LilacSat-2 Telemetry 28-08-2015

LilacSat-2 Telemetry 28-08-2015 16:26 UTC

9600bps BPSK 437.200 and 4800bps GMSK 437.225

GNURadio LilacSat-2 Frontend RTL-SDR block

lilacsat-gnuradio-rtl-sdr

A0 54 20 00 AA A1 01 0F 09 1B 00 06 19 2F 04 00 00 00 00 09 00 00 00 00 00 03 1A 02 0B B7 52 52 2C 7F FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF 35 02 00 04 5C 0A 07 05 D1 D2 D1 AE 00 55 01 CA 0E 9B 0F C6 0F 1E 01 67 20 14 01 0E 00 0E 00 0E 00 0E 00 FF FF FF FF 19 00 C9 FF E5 FF FF FF FF FF FF FF FF 77 91 03 00 00 AC B4 30 A0

A0 54 26 00 AA A1 01 0F 09 1B 00 06 37 2F 00 00 00 00 00 09 00 00 00 00 00 03 1A 02 0B BF DD 35 30 7F 37 02 0A 1A DB 09 A2 19 C0 08 00 00 00 00 11 05 C0 2D 04 00 04 4C 0F 08 04 D1 D2 D1 AE 00 55 01 D9 0E 4A 0F E9 0F DC 00 54 20 20 01 0E 00 0E 00 0E 00 0E 00 FF FF FF FF 1B 00 C9 FF E4 FF FF FF FF FF FF FF FF 77 92 03 00 00 46 4B EC F8

A2 54 21 00 BB A1 01 0F 09 1B 00 07 21 5F 00 03 00 00 00 09 00 00 00 00 00 03 1A 01 0B A8 E8 3E 27 7F 37 02 0A 1A B2 09 AA 19 C0 08 00 00 00 00 15 05 C0 0D 03 01 03 73 0A 07 05 D1 D2 D1 AE 00 55 01 7E 0E 9A 0E 35 10 9A 00 4B 20 14 01 0E 00 0E 00 0E 00 0E 00 FF FA BD F7 FF 03 01 00 3C 00 06 00 25 00 E3 18 00 01 00 00 00 00 8B 7A FC 7B

A0 54 2B 00 AA A1 01 0F 09 1B 00 07 19 2F 04 00 00 00 00 09 00 00 00 00 00 03 1A 01 0B A8 E8 3E 27 7F 37 02 0A 1A B2 09 AA 19 40 09 00 00 00 00 15 05 C0 1F 04 01 04 76 0A 07 05 D1 D2 D1 AE 00 55 01 2E 0F 87 0E 5A 10 95 00 4B 20 14 01 0E 00 0E 00 0E 00 0E 00 FF FF FF FF 19 00 C7 FF E3 FF FF FF FF FF FF FF FF 77 93 03 00 00 7F C5 FE A7

A6 54 2A 00 13 A1 37 02 0A 1A CD 09 A2 19 E2 03 00 09 37 0A B8 04 01 03 EC 06 00 00 00 00 0A 05 94 FB 90 01 00 2D 00 00 00 55 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 07 01 00 01 A9 5C 00 00 2C 00 00 00 00 A6 B0 D1 C5

A0 54 30 00 AA A1 01 0F 09 1B 00 07 37 2F 00 00 00 00 00 09 00 00 00 00 00 03 1A 02 0B C0 ED 35 24 7F 37 02 0A 1A D0 09 A2 19 40 09 00 00 00 00 0E 05 C0 18 08 02 0C 79 10 07 05 D1 D2 D1 AE 00 55 01 38 0F EB 0E 05 10 5E 00 38 20 14 01 0E 00 0E 00 0D 00 0E 00 FF FF FF FF 1B 00 C7 FF E1 FF FF FF FF FF FF FF FF 77 94 03 00 00 66 3B 89 B5

A0 54 36 00 AA A1 01 0F 09 1B 00 08 19 2F 04 00 00 00 00 09 00 00 00 00 00 03 1A 01 0B AD DC 27 3C 7F 37 02 0A 1A D0 09 A2 19 00 09 00 00 00 00 07 05 C0 0B 0F 01 17 11 0C 08 05 D1 D1 D1 AE 00 55 01 CA 0E A7 10 CE 0E 4D 00 32 20 14 01 0E 00 0E 00 0D 00 0E 00 FF FF FF FF 18 00 C5 FF E3 FF FF FF FF FF FF FF FF 77 95 03 00 00 83 63 DE B7

