KB8PMY
/
CubeSatSim
mirror of https://github.com/alanbjohnston/CubeSatSim.git
1
0
Fork 0
Code Issues Packages Projects Releases Wiki Activity

updated for rel 0.19 and also UHF, VHF, and HF profiles together

Browse Source
pull/52/head
alanbjohnston 6 years ago committed by GitHub
parent 32989c1e2a
commit 1613fef27d
No known key found for this signature in database
GPG Key ID: 4AEE18F83AFDEB23
1 changed files with 779 additions and 145 deletions
Show Stats Download Patch File Download Diff File

878
groundstation/config_webrx.py
Unescape View File

@ -6,6 +6,7 @@ config_webrx: configuration options for OpenWebRX
This file is part of OpenWebRX, This file is part of OpenWebRX,
an open-source SDR receiver software with a web UI. an open-source SDR receiver software with a web UI.
Copyright (c) 2013-2015 by Andras Retzler <randras@sdr.hu> Copyright (c) 2013-2015 by Andras Retzler <randras@sdr.hu>
Copyright (c) 2019-2020 by Jakob Ketterl <dd5jfk@darc.de>
This program is free software: you can redistribute it and/or modify This program is free software: you can redistribute it and/or modify
it under the terms of the GNU Affero General Public License as it under the terms of the GNU Affero General Public License as
@ -16,6 +17,7 @@ config_webrx: configuration options for OpenWebRX
but WITHOUT ANY WARRANTY; without even the implied warranty of but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU Affero General Public License for more details. GNU Affero General Public License for more details.
You should have received a copy of the GNU Affero General Public License You should have received a copy of the GNU Affero General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>. along with this program. If not, see <http://www.gnu.org/licenses/>.
@ -28,61 +30,55 @@ config_webrx: configuration options for OpenWebRX
(It means that you do not have to redistribute config_rtl.py and (It means that you do not have to redistribute config_rtl.py and
config_webrx.py if you make any changes to these two configuration files, config_webrx.py if you make any changes to these two configuration files,
and use them for running your web service with OpenWebRX.) and use them for running your web service with OpenWebRX.)
portions inspired by http://gephi.michalnovak.eu/config_webrx.py
""" """
# configuration version. please only modify if you're able to perform the associated migration steps.
version = 2
# NOTE: you can find additional information about configuring OpenWebRX in the Wiki: # NOTE: you can find additional information about configuring OpenWebRX in the Wiki:
# https://github.com/simonyiszk/openwebrx/wiki # https://github.com/jketterl/openwebrx/wiki/Configuration-guide
# ==== Server settings ==== # ==== Server settings ====
web_port = 8073 web_port = 8073
server_hostname="localhost" # If this contains an incorrect value, the web UI may freeze on load (it can't open websocket) max_clients = 10
max_clients=20
# ==== Web GUI configuration ==== # ==== Web GUI configuration ====
receiver_name="AMSAT CubeSat Simulator Ground Station" receiver_name = "KU2Y"
receiver_location="" receiver_location = "Philadelphia, PA"
receiver_qra="" receiver_asl = 200
receiver_asl=0
receiver_ant="monopole"
receiver_device="RTL-SDR"
receiver_admin = "ku2y@amsat.org" receiver_admin = "ku2y@amsat.org"
receiver_gps=(39.0302,-77.0747) receiver_gps = (40.0376, -75.3492)
photo_height=350 receiver_gps = {"lat": 40.0376, "lon": -75.3492}
photo_title="Panorama of Budapest from Schönherz Zoltán Dormitory" photo_title = "ARISS"
photo_desc = """ photo_desc = """
You can add your own background photo and receiver information.<br /> You can add your own background photo and receiver information.<br />
Receiver is operated by: <a href="mailto:%[RX_ADMIN]">%[RX_ADMIN]</a><br/> Receiver is operated by: <a href="mailto:ku2y@amsat.org">ku2y@amsat.org</a><br/>
Device: %[RX_DEVICE]<br /> Device: RTL-SDR<br />
Antenna: %[RX_ANT]<br /> Antenna: <br />
Website: <a href="http://localhost" target="_blank">http://localhost</a> Website: <a href="http://ariss-radio:8073" target="_blank">http://ariss-radio:8073</a>
""" """
# ==== sdr.hu listing ====
# If you want your ham receiver to be listed publicly on sdr.hu, then take the following steps:
# 1. Register at: http://sdr.hu/register
# 2. You will get an unique key by email. Copy it and paste here:
sdrhu_key = ""
# 3. Set this setting to True to enable listing:
sdrhu_public_listing = False
# ==== DSP/RX settings ==== # ==== DSP/RX settings ====
fft_fps = 9 fft_fps = 9
fft_size = 4096 # Should be power of 2 fft_size = 4096 # Should be power of 2
fft_voverlap_factor=0.3 #If fft_voverlap_factor is above 0, multiple FFTs will be used for creating a line on the diagram. fft_voverlap_factor = (
0.3 # If fft_voverlap_factor is above 0, multiple FFTs will be used for creating a line on the diagram.
