 2 meters antennas was 10 dBi and we put your 10 watt on it.
Suppose that your 2 meter antenna has a gain of 13 dBi and the overall noise figure of your receiving system is NF= 0,7 dB = 51 kelvin so that the noise floor into a CW passband of 500 Hz with the antenna looking at the moon (200 kelvin) is about -178 dBW
Suppose that the station in QSO with you has a 70 cm EIRP capability to get the full 2 meters 10 watt from the transponder only for you and we can calculate it later on.
2 meters downlink budged calculation:
Satellite power ................................... + 10 dBW Satellite antenna gain.......................... + 10 dBi
--------------
Satellite EIRP..................................... + 20 dBW (100 W
EIRP)
2 m isotr. attenuation 400.000 km.. -188 dB
--------------
power density received on a ground isotropic 2 meters antenna..................-168 dBW
2 m ground station antenna gain.........+ 13 dBi
---------------
Power density at 2 m RX input...........- 155 dBW 2 m receiver noise floor......................- 178 dBW
---------------
Received CW signal S/N.................... + 23 dB
If we increase the BW to 2500 Hz for a SSB QSO than the noise floor of the receiving system increases by log (2500/500) = 7 dB i.e. 10 it becames about -171 dB and the SSB signal will be received with a S/N ratio = 23-7 = 16 dB wich is a very strong SSB signal.
Be aware that the above figures are based on the assumption that the satellite antennas are pointig toward the earth wich is not the case
with
a moon orbiting satellite.
In addition we assume that the station in QSO with you has a 70 cm EIRP capability in order to get 10 watt from the 2m transponder only for you.
On the other side if a fixed 10 dBi 2 meters antenna is placed over the moon and it is oriented toward the earth could easily cover the inclination X libration window without any adjustement and only from the point of view of the downlink with 10 watt it can be easily used for a
transponder
on the moon.
If you make again the downlink budged calculation considering that the 2 meter transponder will develope only 2.5 watt for you then you will realize that the transponder will accomodate 3 more stations if
each
one is getting 2.5 watt as well. In this case your S/N ratio will be still +15.5 dB on CW and +8.5 dB in SSB and the same is true for the other 3 users.
73" de
i8CVS Domenico
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