Difference between revisions of "Adjusting the SatNOGS Client"

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(SatNOGS station adjustments)
 
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 +
==Introduction==
 +
 
(This page is a port of [https://community.libre.space/t/how-to-do-some-client-adjustments/1604/1 DL4PD's excellent post] to the SatNOGS forum.)
 
(This page is a port of [https://community.libre.space/t/how-to-do-some-client-adjustments/1604/1 DL4PD's excellent post] to the SatNOGS forum.)
  
== Prerequisites / dependencies ==
+
==Prerequisites / dependencies==
  
 
This page assumes:
 
This page assumes:
  
* you've read all the [[Get Started|Getting Started]] page, as well as the pages linked under "Build" and "Operate" on the [[Main Page]]
+
*you've read all the [[Get Started|Getting Started]] page, as well as the pages linked under "Build" and "Operate" on the [[Main Page]]
* you've already made your [[Operation|first observations]] and have some waterfalls in the [[Network]]
+
*you've already made your [[Operation|first observations]] and have some waterfalls in the [[Network]]
* you've installed [http://gqrx.dk/download install gqrx] on your local computer.
+
*you've installed [http://gqrx.dk/download install gqrx] on your local computer.
  
== SatNOGS station adjustments ==
+
==Frequency Offset Calibration==
  
Now you've come to a point where you want to know how well your station is performing.  The first step is to determine your frequency offset.
+
Some cheaper SDRs may have a significant frequency offset, due to the use of poor quality reference crystal oscillators. This can result in observations which may be un-decodable. If you see observations that have signals that appear to be 'off to one side', then you should perform some of the steps below to determine your offset.
  
=== automatic adjustment via kalibrate-rtl ===
+
{{Message|Note: SDRs which use a 'standard' crystal, without temperature compensation (e.g. the cheaper RTLSDRs) will drift noticeably in frequency with temperature changes. This means any calibration values determined below will not be consistent. It is highly recommended that you purchase a SDR which utilises a temperature compensated crystal oscillator (TCXO).}}<br />
 +
 
 +
===Automatic adjustment via kalibrate-rtl===
  
 
As a more comfortable way to get the ppm of your SDR the tool ''kal'' from https://github.com/viraptor/kalibrate-rtl can be used.
 
As a more comfortable way to get the ppm of your SDR the tool ''kal'' from https://github.com/viraptor/kalibrate-rtl can be used.
At the moment you propably have to get and build it by yourself.
+
At the moment you probably have to get and build it by yourself.
 +
 
 +
'''Note: This is only going to work if GSM is still in existence in your country. If (like Australia), your country has moved on from the 1980s and deprecated GSM, you will need to use another option (scroll down).'''
 +
 
 +
When using the pre-built image for the Raspberry Pi, you have
 +
to install the following dependencies:
 +
$ sudo apt-get install libtool pkg-config libfftw3-dev librtlsdr-dev automake m4
  
see available parameters:
+
Then you can build and install it with
  root@raspberrypi:~# kal -h
+
$ ./bootstrap
 +
$ CXXFLAGS='-W -Wall -O3' ./configure
 +
$ make
 +
$ sudo make install
 +
 
 +
For usage, see available parameters:
 +
  $ kal -h
 
  kalibrate v0.4.1-rtl, Copyright (c) 2010, Joshua Lackey
 
  kalibrate v0.4.1-rtl, Copyright (c) 2010, Joshua Lackey
 
  modified for use with rtl-sdr devices, Copyright (c) 2012, Steve Markgraf
 
  modified for use with rtl-sdr devices, Copyright (c) 2012, Steve Markgraf
Line 41: Line 57:
 
  -D enable debug messages
 
  -D enable debug messages
 
  -h help
 
  -h help
root@raspberrypi:~#
+
 
  
 
choose an appropriate band for scanning:
 
choose an appropriate band for scanning:
  root@raspberrypi:~# kal -s GSM900
+
  $ kal -s GSM900
 
  Found 1 device(s):
 
  Found 1 device(s):
 