samp_rate = 250000 )
# samp_rate = 2400000
center_freq = 434950000
rf_gain = 7 #in dB. For an RTL-SDR, rf_gain=0 will set the tuner to auto gain mode, else it will be in manual gain mode.
ppm = 0
audio_compression = "adpcm" # valid values: "adpcm", "none" audio_compression = "adpcm" # valid values: "adpcm", "none"
fft_compression = "adpcm" # valid values: "adpcm", "none" fft_compression = "adpcm" # valid values: "adpcm", "none"
digimodes_enable=False # True #Decoding digimodes come with higher CPU usage. digimodes_enable = True # Decoding digimodes come with higher CPU usage.
digimodes_fft_size = 1024 digimodes_fft_size = 1024
start_rtl_thread=True # determines the quality, and thus the cpu usage, for the ambe codec used by digital voice modes
# if you're running on a Raspi (up to 3B+) you'll want to leave this on 1
digital_voice_unvoiced_quality = 1
# enables lookup of DMR ids using the radioid api
digital_voice_dmr_id_lookup = True
""" """
Note: if you experience audio underruns while CPU usage is 100%, you can: Note: if you experience audio underruns while CPU usage is 100%, you can:
@ -95,109 +91,698 @@ Note: if you experience audio underruns while CPU usage is 100%, you can:
# ==== I/Q sources ==== # ==== I/Q sources ====
# (Uncomment the appropriate by removing # characters at the beginning of the corresponding lines.) # (Uncomment the appropriate by removing # characters at the beginning of the corresponding lines.)
################################################################################################# ###############################################################################
# Is my SDR hardware supported? # # Is my SDR hardware supported? #
# Check here: https://github.com/simonyiszk/openwebrx/wiki#guides-for-receiver-hardware-support # # Check here: https://github.com/jketterl/openwebrx/wiki/Supported-Hardware #
################################################################################################# ###############################################################################
# You can use other SDR hardware as well, by giving your own command that outputs the I/Q samples... Some examples of configuration are available here (default is RTL-SDR):
# >> RTL-SDR via rtl_sdr
start_rtl_command="rtl_sdr -s {samp_rate} -f {center_freq} -p {ppm} -g {rf_gain} -".format(rf_gain=rf_gain, center_freq=center_freq, samp_rate=samp_rate, ppm=ppm)
format_conversion="csdr convert_u8_f"
#lna_gain=8
#rf_amp=1
#start_rtl_command="hackrf_transfer -s {samp_rate} -f {center_freq} -g {rf_gain} -l{lna_gain} -a{rf_amp} -r-".format(rf_gain=rf_gain, center_freq=center_freq, samp_rate=samp_rate, ppm=ppm, rf_amp=rf_amp, lna_gain=lna_gain)
#format_conversion="csdr convert_s8_f"
"""
To use a HackRF, compile the HackRF host tools from its "stdout" branch:
git clone https://github.com/mossmann/hackrf/
cd hackrf
git fetch
git checkout origin/stdout
cd host
mkdir build
cd build
cmake .. -DINSTALL_UDEV_RULES=ON
make
sudo make install
"""
