openwebrx-clone/config_webrx.py
2019-09-25 23:12:30 +02:00

291 lines
11 KiB
Python

# -*- coding: utf-8 -*-
"""
config_webrx: configuration options for OpenWebRX
This file is part of OpenWebRX,
an open-source SDR receiver software with a web UI.
Copyright (c) 2013-2015 by Andras Retzler <randras@sdr.hu>
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU Affero General Public License as
published by the Free Software Foundation, either version 3 of the
License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU Affero General Public License for more details.
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/>.
++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
In addition, as a special exception, the copyright holders
state that config_rtl.py and config_webrx.py are not part of the
Corresponding Source defined in GNU AGPL version 3 section 1.
(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,
and use them for running your web service with OpenWebRX.)
"""
# NOTE: you can find additional information about configuring OpenWebRX in the Wiki:
# https://github.com/simonyiszk/openwebrx/wiki
# ==== Server settings ====
web_port = 8073
max_clients = 20
# ==== Web GUI configuration ====
receiver_name = "[Callsign]"
receiver_location = "Budapest, Hungary"
receiver_qra = "JN97ML"
receiver_asl = 200
receiver_ant = "Longwire"
receiver_device = "RTL-SDR"
receiver_admin = "example@example.com"
receiver_gps = (47.000000, 19.000000)
photo_height = 350
photo_title = "Panorama of Budapest from Schönherz Zoltán Dormitory"
photo_desc = """
You can add your own background photo and receiver information.<br />
Receiver is operated by: <a href="mailto:%[RX_ADMIN]">%[RX_ADMIN]</a><br/>
Device: %[RX_DEVICE]<br />
Antenna: %[RX_ANT]<br />
Website: <a href="http://localhost" target="_blank">http://localhost</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
server_hostname = "localhost"
# ==== DSP/RX settings ====
fft_fps = 9
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.
audio_compression = "adpcm" # valid values: "adpcm", "none"
fft_compression = "adpcm" # valid values: "adpcm", "none"
digimodes_enable = True # Decoding digimodes come with higher CPU usage.
digimodes_fft_size = 1024
# 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:
- decrease `samp_rate`,
- set `fft_voverlap_factor` to 0,
- decrease `fft_fps` and `fft_size`,
- limit the number of users by decreasing `max_clients`.
"""
# ==== I/Q sources ====
# (Uncomment the appropriate by removing # characters at the beginning of the corresponding lines.)
#################################################################################################
# Is my SDR hardware supported? #
# Check here: https://github.com/simonyiszk/openwebrx/wiki#guides-for-receiver-hardware-support #
#################################################################################################
# Currently supported types of sdr receivers: "rtl_sdr", "sdrplay", "hackrf", "airspy"
sdrs = {
"rtlsdr": {
"name": "RTL-SDR USB Stick",
"type": "rtl_sdr",
"ppm": 0,
# you can change this if you use an upconverter. formula is:
# shown_center_freq = center_freq + lfo_offset
# "lfo_offset": 0,
"profiles": {
"70cm": {
"name": "70cm Relais",
"center_freq": 438800000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 439275000,
"start_mod": "nfm",
},
"2m": {
"name": "2m komplett",
"center_freq": 145000000,
"rf_gain": 30,
"samp_rate": 2400000,
"start_freq": 145725000,
"start_mod": "nfm",
},
},
},
"sdrplay": {
"name": "SDRPlay RSP2",
"type": "sdrplay",
"ppm": 0,
"profiles": {
"20m": {
"name": "20m",
"center_freq": 14150000,
"rf_gain": 4,
"samp_rate": 500000,
"start_freq": 14070000,
"start_mod": "usb",
"antenna": "Antenna A",
},
"30m": {
"name": "30m",
"center_freq": 10125000,
"rf_gain": 4,
"samp_rate": 250000,
"start_freq": 10142000,
"start_mod": "usb",
},
"40m": {
"name": "40m",
"center_freq": 7100000,
"rf_gain": 4,
"samp_rate": 500000,
"start_freq": 7070000,
"start_mod": "usb",
"antenna": "Antenna A",
},
"80m": {
"name": "80m",
"center_freq": 3650000,
"rf_gain": 4,
"samp_rate": 500000,
"start_freq": 3570000,
"start_mod": "usb",
"antenna": "Antenna A",
},
"49m": {
"name": "49m Broadcast",
"center_freq": 6000000,
"rf_gain": 4,
"samp_rate": 500000,
"start_freq": 6070000,
"start_mod": "am",
"antenna": "Antenna A",
},
},
},
# this one is just here to test feature detection
"test": {"type": "test"},
}
# ==== Misc settings ====
client_audio_buffer_size = 5
# increasing client_audio_buffer_size will:
# - also increase the latency
# - decrease the chance of audio underruns
iq_port_range = [
4950,
4960,
] # TCP port for range 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.
# ==== Color themes ====
# A guide is available to help you set these values: https://github.com/simonyiszk/openwebrx/wiki/Calibrating-waterfall-display-levels
### default theme by teejez:
waterfall_colors = [0x000000FF, 0x0000FFFF, 0x00FFFFFF, 0x00FF00FF, 0xFFFF00FF, 0xFF0000FF, 0xFF00FFFF, 0xFFFFFFFF]
waterfall_min_level = -88 # in dB
waterfall_max_level = -20
waterfall_auto_level_margin = (5, 40)
### old theme by HA7ILM:
# waterfall_colors = "[0x000000ff,0x2e6893ff, 0x69a5d0ff, 0x214b69ff, 0x9dc4e0ff, 0xfff775ff, 0xff8a8aff, 0xb20000ff]"
# waterfall_min_level = -115 #in dB
# waterfall_max_level = 0
# waterfall_auto_level_margin = (20, 30)
##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:
# [waterfall_min_level] = [current_min_power_level] - [waterfall_auto_level_margin[0]]
# [waterfall_max_level] = [current_max_power_level] + [waterfall_auto_level_margin[1]]
#
# ___|____________________________________|____________________________________|____________________________________|___> signal power
# \_waterfall_auto_level_margin[0]_/ |__ current_min_power_level | \_waterfall_auto_level_margin[1]_/
# 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 ===
# Warning! The settings below are very experimental.
csdr_dynamic_bufsize = False # This allows you to change the buffering mode of csdr.
csdr_print_bufsizes = False # This prints the buffer sizes used for csdr processes.
csdr_through = False # Setting this True will print out how much data is going into the DSP chains.
nmux_memory = 50 # in megabytes. This sets the approximate size of the circular buffer used by nmux.
google_maps_api_key = ""
# how long should positions be visible on the map?
# they will start fading out after half of that
# in seconds; default: 2 hours
map_position_retention_time = 2 * 60 * 60
# wsjt decoder queue configuration
# due to the nature of the wsjt operating modes (ft8, ft8, jt9, jt65 and wspr), the data is recorded for a given amount
# of time (6.5 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)
wsjt_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 wsjt services running at the same time
wsjt_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}
temporary_directory = "/tmp"
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"