A0 54 3C 00 AA A1 01 0F 09 1B 00 08 3A 2F 00 00 00 00 00 09 00 00 00 00 00 03 1A 01 0B B9 F6 2C 20 7F 35 02 0A 1A BE 09 A2 19 C0 08 00 00 00 00 10 05 C0 04 1A 08 2D 40 11 08 04 D1 D2 D1 AE 00 55 01 32 11 81 10 A8 0E 84 00 38 20 14 01 0E 00 0E 00 0D 00 0E 00 FF FF FF FF 19 00 C8 FF E1 FF FF FF FF FF FF FF FF 77 96 03 00 00 9E C8 A0 66

Fox Telemetry Decoder

Fox Telemetry Decoder Software Version 1.0 is Available for Download.

I downloaded the software to see if everything is working. I did some testing an debugging on my side. Except of the audio monitor function I got everything working with the help of the available AF and IQ recordings. The software is looking great and I am ready to received and decode the FOX satellites.

FoxTelem

Version 1.0 of the FoxTelem software, the Fox Telemetry Decoder is being
released to enable setup, testing, and debugging of your Fox-1A ground
station prior to the launch of the satellite. FoxTelem is used to
demodulate, store and analyze telemetry data from AMSAT’s Fox series of
Cube Sats.

Fox-1 satellites include two telemetry formats:

  • Slow Speed, also called Data Under Voice (DUV) is 200 bps FSK data
    sent at the same time as the transponder audio. Whenever the trans-
    mitter is on, data is being sent. This happens during beacons and
    during live QSOs.
  • High Speed is 9600 bps FSK sent instead of the transponder. This is
    used for data intensive experiments such as the Virginia Tech Camera.
    This is only active when commanded from the ground. You can recognize
    High Speed because it sounds like an old school computer modem.

FoxTelem will receive and store both formats assuming you can feed it audio
that does not have the frequencies below 200 Hz filtered. For High Speed,
the audio must also extend to include the full 9600bps bandwidth of the FM
signal. For both modes this is best achieved from a Software Defined Radio
or from the 9600 bps packet port of some radios. The FoxTelem User Guide
provides more details.

Source: FoxTelem Software for Windows, Mac, & Linux

XW-2 (CAS3) launched and active

XW2-2 (CAS3) Satellites launched and active.

I was able to decode FSK signals after analyzing the recorded IQ data, real-time CW and heard some signals on the transponders.

from BJ1SG to CQ: 
   1 > EB 90 6A 5E B9 8F 57 54 54 21 2D 65 80 CF B4 5B 70 56 56 4E 
  21 > 4E 4C 4D 00 38 00 00 00 05 00 00 00 5C 00 00 00 06 00 03 0C 
  41 > 03 18 03 25 03 34 03 20 03 0C 02 FD 02 EE 02 94 02 26 01 F4 
  61 > 03 E8 03 20 03 20 03 0C 00 67 4C 00 60 95 AA AA AA AA AA AA 
  81 > AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA 
 101 > AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA 
 121 > AA AA AA AA AA AA AA AA

from BJ1SF to CQ: 
   1 > EB 90 69 62 B7 96 58 57 57 21 16 65 40 E5 AB 5D 78 58 58 4D 
  21 > 50 4C 4D 00 38 00 00 00 00 00 00 00 5C 00 00 00 01 00 03 0C 
  41 > 03 18 03 25 03 34 03 20 03 0C 02 FD 02 EE 02 94 02 26 01 F4 
  61 > 03 E8 03 20 03 20 03 0C 00 57 7B 00 49 A0 AA AA AA AA AA AA 
  81 > AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA 
 101 > AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA AA 
 121 > AA AA AA AA AA AA AA AA
BJ1SG DFH XW2 XW2 AAAA IVBI KF6I AIN4 ITDU URVU 6ICK ANIM 6UI6 I64E 4E4E 4ETT TTTT TTTT TFN4 TTTT 4CT4 6KKM 6EEH DDDD DDDD DDDD DDDD DDDD CAMSAT CAMSAT