# >> Sound card SDR (needs ALSA)
# I did not have the chance to properly test it.
#samp_rate = 96000
#start_rtl_command="arecord -f S16_LE -r {samp_rate} -c2 -".format(samp_rate=samp_rate)
#format_conversion="csdr convert_s16_f | csdr gain_ff 30"
# >> /dev/urandom test signal source
# samp_rate = 2400000
# start_rtl_command="cat /dev/urandom | (pv -qL `python -c 'print int({samp_rate} * 2.2)'` 2>&1)".format(rf_gain=rf_gain, center_freq=center_freq, samp_rate=samp_rate)
# format_conversion="csdr convert_u8_f"
# >> Pre-recorded raw I/Q file as signal source
# You will have to correctly specify: samp_rate, center_freq, format_conversion in order to correctly play an I/Q file.
#start_rtl_command="(while true; do cat my_iq_file.raw; done) | csdr flowcontrol {sr} 20 ".format(sr=samp_rate*2*1.05)
#format_conversion="csdr convert_u8_f"
#>> The rx_sdr command works with a variety of SDR harware: RTL-SDR, HackRF, SDRplay, UHD, Airspy, Red Pitaya, audio devices, etc.
# It will auto-detect your SDR hardware if the following tools are installed:
# * the vendor provided driver and library,
# * the vendor-specific SoapySDR wrapper library,
# * and SoapySDR itself.
# Check out this article on the OpenWebRX Wiki: https://github.com/simonyiszk/openwebrx/wiki/Using-rx_tools-with-OpenWebRX/
#start_rtl_command="rx_sdr -F CF32 -s {samp_rate} -f {center_freq} -p {ppm} -g {rf_gain} -".format(rf_gain=rf_gain, center_freq=center_freq, samp_rate=samp_rate, ppm=ppm)
#format_conversion=""
# >> gr-osmosdr signal source using GNU Radio (follow this guide: https://github.com/simonyiszk/openwebrx/wiki/Using-GrOsmoSDR-as-signal-source) # Currently supported types of sdr receivers:
#start_rtl_command="cat /tmp/osmocom_fifo" # "rtl_sdr", "rtl_sdr_soapy", "sdrplay", "hackrf", "airspy", "airspyhf", "fifi_sdr",
#format_conversion="" # "perseussdr", "lime_sdr", "pluto_sdr", "soapy_remote"
#
# ==== Misc settings ==== # In order to use rtl_sdr, you will need to install librtlsdr-dev and the connector.
# In order to use sdrplay, airspy or airspyhf, you will need to install soapysdr, the corresponding driver, and the
shown_center_freq = center_freq #you can change this if you use an upconverter # connector.
#
client_audio_buffer_size = 5 # https://github.com/jketterl/owrx_connector
#increasing client_audio_buffer_size will: #
# - also increase the latency # In order to use Perseus HF you need to install the libperseus-sdr
# - decrease the chance of audio underruns #
# https://github.com/Microtelecom/libperseus-sdr
start_freq = center_freq #
start_mod = "nfm" #nfm, am, lsb, usb, cw # and do the proper changes to the sdrs object below
# (see also Wiki in https://github.com/jketterl/openwebrx/wiki/Sample-configuration-for-Perseus-HF-receiver).
iq_server_port = 4951 #TCP port for ncat to listen on. It will send I/Q data over its connections, for internal use in OpenWebRX. It is only accessible from the localhost by default. #
#access_log = "~/openwebrx_access.log" sdrs = {
"rtlsdr": {
"name": "RTL-SDR VHF/UHF",
"type": "rtl_sdr",
"ppm": 0,
# you can change this if you use an upconverter. formula is:
# center_freq + lfo_offset = actual frequency on the sdr
# "lfo_offset": 0,
"profiles": {
"wx": {
"name": "Weather Band",
"center_freq": 162000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 161500000,
"start_mod": "nfm",
},
"70cm": {
"name": "70cm Band",
"center_freq": 435500000,
"rf_gain": 3,
"samp_rate": 2400000,
"start_freq": 4355000000,
"start_mod": "nfm",
},
"70cm-hi": {
"name": "70cm Band High Gain",
"center_freq": 435500000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 4355000000,
"start_mod": "nfm",
},
"2m": {
"name": "2m Band",
"center_freq": 145000000,
"rf_gain": 15,
"samp_rate": 2400000,
"start_freq": 145725000,
"start_mod": "nfm",
},
"2m-hi": {
"name": "2m Band High Gain",
"center_freq": 145000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 145725000,
"start_mod": "nfm",
},
"fm": {
"name": "FM Band",