   0:  Generic RTL2832U OEM
 
   0:  Generic RTL2832U OEM
Line 63: Line 79:
 
     chan:  86 (952.2MHz - 212Hz)    power: 2314696.93
 
     chan:  86 (952.2MHz - 212Hz)    power: 2314696.93
 
     chan:  116 (958.2MHz - 180Hz)    power:  862935.90
 
     chan:  116 (958.2MHz - 180Hz)    power:  862935.90
root@raspberrypi:~#
+
 
  
 
choose a strong channel:
 
choose a strong channel:
  root@raspberrypi:~# kal -c 33
+
  $ kal -c 33
 
  Found 1 device(s):
 
  Found 1 device(s):
 
   0:  Generic RTL2832U OEM
 
   0:  Generic RTL2832U OEM
Line 81: Line 97:
 
  not found: 0
 
  not found: 0
 
  average absolute error: 0.219 ppm
 
  average absolute error: 0.219 ppm
root@raspberrypi:~#
 
 
Now enter the measured ppm in satnogs-setup and you're done.
 
 
=== manual adjustment ===
 
 
To start, please connect to your Raspberry Pi's local web interface. By default the URL is something like "http://192.168.0.5:5000"; you'll need to figure out what it is for your client. In the upper right corner there is a big green button where you can set your ground station in standalone mode.
 
 
Here's how it looks in network mode:
 
  
<p>[[File:SatNOGS_local_network_mode.png|center|600px]]</p>
 
  
And here's how it looks when it's switched to standalone mode:
+
Now enter the measured ppm in satnogs-setup and you're done. The value should be entered without decimals, for example -1.
  
<p>[[File:SatNOGS_local_standalone_mode.png|center|600px]]</p>
+
===Automatic Adjustment using LTE Signals===
 +
If you are living in a country where GSM is no longer present, but LTE is available (in a frequency range supported by your receiver), then you can determine your SDR's PPM offset by following this guide: https://gist.github.com/darksidelemm/b517e6a9b821c50c170f1b9b7d65b824
  
{{Message|
+
===Manual Adjustment using GQRX===
* Do not forget to set this back to network mode when done with your adjustments!
+
If you cannot calibrate against GSM or LTE towers, but you have a nearby amateur radio beacon or transmitter at a reasonably well-known frequency, you can use this to obtain at least a coarse PPM correction.
* While your station is in standalone mode, no observations from the SatNOGS network will be executed!}}
 
  
After setting to standalone mode, please SSH to your SatNOGS Pi with your well-known user account; by default, this is the user "pi". After successful authorization you will see a prompt like this:
+
'''NOTE: This section needs to be updated to follow the same process as is used in `Setting The Gain`, as rtl_tcp may not be available on the latest SatNOGS RPI images, and will not work if any other SDR type is in use.'''
  
<pre>
+
SSH to your SatNOGS Pi with your well-known user account; by default, this is the user "pi".  After successful authorization you will see a prompt like this:<pre>
 
  Linux satnogs190-dev 4.9.59-v7+ #1047 SMP Sun Oct 29 12:19:23 GMT 2017 armv7l
 
  Linux satnogs190-dev 4.9.59-v7+ #1047 SMP Sun Oct 29 12:19:23 GMT 2017 armv7l
  
Line 116: Line 122:
 
</pre>
 
</pre>
  
 +
You will now need to temporarily stop the satnogs-client, using the command:
 +
$ sudo systemctl stop satnogs-client
 
Now go ahead and start the "RTL SDR spectrum server":
 
Now go ahead and start the "RTL SDR spectrum server":
  
Line 197: Line 205:
 