BJ1SG DFH XW2 XW2 AAAA IUAF KF6M AIN4 4FEI URNC .... IA4D RAI6 I6IC ..UA VBTT TTTT TTTT TKN4 TTTT 4CT4 6KKM DDDD DDDD DDDD DDDD DDDD DDDD CAMSAT CAMSAT 
BJ1SG DFH XW2 XW2 AAAA ..BI KFKT AIN4 ITET URAU 6ITK NK4E RUI6 I64C 4F4B 4CTT TTTT TTTT TTN4 TTTT 4CT4 6K4M DDDD DDDD DDDD DDDD DDDD DDDD CAMSAT CAMSAT
BJ1SG DFH XW2 XW2 AAAA IRBC KBKI AINK IUE4 URN6 64CK BM6V UVIM IM4E IT4C 4ETT TTTT TTTT TMN4 TTTT KBT4 IK4M DDDD DDDD DDDD DDDD DDDD DDDD CAMSAI CAMSAT
BJ1SF DFH XW2 XW2 AAAA IUBC KBKI AINK IUEI URUM 6IMK AMIA KVIM IM4F 4E4E 4FTT TTTT TTTT TUN4 TTTT KBT4 IKIT DDDD DDDD DDDD DDDD DDDD DDDD CAMSAT CAMSAT

BJ1SE DFH XW2 XW2 AAA RTT RUR RUR RUV TMT R6I RNT RUR TTT RKM TIU FAR TTT TTT FET TTT TTI TTT TTT K4K VTT CAMSAT CAMSAT
BJ1SD DFH XW2 XW2 AAA RTT RUT RUT RUI TNV R6V RMN RUR TTT RKI TIT EUR TTT TTT EDT TET TTT TTT TTT 6VK VTT CAMSAT CAMSAT

XW-2-CAR-CW-TRSP

Update GRIFEX operations

Update: 12-08-2015

The GRIFEX operations team just wanted to give you a quick update on operations and thank you for your continued support of the mission.

First off, we’ve now had 30 successful MARINA run completions at various locations across the US and Canada. Many of these images have unfortunately been saturated, but we did downlink a few images with interesting features. We are still waiting on confirmation from JPL of a good image before we release these images, but it appears as though the most interesting ones come from mid-latitudes in the continental US (Arizona or Virginia latitudes).

In addition to MARINA data, we’ve also been downlinking telemetry to ensure the continued health of the satellite, as per usual.

On the Ann Arbor passes during which we are not downlinking, we’ve been experimenting with the magnetorquers on GRIFEX. GRIFEX has three coils of wires, each aligned with one axis of the spacecraft (X, Y, or Z). When we run current through these wires, a magnetic dipole is generated that interacts with Earth’s magnetic field to alter GRIFEX’s attitude. Thus far, we have just been “pulsing” the coils, i.e. running current through them for only 10 seconds at a time, to make sure they are functioning properly and that the magnetometers record an appropriate change in magnetic field. You can see the results of our experiments in the three graphs below:

12082015-01

12082015-02

12082015-03

You’ll note that the X and Y coils draw much less current than the Z coil does and generate a much weaker change in magnetic field – this is because the Z coil needs to be strong enough to overcome the permanent magnet on GRIFEX (which is aligned with the Z axis of the spacecraft) if necessary. Thus far, we have only experimented with running current in one direction through the magnetorquer coils, but we plan on completing “pulse” tests with current running the opposite direction before we attempt full attitude control of the spacecraft.

Another event to note is that GRIFEX stopped beaconing sometime between 7/30/2015 23:45:00 UTC and 7/31/2015 00:51:00 UTC. At the 00:51:00 UTC pass over Ann Arbor, we attempted to reset the spacecraft, but to no avail; GRIFEX was neither beaconing nor responding to any commands we sent. GRIFEX remained silent throughout 7/31/2015, but luckily a watchdog timeout reset the spacecraft and we started picking up beacons again on 8/1/2015 13:55:00 UTC. We are still unsure of what caused this anomalous behavior, but we have been downlinking telemetry from the time period during which GRIFEX was silent (beacons were still being created and saved on the spacecraft) to debug the problem and ensure it does not happen again. A big shout out to the hams that were tracking GRIFEX during this worrisome time and alerting us to the fact that it was silent! We are all very glad that the GRIFEX mission can continue now that the spacecraft is beaconing again.

Thanks again for all your support.

Valerie Chen (KG7RGV)

FUNcube QSL and Certificate

As announced at the recent AMSAT-UK Colloquium, a ‘Certificate of Achievement’ and/or an amateur radio style ‘QSL’ card are now available online.

AO-73 Certificate

AO-73_QSL_Card

Only those who have successfully received telemetry from FUNcube-1 AND uploaded it to the Warehouse are able to download these documents. The place to download them is amsatuk.me.uk, and chose the appropriate link.