"center_freq": 91000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 90000000,
"start_mod": "nfm",
},
"atc": {
"name": "Air Band - ATC",
"center_freq": 134000000,
"rf_gain": 20,
"samp_rate": 2400000,
"start_freq": 134000000,
"start_mod": "am",
},
"atc-hi": {
"name": "Air Band - ATC High Gain",
"center_freq": 134000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 134000000,
"start_mod": "am",
},
"noaa": {
"name": "NOAA Weather Satellites",
"center_freq": 137000000,
"rf_gain": 20,
"samp_rate": 2400000,
"start_freq": 137000000,
"start_mod": "fm",
},
"noaa-hi": {
"name": "NOAA Weather Satellites High Gain",
"center_freq": 137000000,
"rf_gain": 25,
"samp_rate": 2400000,
"start_freq": 137000000,
"start_mod": "fm",
},
"10m": {
"name": "10m Band",
"center_freq": 28000000,
"rf_gain": 25,
"samp_rate": 2400000,
"start_freq": 28500000,
"start_mod": "usb",
},
"6m": {
"name": "6m Band",
"center_freq": 51000000,
"rf_gain": 25,
"samp_rate": 2400000,
"start_freq": 51000000,
"start_mod": "usb",
},
"110MHz": {
"name": "110 MHz",
"center_freq": 110000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 110000000,
"start_mod": "nfm",
},
"112MHz": {
"name": "112 MHz",
"center_freq": 112000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 112000000,
"start_mod": "nfm",
},
"114MHz": {
"name": "114 MHz",
"center_freq": 114000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 114000000,
"start_mod": "nfm",
},
"116mhz": {
"name": "116 MHz",
"center_freq": 116000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 116000000,
"start_mod": "nfm",
},
"118mhz": {
"name": "118 MHz",
"center_freq": 118000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 118000000,
"start_mod": "nfm",
},
"120mhz": {
"name": "120 MHz",
"center_freq": 120000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 120000000,
"start_mod": "nfm",
},
"122mhz": {
"name": "122 MHz",
"center_freq": 122000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 122000000,
"start_mod": "nfm",
},
"124mhz": {
"name": "124 MHz",
"center_freq": 124000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 124000000,
"start_mod": "nfm",
},
"126mhz": {
"name": "126 MHz",
"center_freq": 126000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 126000000,
"start_mod": "nfm",
},
"128mhz": {
"name": "126 MHz",
"center_freq": 128000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 128000000,
"start_mod": "nfm",
},
"130mhz": {
"name": "130 MHz",
"center_freq": 130000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 130000000,
"start_mod": "nfm",
},
"132mhz": {
"name": "132 MHz",
"center_freq": 132000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 132000000,
"start_mod": "nfm",
},
"134mhz": {
"name": "134 MHz",
"center_freq": 134000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 134000000,
"start_mod": "nfm",
},
"136mhz": {
"name": "136 MHz",
"center_freq": 136000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 136000000,
"start_mod": "nfm",
},
"138mhz": {
"name": "138 MHz",
"center_freq": 138000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 138000000,
"start_mod": "nfm",
},
"140mhz": {
"name": "140 MHz",
"center_freq": 140000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 140000000,
"start_mod": "nfm",
},
"142mhz": {
"name": "142 MHz",
"center_freq": 142000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 142000000,
"start_mod": "nfm",
},
"144mhz": {
"name": "144 MHz",
"center_freq": 144000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 144000000,
"start_mod": "nfm",
},
"146mhz": {
"name": "146 MHz",
"center_freq": 146000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 146000000,
"start_mod": "nfm",
},
"148mhz": {
"name": "148 MHz",
"center_freq": 148000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 148000000,
"start_mod": "nfm",
},
"150mhz": {
"name": "150 MHz",
"center_freq": 150000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 150000000,
"start_mod": "nfm",
},
"152mhz": {
