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Repository Details

Multi-architecture readsb-protobuf container with support for RTLSDR, bladeRF and plutoSDR (x86_64, arm32v7, arm64v8)

sdr-enthusiasts/docker-readsb-protobuf

Docker Image Size (tag) Discord

Mictronics' readsb-protobuf Mode-S/ADSB/TIS decoder for RTLSDR, BladeRF, Modes-Beast and GNS5894 devices, running in a docker container.

This version uses Google's protocol buffer for data storage and exchange with web application. Saves on storage space and bandwidth.

This container also contains InfluxData's Telegraf, and can send flight data and readsb metrics to InfluxDB (if wanted - not started by default).

Support for all supported SDRs is compiled in. Builds and runs on x86_64, arm32v7 and arm64v8 (see below).

This image will configure a software-defined radio (SDR) to receive and decode Mode-S/ADSB/TIS data from aircraft within range, for use with other services such as:

bladeRF & plutoSDR are untested - I don't own bladeRF or plutoSDR hardware (only RTL2832U as outlined above), but support for the devices is compiled in. If you have the hardware and would be willing to test, please open an issue on GitHub.

Note for Users running 32-bit Debian Buster-based OSes on ARM

Please see: Buster-Docker-Fixes!

Table of Contents

Supported tags and respective Dockerfiles

  • latest should always contain the latest released versions of rtl-sdr, bladeRF, libiio, libad9361-iio and readsb. This image is built nightly from the main branch Dockerfile for all supported architectures.
  • latest_nohealthcheck is the same as the latest version above. However, this version has the docker healthcheck removed. This is done for people running platforms (such as Nomad) that don't support manually disabling healthchecks, where healthchecks are not wanted.
  • Specific version and architecture tags are available if required, however these are not regularly updated. It is generally recommended to run latest.

Multi Architecture Support

Currently, this image should pull and run on the following architectures:

  • amd64: Linux x86-64
  • arm32v7, armv7l: ARMv7 32-bit (Odroid HC1/HC2/XU4, RPi 2/3)
  • arm64v8, aarch64: ARMv8 64-bit (RPi 3B+/4)

Prerequisites

Kernel Module Configuration

NOTE: If you used the docker-install.sh script, you can skip this section.

Before we can plug in our RTL-SDR dongle, we need to blacklist the kernel modules for the RTL-SDR USB device from being loaded into the host's kernel and taking ownership of the device.

There are three parts to this.

  1. Blacklist modules from being directly loaded AND blacklist modules from being loaded as a dependency of other modules
  2. Unload any of our blacklisted modules from memory
  3. Updating the initramfs boot image to remove any references to our now blacklisted modules
1. Blacklist Modules

To do this, we will create a blacklist file at /etc/modprobe.d/blacklist-rtlsdr.conf with the following command. While logged in as root, please copy and paste all lines at once, and press enter after to ensure the final line is given allowing it to run.

sudo tee /etc/modprobe.d/blacklist-rtlsdr.conf <<TEXT1
# Blacklist host from loading modules for RTL-SDRs to ensure they
# are left available for the Docker guest.

blacklist dvb_core
blacklist dvb_usb_rtl2832u
blacklist dvb_usb_rtl28xxu
blacklist dvb_usb_v2
blacklist r820t
blacklist rtl2830
blacklist rtl2832
blacklist rtl2832_sdr
blacklist rtl2838
blacklist rtl8192cu
blacklist rtl8xxxu

# This alone will not prevent a module being loaded if it is a
# required or an optional dependency of another module. Some kernel
# modules will attempt to load optional modules on demand, which we
# mitigate here by causing /bin/false to be run instead of the module.
#
# The next time the loading of the module is attempted, the /bin/false
# will be executed instead. This will prevent the module from being
# loaded on-demand. Source: https://access.redhat.com/solutions/41278

install dvb_core /bin/false
install dvb_usb_rtl2832u /bin/false
install dvb_usb_rtl28xxu /bin/false
install dvb_usb_v2 /bin/false
install r820t /bin/false
install rtl2830 /bin/false
install rtl2832 /bin/false
install rtl2832_sdr /bin/false
install rtl2838 /bin/false
install rtl8192cu /bin/false
install rtl8xxxu /bin/false

TEXT1
2. Unload Modules

Next, ensure the modules are unloaded by running the following commands:

sudo modprobe -r rtl2832_sdr
sudo modprobe -r dvb_usb_rtl2832u
sudo modprobe -r dvb_usb_rtl28xxu
sudo modprobe -r dvb_usb_v2
sudo modprobe -r r820t
sudo modprobe -r rtl2830
sudo modprobe -r rtl2832
sudo modprobe -r rtl2838
sudo modprobe -r rtl8192cu
sudo modprobe -r rtl8xxxu
sudo modprobe -r dvb_core
3. Update the Boot Image

Now we need to update our boot image to ensure any references to the modules we've blacklisted are removed

sudo update-initramfs -u

This will take a minute or more depending on the speed of your system, and output lots of status message lines as it goes until it is finished.