<p>[[File:Gqrx_running.png|center|600px]]</p>
 
<p>[[File:Gqrx_running.png|center|600px]]</p>
  
Go for a known local HAM radio repeater or a CW beacon transmitter and set your demodulator accordingly. Narrow Band FM or CW is best to discover ppm error offset, which is the frequency offset in parts per million (ppm) which is always there with standard RTL-SDR dongles. It is also highly temperature dependent, so one might have to re-evaluate this from time to time. Enter the known frequency of your chosen transmitter (NFM repaeter or CW beacon). I have chosen a very known CW beacon just some km away from my home: ON4VHF on 144.718000 MHz. Walk through the tab called "Receiver options" and change the settings to fit the beacon: "Filter width Normal", "Filter shape Normal", "Mode CW-L", "AGC Medium". Set Squelch to something low, so you can hear noise from your speakers. Maybe you have to Adjust the audio "Gain" to something like "0.0 dB". You can adjust this to fit your needs to hear noise. With ppm error, which is default, set to 0.0 ppm, one can just guess where your receiver is listening. Anyway, just set it to 144.718000 MHz and try to find your beacon. You can see the result for my RTL SDR dongle down here:
+
Go for a known local HAM radio repeater or a CW beacon transmitter and set your demodulator accordingly. Narrow Band FM or CW is best to discover ppm error offset, which is the frequency offset in parts per million (ppm) which is always there with standard RTL-SDR dongles. For SDRs without a Temperature Compensated Crystal Oscillator ('TCXO') this value may be temperature dependent. Enter the known frequency of your chosen transmitter (NFM repeater or CW beacon). I have chosen a very known CW beacon just some km away from my home: ON4VHF on 144.718000 MHz. Walk through the tab called "Receiver options" and change the settings to fit the beacon: "Filter width Normal", "Filter shape Normal", "Mode CW-L", "AGC Medium". Set Squelch to something low, so you can hear noise from your speakers. Maybe you have to Adjust the audio "Gain" to something like "0.0 dB". You can adjust this to fit your needs to hear noise. With ppm error, which is default, set to 0.0 ppm, one can just guess where your receiver is listening. Anyway, just set it to 144.718000 MHz and try to find your beacon. You can see the result for my RTL SDR dongle down here:
  
 
<p>[[File:Gqrx_ppm-error_offset.png|center|600px]]</p>
 
<p>[[File:Gqrx_ppm-error_offset.png|center|600px]]</p>
Line 219: Line 227:
 
{{Message|With gqrx, you get a nice tool to do some SDR stuff by the way. Just play around a bit and get familiar with all that stuff. Just keep in mind that, as long as you run the RTL SDR Spectrum server or you have set your client into standalone mode, nothing is done from network.}}
 
{{Message|With gqrx, you get a nice tool to do some SDR stuff by the way. Just play around a bit and get familiar with all that stuff. Just keep in mind that, as long as you run the RTL SDR Spectrum server or you have set your client into standalone mode, nothing is done from network.}}
  
== Enhancements ==
+
===adjustment using observations===
 
+
Another way of adjusting the frequency offset is by making an observation of a satellite that transmits CW. Once the observation is complete, the CW signal from the satellite should look like a straight line at 0Hz on the observation waterfall. If there's a frequency offset, the signal will be off-center. The image below shows observation details for a CW transmitter on VHF. Since the frequency offset is not yet adjusted, the CW signal is present between the -10kHz and 0Hz markers.
=== Waterfall color improvements ===
+
{{Message|It is possible for the CW signal to appear at a frequency above the 10kHz tick or below the -10kHz tick. In that case, use the frequency of the first tick with a higher absolute value frequency than the CW signal absolute value frequency. Do not forget to update the selected tick frequency in the equations below!}}<br />
 
+
[[File:Marked CW observation.jpg|center|800x800px]]
To get some nicer waterfalls one has to dig into waterfall plotting script. This is a static one and, so far, cannot be configured through satnogs-setup. Anyway: there is no magic behind it and one can understand what the changes are once you have seen them.
+
In order to compute the frequency offset, the waterfall image can be downloaded and opened with graphics editor like GIMP. After opening the waterfall image, vertical markers are placed on the -10kHz tick, the 0Hz tick and on the CW signal. Once the markers are placed, measure the width in pixels between the -10kHz tick and 0Hz tick, as well as the width between the CW signal and the 0Hz tick. The image below shows an example of the placed markers and the widths to be measured:
 
+
<br />
Log into the Pi and start at making a copy of /usr/share/satnogs/scripts/satnogs_waterfall.gp, just in case:
+
[[File:Measurement markers.jpg|center|550x550px]]
 