"name": "152 MHz",
"center_freq": 152000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 152000000,
"start_mod": "nfm",
},
"154mhz": {
"name": "154 MHz",
"center_freq": 154000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 154000000,
"start_mod": "nfm",
},
"156mhz": {
"name": "156 MHz",
"center_freq": 156000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 156100000,
"start_mod": "nfm",
},
"158mhz": {
"name": "158 MHz",
"center_freq": 158000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 158000000,
"start_mod": "nfm",
},
"160mhz": {
"name": "160 MHz",
"center_freq": 160000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 160000000,
"start_mod": "nfm",
},
"162mhz": {
"name": "162 MHz",
"center_freq": 162000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 162000000,
"start_mod": "nfm",
},
"164mhz": {
"name": "164 MHz",
"center_freq": 164000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 164000000,
"start_mod": "nfm",
},
"166mhz": {
"name": "166 MHz",
"center_freq": 166000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 166000000,
"start_mod": "nfm",
},
"168mhz": {
"name": "168 MHz",
"center_freq": 168000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 168000000,
"start_mod": "nfm",
},
"170mhz": {
"name": "170 MHz",
"center_freq": 170000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 170000000,
"start_mod": "nfm",
},
"172mhz": {
"name": "172 MHz",
"center_freq": 172000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 172000000,
"start_mod": "nfm",
},
"174mhz": {
"name": "174 MHz",
"center_freq": 174000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 174000000,
"start_mod": "nfm",
},
"433mhz": {
"name": "433 MHz",
"center_freq": 433000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 433000000,
"start_mod": "nfm",
},
"446mhz": {
"name": "446 MHz (PMR)",
"center_freq": 446000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 446000000,
"start_mod": "nfm",
},
"460mhz": {
"name": "460 MHz",
"center_freq": 460000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 460000000,
"start_mod": "nfm",
},
"860mhz": {
"name": "860 MHz",
"center_freq": 860000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 860000000,
"start_mod": "nfm",
},
"862mhz": {
"name": "862 MHz",
"center_freq": 862000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 862000000,
"start_mod": "nfm",
},
"864mhz": {
"name": "864 MHz",
"center_freq": 864000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 864000000,
"start_mod": "nfm",
},
"866mhz": {
"name": "866 MHz",
"center_freq": 866000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 866000000,
"start_mod": "nfm",
},
"868mhz": {
"name": "868 MHz",
"center_freq": 868000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 868000000,
"start_mod": "nfm",
},
"870mhz": {
"name": "870 MHz",
"center_freq": 870000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 870000000,
"start_mod": "nfm",
},
"915mhz": {
"name": "915 MHz",
"center_freq": 915000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 915000000,
"start_mod": "nfm",
},
"1090mhz": {
"name": "1090 MHz",
"center_freq": 1090000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1090000000,
"start_mod": "nfm",
},
"1880mhz": {
"name": "1880 MHz",
"center_freq": 1880000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1880000000,
"start_mod": "nfm",
},
"1882mhz": {
"name": "1882 MHz",
"center_freq": 1882000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1882000000,
"start_mod": "nfm",
},
"1884mhz": {
"name": "1884 MHz",
"center_freq": 1884000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1884000000,
"start_mod": "nfm",
},
"1886mhz": {
"name": "1886 MHz",
"center_freq": 1886000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1886000000,
"start_mod": "nfm",
},
"1888mhz": {
"name": "1888 MHz",
"center_freq": 1888000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1888000000,
"start_mod": "nfm",
},
"1890mhz": {
"name": "1890 MHz",