Failure to do the steps above will result in the error below being spammed to the readsb container log.

usb_claim_interface error -6
rtlsdr: error opening the RTLSDR device: Device or resource busy

Identifying your SDR's device path

Plug in your USB radio, and run the command lsusb. Find your radio. It'll look something like this:

Bus 001 Device 004: ID 0bda:2832 Realtek Semiconductor Corp. RTL2832U DVB-T

Take note of the USB bus number, and USB device number. In the output above, its 001 and 004 respectively. While the individual device can be passed through (/dev/bus/usb/001/004 in this case), it's more reliable to pass the entire USB bus through, as seen in the examples below.

Up-and-Running with docker run

Start the docker container, passing through the USB device:

docker volume create readsbpb_rrd
docker volume create readsbpb_autogain
docker run \
 -d \
 -it \
 --restart=always \
 --name readsb \
 --hostname readsb \
 --device /dev/bus/usb:/dev/bus/usb \
 -p 8080:8080 \
 -p 30005:30005 \
 -e TZ=<YOUR_TIMEZONE> \
 -e READSB_DCFILTER=true \
 -e READSB_DEVICE_TYPE=rtlsdr \
 -e READSB_FIX=true \
 -e READSB_GAIN=autogain \
 -e READSB_LAT=<YOUR_LATITUDE> \
 -e READSB_LON=<YOUR_LONGITUDE> \
 -e READSB_MODEAC=true \
 -e READSB_RX_LOCATION_ACCURACY=2 \
 -e READSB_STATS_RANGE=true \
 -e READSB_NET_ENABLE=true \
 -v readsbpb_autogain:/run/autogain \
 -v readsbpb_rrd:/run/collectd \
 --tmpfs=/run:exec,size=64M \
 --tmpfs=/var/log:size=32M \
 ghcr.io/sdr-enthusiasts/docker-readsb-protobuf:latest

For example:

docker volume create readsbpb_rrd
docker volume create readsbpb_autogain
docker run \
 -d \
 -it \
 --restart=always \
 --name readsb \
 --hostname readsb \
 --device /dev/bus/usb:/dev/bus/usb \
 -p 8080:8080 \
 -p 30005:30005 \
 -e TZ=Australia/Perth \
 -e READSB_DCFILTER=true \
 -e READSB_DEVICE_TYPE=rtlsdr \
 -e READSB_FIX=true \
 -e READSB_GAIN=autogain \
 -e READSB_LAT=33.33333 \
 -e READSB_LON=-111.11111 \
 -e READSB_MODEAC=true \
 -e READSB_RX_LOCATION_ACCURACY=2 \
 -e READSB_STATS_RANGE=true \
 -e READSB_NET_ENABLE=true \
 -v readsbpb_autogain:/run/autogain \
 -v readsbpb_rrd:/run/collectd \
 --tmpfs=/run:exec,size=64M \
 --tmpfs=/var/log:size=32M \
 ghcr.io/sdr-enthusiasts/docker-readsb-protobuf:latest

Alternatively, you could pass through the entire USB bus with --device /dev/bus/usb:/dev/bus/usb, but please understand the security implications of doing so.

Up-and-Running with Docker Compose

An example docker-compose.yml file is below:

version: '2.0'

volumes:
  readsbpb_rrd:
  readsbpb_autogain:

services:

  readsb:
    image: ghcr.io/sdr-enthusiasts/docker-readsb-protobuf:latest
    tty: true
    container_name: readsb
    hostname: readsb
    restart: always
    devices:
      - /dev/bus/usb:/dev/bus/usb
    ports:
      - 8080:8080
      - 30005:30005
    environment:
      - TZ=Australia/Perth
      - READSB_DCFILTER=true
      - READSB_DEVICE_TYPE=rtlsdr
      - READSB_FIX=true
      - READSB_GAIN=autogain
      - READSB_LAT=-33.33333
      - READSB_LON=111.11111
      - READSB_MODEAC=true
      - READSB_RX_LOCATION_ACCURACY=2
      - READSB_STATS_RANGE=true
      - READSB_NET_ENABLE=true
    volumes:
      - readsbpb_rrd:/run/collectd
      - readsbpb_autogain:/run/autogain
      - /proc/diskstats:/proc/diskstats:ro
    tmpfs:
      - /run/readsb:size=64M
      - /var/log:size=32M