+
Let’s call the width between the -10kHz and 0Hz markers '''''widthTickTo0''''', and the width between the CW and 0Hz markers '''''widthCWto0'''''. From the example image above, we get the values '''''widthTickTo0 = 224''''' and '''''widthCWto0 = 131'''''. To compute the frequency offset, we compute the ratio between those widths and multiply by the frequency tick value as follows:
$ cp /usr/share/satnogs/scripts/satnogs_waterfall.gp ~/.
+
'''frequencyOffset = -10,000Hz * widthCWto0 / ''widthTickTo0'''''
 
+
In the case of the example above:
Now you can start editing the script:
+
'''frequencyOffset = -10,000Hz * widthCWto0 / ''widthTickTo0'' = -10,000Hz * 131 / 224 = -5,848Hz'''
 
+
To compute the offset in PPM, divide the frequency offset in Hz by the transmitter frequency in MHz. In the case of the example above:
$ sudo nano /usr/share/satnogs/scripts/satnogs_waterfall.gp
+
'''ppmOffset = frequencyOffset / transmitterFrequency = -5,848Hz / 145.725MHz = -40 PPM'''
 
+
The correction entered in satnogs-setup must have the opposite sign of that in the calculation, since we will be shifting the frequency in the opposite direction, making the SATNOGS_PPM_ERROR value:
Search for a line starting with cbtics:
+
  '''SATNOGS_PPM_ERROR = 40'''
 
+
Note that if the CW signal is on the left side of the 0Hz marker, the PPM value is positive, otherwise, the PPM value is negative.
# Spectravue palette and scale
+
{{Message|Please keep in mind that it is possible for the CW transmitter to drift in some satellites. This makes the CW transmission an unreliable source in some cases. Make sure to double-check your adjustment with another CW satellite!}}
set cbtics (-110, -105, -100, -95, -90, -85, -80, -75, -70, -65, -60, -55, -50, -55, -40)
 
 
 
Comment it out by adding a #, copy, paste and edit that new line that it matches something like this:
 
 
 
# Spectravue palette and scale
 
#set cbtics (-110, -105, -100, -95, -90, -85, -80, -75, -70, -65, -60, -55, -50, -55, -40)
 
  set cbtics (-90, -85, -80, -75, -70, -65, -60, -55, -50, -55, -45, -40, -35, -40, -25)
 
  
Now go ahead and find a line with cbrange:
+
==Enhancements==
  
set ylabel 'Time (seconds)'
+
===Waterfall Color improvements===
set cbrange [-100:-50]
 
  
I guess, one already gets the point - change cbrange to match the new cbtics:
+
By default the SatNOGS client will adjust the waterfall colour ranges to best display the received signal.
  
set ylabel 'Time (seconds)'
+
If desired, this auto-ranging can be disabled by running <code>sudo satnogs-setup</code>, and navigating to <code>Advanced -> Waterfall</code>. From here the auto-ranging can be turned off, and the minimum and maximum waterfall colour-scale levels can be set.
#set cbrange [-100:-50]
 
set cbrange [-85:-35]
 
  
Save the file and you are done. Schedule some observations and watch the new colors. Maybe you can just improve it a little more but keep in mind: always keep a bit of the noise floor into the waterfalls, so you can see the whole signals dynamic range. I love it, when there are only a few dots of the noise.
+
[[Category:Software]]
 +
[[Category:Operate]]

Latest revision as of 10:25, 7 November 2020

Introduction

(This page is a port of DL4PD's excellent post to the SatNOGS forum.)

Prerequisites / dependencies

This page assumes:

Frequency Offset Calibration

Some cheaper SDRs may have a significant frequency offset, due to the use of poor quality reference crystal oscillators. This can result in observations which may be un-decodable. If you see observations that have signals that appear to be 'off to one side', then you should perform some of the steps below to determine your offset.

Idea.png
Note: SDRs which use a 'standard' crystal, without temperature compensation (e.g. the cheaper RTLSDRs) will drift noticeably in frequency with temperature changes. This means any calibration values determined below will not be consistent. It is highly recommended that you purchase a SDR which utilises a temperature compensated crystal oscillator (TCXO).


Automatic adjustment via kalibrate-rtl

As a more comfortable way to get the ppm of your SDR the tool kal from https://github.com/viraptor/kalibrate-rtl can be used. At the moment you probably have to get and build it by yourself.