"center_freq": 1890000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1890000000,
"start_mod": "nfm",
},
"1892mhz": {
"name": "1892 MHz",
"center_freq": 1892000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1892000000,
"start_mod": "nfm",
},
"1894mhz": {
"name": "1894 MHz",
"center_freq": 1894000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1894000000,
"start_mod": "nfm",
},
"1896mhz": {
"name": "1896 MHz",
"center_freq": 1896000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1896000000,
"start_mod": "nfm",
},
"1898mhz": {
"name": "1898 MHz",
"center_freq": 1898000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1898000000,
"start_mod": "nfm",
},
"1900mhz": {
"name": "1900 MHz",
"center_freq": 1900000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1900000000,
"start_mod": "nfm",
},
"23cm": {
"name": "23cm Band",
"center_freq": 1270000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 1270000000,
"start_mod": "nfm",
},
"13cm": {
"name": "13cm Band",
"center_freq": 2370000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 2370000000,
"start_mod": "nfm",
},
"9cm": {
"name": "9cm Band",
"center_freq": 3440000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 3440000000,
"start_mod": "nfm",
},
},
},
"rtl_sdr-2": {
"name": "RTL-SDR HF",
"type": "rtl_sdr_soapy",
"ppm": 0,
"direct_sampling": 2,
"profiles": {
"10m": {
"name": "10m Band",
"center_freq": 29150000,
"rf_gain": 10,
"samp_rate": 2400000,
"start_freq": 28283000,
"start_mod": "usb",
},
"19m": {
"name": "19m Broadcast Band",
"center_freq": 16000000,
"rf_gain": 10,
"samp_rate": 2400000,
"start_freq": 15400000,
"start_mod": "am",
},
"20m": {
"name": "20m Band",
"center_freq": 14150000,
"rf_gain": 10,
"samp_rate": 2400000,
"start_freq": 14070000,
"start_mod": "usb",
},
"30m": {
"name": "30m Band",
"center_freq": 10125000,
"rf_gain": 10,
"samp_rate": 2400000,
"start_freq": 10142000,
"start_mod": "usb",
},
"40m": {
"name": "40m Band",
"center_freq": 7100000,
"rf_gain": 10,
"samp_rate": 2400000,
"start_freq": 7070000,
"start_mod": "lsb",
},
"49m": {
"name": "49m Broadcast Band",
"center_freq": 6000000,
"rf_gain": 10,
"samp_rate": 2400000,
"start_freq": 6070000,
"start_mod": "am",
},
"80m": {
"name": "80m Band",
"center_freq": 3650000,
"rf_gain": 10,
"samp_rate": 2400000,
"start_freq": 3570000,
"start_mod": "lsb",
},
"160m": {
"name": "160m Band",
"center_freq": 1700000,
"rf_gain": 10,
"samp_rate": 2400000,
"start_freq": 1440000,
"start_mod": "am",
},
},
},
}
# ==== Color themes ==== # ==== Color themes ====
# A guide is available to help you set these values: https://github.com/simonyiszk/openwebrx/wiki/Calibrating-waterfall-display-levels # A guide is available to help you set these values: https://github.com/simonyiszk/openwebrx/wiki/Calibrating-waterfall-display-levels
### default theme by teejez: ### default theme by teejez:
waterfall_colors = "[0x000000ff,0x0000ffff,0x00ffffff,0x00ff00ff,0xffff00ff,0xff0000ff,0xff00ffff,0xffffffff]" waterfall_colors = [0x000000FF, 0x0000FFFF, 0x00FFFFFF, 0x00FF00FF, 0xFFFF00FF, 0xFF0000FF, 0xFF00FFFF, 0xFFFFFFFF]
waterfall_min_level = -88 # in dB waterfall_min_level = -88 # in dB
waterfall_max_level = -20 waterfall_max_level = -20
waterfall_auto_level_margin = (5, 40) waterfall_auto_level_margin = {"min": 5, "max": 40}
### old theme by HA7ILM: ### old theme by HA7ILM:
# waterfall_colors = "[0x000000ff,0x2e6893ff, 0x69a5d0ff, 0x214b69ff, 0x9dc4e0ff, 0xfff775ff, 0xff8a8aff, 0xb20000ff]" # waterfall_colors = "[0x000000ff,0x2e6893ff, 0x69a5d0ff, 0x214b69ff, 0x9dc4e0ff, 0xfff775ff, 0xff8a8aff, 0xb20000ff]"
# waterfall_min_level = -115 #in dB # waterfall_min_level = -115 #in dB
# waterfall_max_level = 0 # waterfall_max_level = 0
#waterfall_auto_level_margin = (20, 30) # waterfall_auto_level_margin = {"min": 20, "max": 30}
##For the old colors, you might also want to set [fft_voverlap_factor] to 0. ##For the old colors, you might also want to set [fft_voverlap_factor] to 0.