Testing the container

Once running, you can test the container to ensure it is correctly receiving & decoding ADSB traffic by issuing the command:

docker exec -it readsb viewadsb

Which should display a departure-lounge-style screen showing all the aircraft being tracked, for example:

 Hex    Mode  Sqwk  Flight   Alt    Spd  Hdg    Lat      Long   RSSI  Msgs  Ti -
────────────────────────────────────────────────────────────────────────────────
 7C801C S                     8450  256  296                   -28.0    14  1
 7C8148 S                     3900                             -21.5    19  0
 7C7A48 S     1331  VOZ471   28050  468  063  -31.290  117.480 -26.8    48  0
 7C7A4D S     3273  VOZ694   13100  376  077                   -29.1    14  1
 7C7A6E S     4342  YGW       1625  109  175  -32.023  115.853  -5.9    71  0
 7C7A71 S           YGZ        725   64  167  -32.102  115.852 -27.1    26  0
 7C42D1 S                    32000  347  211                   -32.0     4  1
 7C42D5 S                    33000  421  081  -30.955  118.568 -28.7    15  0
 7C42D9 S     4245  NWK1643   1675  173  282  -32.043  115.961 -13.6    60  0
 7C431A S     3617  JTE981   24000  289  012                   -26.7    41  0
 7C1B2D S     3711  VOZ9242  11900  294  209  -31.691  116.118  -9.5    65  0
 7C5343 S           QQD      20000  236  055  -30.633  116.834 -25.5    27  0
 7C6C96 S     1347  JST116   24000  397  354  -30.916  115.873 -17.5    62  0
 7C6C99 S     3253  JST975    2650  210  046  -31.868  115.993  -2.5    70  0
 76CD03 S     1522  SIA214     grnd   0                        -22.5     7  0
 7C4513 S     4220  QJE1808   3925  282  279  -31.851  115.887  -1.9    35  0
 7C4530 S     4003  NYA      21925  229  200  -30.933  116.640 -19.8    58  0
 7C7533 S     3236  XFP       4300  224  266  -32.066  116.124  -6.9    74  0
 7C4D44 S     3730  PJQ      20050  231  199  -31.352  116.466 -20.1    62  0
 7C0559 S     3000  BCB       1000                             -18.4    28  0
 7C0DAA S     1200            2500  146  002  -32.315  115.918 -26.6    48  0
 7C6DD7 S     1025  QFA793   17800  339  199  -31.385  116.306  -8.7    53  0
 8A06F0 S     4131  AWQ544    6125  280  217  -32.182  116.143 -12.6    61  0
 7CF7C4 S           PHRX1A                                     -13.7     8  1
 7CF7C5 S           PHRX1B                                     -13.3     9  1
 7C77F6 S           QFA595     grnd 112  014                   -33.2     2  2

Press CTRL-C to escape this screen.

You should also be able to point your web browser at http://dockerhost:8080/ to view the web interface.

Environment Variables

Container Options

Variable Description Default
DISABLE_PERFORMANCE_GRAPHS Set to any value to disable the performance graphs (and data collection). Unset
DISABLE_WEBAPP Set to any value to disable the container's web server (you may also want to DISABLE_PERFORMANCE_GRAPHS if using this option). Unset
TZ Local timezone in "TZ database name" format. UTC
VERBOSE_LOGGING Set to any value to enable verbose logging for troubleshooting. Unset

readsb General Options

Where the default value is "Unset", readsb's default will be used.

