190311-12 : Satellite arcing experiment

11-12 mar 2019

links
Acquiring the data
observation sequence
processing the data
plotting the data
summary
exporting the files

intro

s3043 was looking for arcing signals from satellite solar panels (more info)

Data was taken on:

11-12mar19 22:30 to 02:45 AST. tracked astra1 the entire time.

dome 327 receiver -> mock spectrometer
10 min on,offs were done
Toward the end, two ons were done before each off.

Acquiring the data:

Only 1 set of data was acquired (there was no separate beam to detect rfi).

satellite

this used the gregorian dome. The 327 receiver was used.
The satellite on position was tracked for 10 minutes.
The off position was 4 beams away in za (1 deg) from the satellite.
The receiver, backend setup:

327 receiver: 53.3333 Mhz bandwidth (160Mhz/3.) 128 frequency channels, sum polA, polB. Centered at 327 Mhz.

the data was piped to the mock spectrometer where the spectral density function was computed and integrated for 9.6 micro seconds

the spectra were output to fits files:
A continuous (in time) data set (called a scan) consisted of multiple fits files (each about 2.2 gbytes).

Two command file were used to control the experiment:

Setup.cmd

loads the mock configuration
setups the 10 minute tracking parameters
adjust the power

astra1d_190312.cmd

load ephemeris file
10 min on
10 min off
... repeat
.. note toward the end we had 2 on's between the offs

12mar19(UTC): Observation sequence

Observation sequence:

start time hh:mm:ss utc	on/off	object	mock filedate	mock fnum
02:33:38	on	astra1d	20190311	0000-0008
02:44:23	off			0100-0108
02:55:08	on			0200-0208
03:05:53	off			0300-0308
03:16:38	on			0400-0408
03:27:23	off			0500-0508
03:38:08	on			0600-0608
03:48:53	off			0700-0708
03:59:38	on			0800-0808
04:10:23	off		20190312	0000-0008
04:21:08	on			0100-0108
04:31:53	off			0200-0208
04:42:38	on			0300-0308
04:52:56	on			0400-0408
05:03:41	off			0500-0508
05:14:25	on			0600-0608
05:24:43	on			0700-0708
05:35:27	off			0800-0808
05:46:12	on			0900-0908
05:56:30	on			1000-1008
06:07:15	off			1100-1108
06:18:00	on			1200-1208
06:28:18	on			1300-1380
06:39:03	off			1400-1404

Processing the data:

From the radiometer equation we have that:

deltaTsys/Tsys = 1/sqrt(channelBandwidth*time)

(Since we've added polarizations, the channel bandwidth has been doubled..)

So computing the rms by channel and then normalizing to the average channel value will give sigma values that should be determined by the bandwidth and integration time.. if the signal is noise like.. Any intermittent rfi (narrow channel frequeny broadcasts) will increase the rms values in these channels..

broad band bursts from the satellite that lasts for 10's of usecs will not affect this (since they are too short in time).

PolA and polB were added together in the mock spectrometer, before outputting the spectra.

Satellite beam:

each row of data (.76 sec 327) was processed separately:

dome 327: 79435 9.6 usec spectra /rec

compute rms/mean for each channel (over the 79435 spectra in a record)
do a linear fit to the rms over the 128 freq channels (excluding the edge channels where the analog/digital filter) response fell off.

Create a freq channel mask that includes all freq channels whose value is within 3 sigma of the fit.
This mask will be used to compute the total power for each 9.6 usec spectra .. for this .76 sec of data.

for each of the 9.6 usec spectra in the row () compute the total power using the above row

output the data, and record which frequency channels were used for this row.

repeat the above for each file of the scan
and continue for each scan of the day.
There will be 1 output file of floating point total power data (sampled at 9.6 usecs) for each 2.2 gbyte file of each scan.
repeat the above for each day of data taking.

Plotting the data

Processing the data to make the plots:

The total power data was scaled to sigmas, and then peaks were searched for values greater than N sigma (N = 20 , 50 sigmas)
using the time stamps for the peaks, the width (in time) of each peak was also computed (in case adjacent values continued above N sigma).

When adjacent peaks remained above the threshold, they were combined into a single peak with a longer duration.

plotting the peaks (above 20 sigma) (.pdf) (6.6 MB)
plotting the peaks (above 50 sigma) (.pdf) (3.0 MB)

Page 1: fraction of samples above threshold (by scan)

Top all scans in order data was taken
Bottom: split on (black) and off (red) scans

Page 2: peak max value and duration vs time

colors: black+ is the on scan, red + is the off scan.
top : strength of each peak vs hour of day (AST)
bottom: duration of each peak vs hour of day

Page 3: histogram of number of peaks vs peak duration.

Top: all data (on,off) combined
middle: histograms for on,off data plotted separately.
Bottom: histogram of spike duration done separately for each scan

+ are on scans, * are off scans

Page 4: histogram of number of peaks vs duration (blowup)

same as page 3, but the plot is blownup and uses a linear scale.

Page 5: max/avg value of each spike vs spike duration

+ black are on scans, * red are off scans
The off scans have been shifted a little in duration to no overlay the ons.
Top: max value
bottom: average value

Summary:

20 sigma data

scan 19 (on) had way more peaks above threshold than any other scan. This was probably the 40 hz interference (more info).
the histogram of counts vs duration showed the on's higher than the off's up to about .11 millisecs.
Looking at the histogram by scan, 1 on scan dominates all the others (probably scan 19.).
For scans 13-19 the ons had more total peaks than the offs (including all durations)

50 sigma data

scan 19 (on) no longer sticks out as much (the peaks must have been between 20 and 50 sigma.

No clear preference for arcing from satellite.

processing: usr/s3043/20190311/dorfi.pro

Exporting files:

Each days data are stored under a separate subdirectory (the directory names are the utc dates when data was taken):

A scan is a contiguous set of data.
For each scan:

there is a data set from the gregorian dome, mock spectrometer

this is the beam that pointed at or close to the satellite
the files start with mtp_ (mock Total Power)

Each data set has:

file of total power data (4 byte floating point, little endian)

Equally spaced in time
ends with .dat

an ascii header file that has some info on the scan

Filenames:

mtp_yyyymmdd_hhmmss.dat / .hdr

The date, time is the utc start time for the data in the file

Headers:

mtp_20170406_202541.hdr
start1970 : 1491510341 start time secs 1970 timeStep : 0.000009600 time step seconds nsamples : 62500000 number of samples in file cfr : 327.0000000 center freq Mhz bandwid : 53.3333333 bandwidth Mhz before bad channels mockNmSt : a3164.20170406.b0s1g0.00100.fits fname for first mock raw file nmockFiles: 9 number of mock raw files this scan rifname : '' no ri files were taken

processing:usr/s3043/20190311/*.pro (lots of programs)
rawdata: sitting on:gpuser0: /media/DATA0/phildat/s3043
exportable data on:

/share/phildat/usrproj/s3043/20190311/

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