Note: This is only going to work if GSM is still in existence in your country. If (like Australia), your country has moved on from the 1980s and deprecated GSM, you will need to use another option (scroll down).

When using the pre-built image for the Raspberry Pi, you have to install the following dependencies:

$ sudo apt-get install libtool pkg-config libfftw3-dev librtlsdr-dev automake m4

Then you can build and install it with

$ ./bootstrap
$ CXXFLAGS='-W -Wall -O3' ./configure
$ make
$ sudo make install

For usage, see available parameters:

$ kal -h
kalibrate v0.4.1-rtl, Copyright (c) 2010, Joshua Lackey
modified for use with rtl-sdr devices, Copyright (c) 2012, Steve Markgraf
Usage:
	GSM Base Station Scan:
		kal <-s band indicator> [options]

	Clock Offset Calculation:
		kal <-f frequency | -c channel> [options]

Where options are:
	-s	band to scan (GSM850, GSM-R, GSM900, EGSM, DCS, PCS)
	-f	frequency of nearby GSM base station
	-c	channel of nearby GSM base station
	-b	band indicator (GSM850, GSM-R, GSM900, EGSM, DCS, PCS)
	-g	gain in dB
	-d	rtl-sdr device index
	-e	initial frequency error in ppm
	-E	manual frequency offset in hz
	-v	verbose
	-D	enable debug messages
	-h	help


choose an appropriate band for scanning:

$ kal -s GSM900
Found 1 device(s):
  0:  Generic RTL2832U OEM

Using device 0: Generic RTL2832U OEM
Found Elonics E4000 tuner
Exact sample rate is: 270833.002142 Hz
kal: Scanning for GSM-900 base stations.
GSM-900:
    chan:   33 (941.6MHz - 155Hz)    power: 4877018.31
    chan:   41 (943.2MHz - 208Hz)    power: 2265226.87
    chan:   43 (943.6MHz - 133Hz)    power: 1287992.91
    chan:   55 (946.0MHz - 179Hz)    power: 1041611.46
    chan:   57 (946.4MHz - 252Hz)    power: 1405188.40
    chan:   66 (948.2MHz -  13Hz)    power: 5027059.56
    chan:   79 (950.8MHz - 111Hz)    power: 1088677.82
    chan:   84 (951.8MHz - 231Hz)    power:  945912.38
    chan:   86 (952.2MHz - 212Hz)    power: 2314696.93
    chan:  116 (958.2MHz - 180Hz)    power:  862935.90


choose a strong channel:

$ kal -c 33
Found 1 device(s):
  0:  Generic RTL2832U OEM

Using device 0: Generic RTL2832U OEM
Found Elonics E4000 tuner
Exact sample rate is: 270833.002142 Hz
kal: Calculating clock frequency offset.
Using GSM-900 channel 33 (941.6MHz)
Tuned to 941.600000MHz (reported tuner error: 0Hz)
average		[min, max]	(range, stddev)
- 206Hz		[-293, -89]	(204, 56.913998)
overruns: 0
not found: 0
average absolute error: 0.219 ppm


Now enter the measured ppm in satnogs-setup and you're done. The value should be entered without decimals, for example -1.

Automatic Adjustment using LTE Signals

If you are living in a country where GSM is no longer present, but LTE is available (in a frequency range supported by your receiver), then you can determine your SDR's PPM offset by following this guide: https://gist.github.com/darksidelemm/b517e6a9b821c50c170f1b9b7d65b824

Manual Adjustment using GQRX

If you cannot calibrate against GSM or LTE towers, but you have a nearby amateur radio beacon or transmitter at a reasonably well-known frequency, you can use this to obtain at least a coarse PPM correction.

NOTE: This section needs to be updated to follow the same process as is used in `Setting The Gain`, as rtl_tcp may not be available on the latest SatNOGS RPI images, and will not work if any other SDR type is in use.

SSH to your SatNOGS Pi with your well-known user account; by default, this is the user "pi". After successful authorization you will see a prompt like this:

 Linux satnogs190-dev 4.9.59-v7+ #1047 SMP Sun Oct 29 12:19:23 GMT 2017 armv7l

 The programs included with the Debian GNU/Linux system are free software;
 the exact distribution terms for each program are described in the
 individual files in /usr/share/doc/*/copyright.