Variable Description Controls which readsb option Default
READSB_AGGRESSIVE Set to any value to enable two-bit CRC error correction --aggressive Unset
READSB_DCFILTER Set to any value to apply a 1Hz DC filter to input data (requires more CPU) --dcfilter Unset
READSB_DEVICE_TYPE If using an SDR, set this to rtlsdr, bladerf, modesbeast, gnshulc or plutosdr depending on the model of your SDR. If not using an SDR, leave un-set. --device-type=<type> Unset
READSB_ENABLE_BIASTEE Set to any value to enable bias tee on supporting interfaces --enable-biastee Unset
READSB_FIX Set to any value to enable CRC single-bit error correction --fix Unset
READSB_FORWARD_MLAT Set this to any value to allow forwarding of received mlat results to output ports. Leave this unset unless you know what you're doing. --forward-mlat Unset
READSB_FREQ Set frequency (in Hz). Typically 1090000000. --freq=<hz> 1090000000
READSB_GAIN Set gain (in dB). Use autogain to have the container determine an appropriate gain, more on this below. --gain=<db> Max gain
READSB_GNSS Set this to any value to show altitudes as GNSS when available --gnss Unset
READSB_LAT Reference/receiver surface latitude --lat=<lat> Unset
READSB_LON Reference/receiver surface longitude --lon=<lon> Unset
READSB_MAX_RANGE Absolute maximum range for position decoding (in nm) --max-range=<dist> 300
READSB_METRIC Set this to any value to use metric units --metric Unset
READSB_MLAT Set this to any value to display raw messages in Beast ASCII mode --mlat Unset
READSB_MODEAC Set this to any value to enable decoding of SSR Modes 3/A & 3/C --modeac Unset
READSB_NO_CRC_CHECK Set this to any value to disable messages with invalid CRC (discouraged) --no-crc-check Unset
READSB_NO_FIX Set this to any value to disable CRC single-bit error correction --no-fix Unset
READSB_NO_MODEAC_AUTO Set this to any value and Mode A/C won't be enabled automatically if requested by a Beast connection --no-modeac-auto Unset
READSB_PREAMBLE_THRESHOLD Preamble threshold, lower means more CPU usage (valid range: 40 - 400) --preamble-threshold=<n> 58
READSB_RX_LOCATION_ACCURACY Accuracy of receiver location in metadata: 0=no location, 1=approximate, 2=exact --rx-location-accuracy=<n> Unset
READSB_STATS_EVERY Number of seconds between showing and resetting stats. --stats-every=<sec> Unset
READSB_STATS_RANGE Set this to any value to collect range statistics for polar plot. --stats-range Unset

readsb Network Options

Where the default value is "Unset", readsb's default will be used.

Variable Description Controls which readsb option Default
READSB_NET_ENABLE Set this to any value to enable networking. --net Unset
READSB_NET_BEAST_REDUCE_INTERVAL BeastReduce position update interval, longer means less data (valid range: 0.000 - 14.999) --net-beast-reduce-interval=<seconds> 0.125
READSB_NET_BEAST_REDUCE_OUT_PORT TCP BeastReduce output listen ports (comma separated) --net-beast-reduce-out-port=<ports> Unset
READSB_NET_BEAST_INPUT_PORT TCP Beast input listen ports --net-bi-port=<ports> 30004,30104
READSB_NET_BEAST_OUTPUT_PORT TCP Beast output listen ports --net-bo-port=<ports> 30005
READSB_NET_BUFFER TCP buffer size 64Kb * (2^n) --net-buffer=<n> 2 (256Kb)
READSB_NET_CONNECTOR See "READSB_NET_CONNECTOR syntax" below. --net-connector=<ip,port,protocol> Unset
READSB_NET_CONNECTOR_DELAY Outbound re-connection delay. --net-connector-delay=<seconds> 30
READSB_NET_HEARTBEAT TCP heartbeat rate in seconds (0 to disable). --net-heartbeat=<rate> 60
READSB_NET_ONLY Set this to any value to enable just networking, no SDR used. --net-only Unset
READSB_NET_RAW_INPUT_PORT TCP raw input listen ports. --net-ri-port=<ports> 30001
READSB_NET_RAW_OUTPUT_INTERVAL TCP output flush interval in seconds (maximum interval between two network writes of accumulated data). --net-ro-interval=<rate> 0.05
READSB_NET_RAW_OUTPUT_PORT TCP raw output listen ports. --net-ro-port=<ports> 30002
READSB_NET_RAW_OUTPUT_SIZE TCP output flush size (maximum amount of internally buffered data before writing to network). --net-ro-size=<size> 1200
READSB_NET_SBS_INPUT_PORT TCP BaseStation input listen ports. --net-sbs-in-port=<ports> Unset
READSB_NET_SBS_OUTPUT_PORT TCP BaseStation output listen ports. --net-sbs-port=<ports> 30003
REASSB_NET_VERBATIM Set this to any value to forward messages unchanged. --net-verbatim Unset
READSB_NET_VRS_PORT TCP VRS JSON output listen ports. --net-vrs-port=<ports> Unset