# Note: When the auto waterfall level button is clicked, the following happens: # Note: When the auto waterfall level button is clicked, the following happens:
# [waterfall_min_level] = [current_min_power_level] - [waterfall_auto_level_margin[0]] # [waterfall_min_level] = [current_min_power_level] - [waterfall_auto_level_margin["min"]]
# [waterfall_max_level] = [current_max_power_level] + [waterfall_auto_level_margin[1]] # [waterfall_max_level] = [current_max_power_level] + [waterfall_auto_level_margin["max"]]
# #
# ___|____________________________________|____________________________________|____________________________________|___> signal power # ___|________________________________________|____________________________________|________________________________________|___> signal power
# \_waterfall_auto_level_margin[0]_/ |__ current_min_power_level | \_waterfall_auto_level_margin[1]_/ # \_waterfall_auto_level_margin["min"]_/ |__ current_min_power_level | \_waterfall_auto_level_margin["max"]_/
# current_max_power_level __| # current_max_power_level __|
# 3D view settings
mathbox_waterfall_frequency_resolution = 128 #bins
mathbox_waterfall_history_length = 10 #seconds
mathbox_waterfall_colors = "[0x000000ff,0x2e6893ff, 0x69a5d0ff, 0x214b69ff, 0x9dc4e0ff, 0xfff775ff, 0xff8a8aff, 0xb20000ff]"
# === Experimental settings === # === Experimental settings ===
# Warning! The settings below are very experimental. # Warning! The settings below are very experimental.
csdr_dynamic_bufsize = False # This allows you to change the buffering mode of csdr. csdr_dynamic_bufsize = False # This allows you to change the buffering mode of csdr.
@ -206,10 +791,59 @@ csdr_through = False # Setting this True will print out how much data is going i
nmux_memory = 50 # in megabytes. This sets the approximate size of the circular buffer used by nmux. nmux_memory = 50 # in megabytes. This sets the approximate size of the circular buffer used by nmux.
#Look up external IP address automatically from icanhazip.com, and use it as [server_hostname] google_maps_api_key = ""
"""
print "[openwebrx-config] Detecting external IP address..." # how long should positions be visible on the map?
import urllib2 # they will start fading out after half of that
server_hostname=urllib2.urlopen("http://icanhazip.com").read()[:-1] # in seconds; default: 2 hours
print "[openwebrx-config] External IP address detected:", server_hostname map_position_retention_time = 2 * 60 * 60
"""
# decoder queue configuration
# due to the nature of some operating modes (ft8, ft8, jt9, jt65, wspr and js8), the data is recorded for a given amount
# of time (6 seconds up to 2 minutes) and decoded at the end. this can lead to very high peak loads.
# to mitigate this, the recordings will be queued and processed in sequence.
# the number of workers will limit the total amount of work (one worker will losely occupy one cpu / thread)
decoding_queue_workers = 2
# the maximum queue length will cause decodes to be dumped if the workers cannot keep up
# if you are running background services, make sure this number is high enough to accept the task influx during peaks
# i.e. this should be higher than the number of decoding services running at the same time
decoding_queue_length = 10
# wsjt decoding depth will allow more results, but will also consume more cpu
wsjt_decoding_depth = 3
# can also be set for each mode separately
# jt65 seems to be somewhat prone to erroneous decodes, this setting handles that to some extent
wsjt_decoding_depths = {"jt65": 1}
# JS8 comes in different speeds: normal, slow, fast, turbo. This setting controls which ones are enabled.
js8_enabled_profiles = ["normal", "slow"]
# JS8 decoding depth; higher value will get more results, but will also consume more cpu
js8_decoding_depth = 3
temporary_directory = "/tmp/openwebrx"
services_enabled = False
services_decoders = ["ft8", "ft4", "wspr", "packet"]
# === aprs igate settings ===
# if you want to share your APRS decodes with the aprs network, configure these settings accordingly
aprs_callsign = "N0CALL"
aprs_igate_enabled = False
aprs_igate_server = "euro.aprs2.net"
aprs_igate_password = ""
# beacon uses the receiver_gps setting, so if you enable this, make sure the location is correct there
aprs_igate_beacon = False
# path to the aprs symbols repository (get it here: https://github.com/hessu/aprs-symbols)
aprs_symbols_path = "/opt/aprs-symbols/png"
# === PSK Reporter setting ===
# enable this if you want to upload all ft8, ft4 etc spots to pskreporter.info
# this also uses the receiver_gps setting from above, so make sure it contains a correct locator
pskreporter_enabled = False
pskreporter_callsign = "N0CALL"
# === Web admin settings ===
# this feature is experimental at the moment. it should not be enabled on shared receivers since it allows remote
# changes to the receiver settings. enable for testing in controlled environment only.
# webadmin_enabled = False

Write Preview
Loading…
Cancel
Save

Powered by TurnKey Linux.