 Debian GNU/Linux comes with ABSOLUTELY NO WARRANTY, to the extent
 permitted by applicable law.
 Last login: Fri Jan 12 07:34:11 2018 from 192.168.10.35
 pd@satnogs190-dev:~ $

You will now need to temporarily stop the satnogs-client, using the command:

$ sudo systemctl stop satnogs-client

Now go ahead and start the "RTL SDR spectrum server":

$ rtl_tcp -a 0.0.0.0

If everything is fine, you will get an output like this:

 Found 1 device(s):
   0:  Generic, RTL2832U, SN: 77771111153705700

 Using device 0: Generic RTL2832U
 Found Rafael Micro R820T tuner
 [R82XX] PLL not locked!
 Tuned to 100000000 Hz.
 listening...

Use the device argument 'rtl_tcp=0.0.0.0:1234' in OsmoSDR (gr-osmosdr) source to receive samples in GRC and control rtl_tcp parameters (frequency, gain, ...). No further output will be generated until you connect to this server. Hitting C-c will stop it and the command line appears. 
Idea.png
You will have to stop this server if you want to go back to network mode - do not forget about this!

Now go ahead and start gqrx:

Startup gqrx.png

You will have to go to the setup menu, either by clicking on the "harde" symbol, or navigating through the menu item called "File -> I/O Devices"

Gqrx io configuration.png

Click on "Device" and chose "RTL-SDR Spectrum Server" Edit "Device string" to match your Pi's IP address, Port defaults to 1234, which is the same as the default setting for your server you just started on the Pi. Set "Input Rate" to something network friendly - we do not need the whole spectrum the RTL SDR is able to convert. 1,8 MSPS (1800000) should be OK Depending on this setting your network will get very busy. Using wireless LAN is not recommended. Every sample has a data size of 16 bits, so the previous setting of 1,8MSPS/s results in a network load of 28,8 MBit/s:

1,8 MSPS * 16 bit/s = 28,8 MBit/s


"Audio Output -> Device" and "-> Sample rate" should be set by default, values on average soundcards would be something like "Default, 48 kHz" Close the dialogue by clicking "OK" Your RTL-SDR spectrum server on the Pi should now show up a connection from your computer running gqrx.

 client accepted!
 set gain mode 1
 set agc mode 0
 set direct sampling 0
 Disabled direct sampling mode
 set offset tuning 0
 set sample rate 960000
 ll+, now 1
 ll+, now 2
 set freq correction 42
 set freq 144500000
 set gain mode 0
 set agc mode 1
 set gain 0
 set freq 145814000
 ll-, now 0
 ll+, now 1
 ll+, now 2
 ll+, now 3
 ll+, now 4
 ll+, now 5
 ll+, now 6
 ll+, now 7
 ll+, now 8
 ll+, now 9
 ll+, now 10
 ll+, now 11
 ll+, now 12
 ll+, now 13

The only thing left now is to "Start DSP" - from the menu item "File", by hitting C-d or simply clicking the Play-Button.

Gqrx running.png

Go for a known local HAM radio repeater or a CW beacon transmitter and set your demodulator accordingly. Narrow Band FM or CW is best to discover ppm error offset, which is the frequency offset in parts per million (ppm) which is always there with standard RTL-SDR dongles. For SDRs without a Temperature Compensated Crystal Oscillator ('TCXO') this value may be temperature dependent. Enter the known frequency of your chosen transmitter (NFM repeater or CW beacon). I have chosen a very known CW beacon just some km away from my home: ON4VHF on 144.718000 MHz. Walk through the tab called "Receiver options" and change the settings to fit the beacon: "Filter width Normal", "Filter shape Normal", "Mode CW-L", "AGC Medium". Set Squelch to something low, so you can hear noise from your speakers. Maybe you have to Adjust the audio "Gain" to something like "0.0 dB". You can adjust this to fit your needs to hear noise. With ppm error, which is default, set to 0.0 ppm, one can just guess where your receiver is listening. Anyway, just set it to 144.718000 MHz and try to find your beacon. You can see the result for my RTL SDR dongle down here:

Gqrx ppm-error offset.png

Now got to the tab called "Input controls" and find an input field called "Freq. correction". By default this should show "0,0 ppm". Set frequency back to your beacons transmit frequency. After this you have to increase the Freq. correction value as long until you can hear the beacon. Now zoom into the panorama by locating your mouse pointer in the range where the frequency values are printed below the panorama, just above the waterfall. Try to fit the Freq. correction value as good as possible, that your receivers red indication line is just in the middle of the transmitters bandwidth.