READSB_NET_CONNECTOR syntax

This variable allows you to configure outgoing connections. The variable takes a semicolon (;) separated list of ip,port,protocol, where:

  • ip is an IP address. Specify an IP/hostname/containername for outgoing connections.
  • port is a TCP port number
  • protocol can be one of the following:
    • beast_out: Beast-format output
    • beast_in: Beast-format input
    • raw_out: Raw output
    • raw_in: Raw input
    • sbs_out: SBS-format output
    • vrs_out: VRS-format JSON output

For example, to pull in MLAT results (so the performance graphs in the web interface show MLAT numbers), you could do the following:

    environment:
    ...
      - READSB_NET_CONNECTOR=piaware,30105,beast_in;adsbx,30105,beast_in;rbfeeder,30105,beast_in
    ...

readsb RTL-SDR Options

Use with READSB_DEVICE_TYPE=rtlsdr.

Where the default value is "Unset", readsb's default will be used.

Variable Description Controls which readsb option Default
READSB_RTLSDR_DEVICE Select device by serial number. --device=<serial> Unset
READSB_RTLSDR_ENABLE_AGC Set this to any value to enable digital AGC (not tuner AGC!) --enable-agc Unset
READSB_RTLSDR_PPM Set oscillator frequency correction in PPM. See section Estimating PPM below --ppm=<correction> Unset

readsb BladeRF Options

Use with READSB_DEVICE_TYPE=bladerf.

Where the default value is "Unset", readsb's default will be used.

Variable Description Controls which readsb option Default
READSB_BLADERF_DEVICE Select device by bladeRF 'device identifier'. --device=<ident> Unset
READSB_BLADERF_BANDWIDTH Set LPF bandwidth ('bypass' to bypass the LPF). --bladerf-bandwidth=<hz> Unset
READSB_BLADERF_DECIMATION Assume FPGA decimates by a factor of N. --bladerf-decimation=<N> Unset
READSB_BLADERF_FPGA Use alternative FPGA bitstream ('' to disable FPGA load). --bladerf-fpga=<path> Unset

readsb Mode-S Beast Options

Use with READSB_DEVICE_TYPE=modesbeast.

Where the default value is "Unset", readsb's default will be used.

Beast binary protocol and hardware handshake are always enabled.

Variable Description Controls which readsb option Default
READSB_BEAST_CRC_OFF Set this to any value to turn OFF CRC checking. --beast-crc-off Unset
READSB_BEAST_DF045_ON Set this to any value to turn ON DF0/4/5 filter. --beast-df045-on Unset
READSB_BEAST_DF1117_ON Set this to any value to turn ON DF11/17-only filter. --beast-df1117-on Unset
READSB_BEAST_FEC_OFF Set this to any value to turn OFF forward error correction. --beast-fec-off Unset
READSB_BEAST_MLAT_OFF Set this to any value to turn OFF MLAT time stamps. --beast-mlat-off Unset
READSB_BEAST_MODEAC Set this to any value to turn ON mode A/C. --beast-modeac Unset
READSB_BEAST_SERIAL Path to Beast serial device. --beast-serial=<path> /dev/ttyUSB0

readsb GNS HULC Options

Use with READSB_DEVICE_TYPE=gnshulc.

Variable Description Controls which readsb option Default
READSB_BEAST_SERIAL Path to Beast serial device. --beast-serial=<path> /dev/ttyUSB0

readsb ADALM-Pluto SDR Options

Use with READSB_DEVICE_TYPE=plutosdr.

Where the default value is "Unset", readsb's default will be used.

Variable Description Controls which readsb option Default
READSB_PLUTO_NETWORK Hostname or IP to create networks context. --pluto-network=<hostname or IP> pluto.local
READSB_PLUTO_URI Create USB context from this URI. (eg. usb:1.2.5) --pluto-uri=<USB uri> Unset

readsb Graphs Options

Where the default value is "Unset", readsb's default will be used.