Gqrx ppm-error corrected.png

Now write down the evaluated ppm correction value and exit gqrx as well as the RTL SDR spectrum server. In the command line now available start satnogs-setup:

$ sudo satnogs-setup

Navigate to "Advanced -> SATNOGS_PPM_ERROR" and enter the new value.

Fcecd26ca08cf3d23dffce719ef1dd13a4f7109d.png

Exit the satnogs-setup with "Back", then "Apply Configuration" (this might take a while) and "Back".

You are done with frequency offset correction.

Idea.png
With gqrx, you get a nice tool to do some SDR stuff by the way. Just play around a bit and get familiar with all that stuff. Just keep in mind that, as long as you run the RTL SDR Spectrum server or you have set your client into standalone mode, nothing is done from network.

adjustment using observations

Another way of adjusting the frequency offset is by making an observation of a satellite that transmits CW. Once the observation is complete, the CW signal from the satellite should look like a straight line at 0Hz on the observation waterfall. If there's a frequency offset, the signal will be off-center. The image below shows observation details for a CW transmitter on VHF. Since the frequency offset is not yet adjusted, the CW signal is present between the -10kHz and 0Hz markers.

Idea.png
It is possible for the CW signal to appear at a frequency above the 10kHz tick or below the -10kHz tick. In that case, use the frequency of the first tick with a higher absolute value frequency than the CW signal absolute value frequency. Do not forget to update the selected tick frequency in the equations below!


Marked CW observation.jpg

In order to compute the frequency offset, the waterfall image can be downloaded and opened with graphics editor like GIMP. After opening the waterfall image, vertical markers are placed on the -10kHz tick, the 0Hz tick and on the CW signal. Once the markers are placed, measure the width in pixels between the -10kHz tick and 0Hz tick, as well as the width between the CW signal and the 0Hz tick. The image below shows an example of the placed markers and the widths to be measured:

Measurement markers.jpg

Let’s call the width between the -10kHz and 0Hz markers widthTickTo0, and the width between the CW and 0Hz markers widthCWto0. From the example image above, we get the values widthTickTo0 = 224 and widthCWto0 = 131. To compute the frequency offset, we compute the ratio between those widths and multiply by the frequency tick value as follows:

frequencyOffset = -10,000Hz * widthCWto0 / widthTickTo0

In the case of the example above:

frequencyOffset = -10,000Hz * widthCWto0 / widthTickTo0 = -10,000Hz * 131 / 224 = -5,848Hz

To compute the offset in PPM, divide the frequency offset in Hz by the transmitter frequency in MHz. In the case of the example above:

ppmOffset = frequencyOffset / transmitterFrequency = -5,848Hz / 145.725MHz = -40 PPM

The correction entered in satnogs-setup must have the opposite sign of that in the calculation, since we will be shifting the frequency in the opposite direction, making the SATNOGS_PPM_ERROR value:

SATNOGS_PPM_ERROR = 40

Note that if the CW signal is on the left side of the 0Hz marker, the PPM value is positive, otherwise, the PPM value is negative.

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Please keep in mind that it is possible for the CW transmitter to drift in some satellites. This makes the CW transmission an unreliable source in some cases. Make sure to double-check your adjustment with another CW satellite!

Enhancements

Waterfall Color improvements

By default the SatNOGS client will adjust the waterfall colour ranges to best display the received signal.

If desired, this auto-ranging can be disabled by running sudo satnogs-setup, and navigating to Advanced -> Waterfall. From here the auto-ranging can be turned off, and the minimum and maximum waterfall colour-scale levels can be set.