Variable Description Controls which readsb option Default
READSBRRD_STEP Interval in seconds to feed data into RRD files. 60
READSB_GRAPH_SIZE Set graph size, possible values: small, default, large, huge, custom. default
READSB_GRAPH_ALL_LARGE Make the small graphs as large as the big ones by setting to yes. no
READSB_GRAPH_FONT_SIZE Font size (relative to graph size). 10.0
READSB_GRAPH_MAX_MESSAGES_LINE Set to 1 to draw a reference line at the maximum message rate. 0
READSB_GRAPH_LARGE_WIDTH Defines the width of the larger graphs. 1096
READSB_GRAPH_LARGE_HEIGHT Defines the height of the larger graphs. 235
READSB_GRAPH_SMALL_WIDTH Defines the width of the smaller graphs. 619
READSB_GRAPH_SMALL_HEIGHT Defines the height of the smaller graphs. 324

Auto-Gain Options

These variables control the auto-gain system (explained further below). These should rarely need changing from the defaults.

Variable Description Default
AUTOGAIN_INITIAL_PERIOD How long each gain level should be measured during auto-gain initialisation (ie: "roughing in"), in seconds. 7200 (2 hours)
AUTOGAIN_INITIAL_MSGS_ACCEPTED How many locally accepted messages should be received per gain level during auto-gain initialisaion to ensure accurate measurement. 1000000
AUTOGAIN_FINETUNE_PERIOD How long each gain level should be measured during auto-gain fine-tuning, in seconds. 604800 (7 days)
AUTOGAIN_FINETUNE_MSGS_ACCEPTED How many locally accepted messages should be received per gain level during auto-gain fine-tuning to ensure accurate measurement. 7000000
AUTOGAIN_FINISHED_PERIOD How long between the completion of fine-tuning (and ultimetly setting a preferred gain), and re-running the entire process. 31536000 (1 year)
AUTOGAIN_MAX_GAIN_VALUE The maximum gain setting in dB that will be used by auto-gain. 49.6 (max supported by readsb)
AUTOGAIN_MIN_GAIN_VALUE The minimum gain setting in dB that will be used by auto-gain. 0.0 (min supported by readsb)
AUTOGAIN_PERCENT_STRONG_MESSAGES_MAX The maximum percentage of "strong messages" auto-gain will aim for. 10.0
AUTOGAIN_PERCENT_STRONG_MESSAGES_MIN The minimum percentage of "strong messages" auto-gain will aim for. 0.5
AUTOGAIN_SERVICE_PERIOD How often the auto-gain system will check results and perform actions, in seconds 900

InfluxDB Options

These variables control the sending of flight data and readsb metrics to InfluxDB (via a built-in instance of Telegraf).

Variable Description Default
INFLUXDBURL The full HTTP URL for your InfluxDB instance. Required for both InfluxDB v1 and v2. Unset
INFLUXDBUSERNAME If using authentication, a username for your InfluxDB instance. If not using authentication, leave unset. Not required for InfluxDB v2. Unset
INFLUXDBPASSWORD If using authentication, a password for your InfluxDB instance. If not using authentication, leave unset. Not required for InfluxDB v2. Unset
INFLUXDB_V2 Set to a non empty value to enable InfluxDB V2 output. Unset
INFLUXDB_V2_BUCKET Required if INFLUXDB_V2 is set, bucket must already exist in your InfluxDB v2 instance. Unset
INFLUXDB_V2_ORG Required if INFLUXDB_V2 is set. Unset
INFLUXDB_V2_TOKEN Required if INFLUXDB_V2 is set. Unset
INFLUXDB_SKIP_AIRCRAFT Set to any value to skip publishing aircraft data to InfluxDB to minimize bandwidth and database size. Unset

Prometheus Options

These variables control exposing flight data and readsb metrics to Prometheus (via a built-in instance of Telegraf).

Variable Description Default
ENABLE_PROMETHEUS Set to any string to enable Prometheus support Unset
PROMETHEUSPORT The port that the prometheus client will listen on 9273
PROMETHEUSPATH The path that the prometheus client will publish metrics on /metrics

Ports

Port Details
8080/tcp readsb web interface

In addition to the ports listed above, depending on your readsb configuration the container may also be listening on other ports that you'll need to map through (if external connectivity is required).

Some common ports are as follows (which may or may not be in use depending on your configuration):

Port Details
30001/tcp Raw protocol input
30002/tcp Raw protocol output
30003/tcp SBS/Basestation protocol output
30004/tcp Beast protocol input
30005/tcp Beast protocol output
30104/tcp Beast protocol input

Paths & Volumes

Path (inside container) Details
/run/readsb readsb protobuf file storage. Not necessarily required to be mapped to persistant storage.
/run/collectd collectd RRD file storage used by readsb's "performance graphs" in the web interface. Map to persistant storage if you use this feature.
/run/autogain Map this to persistant storage if you set READSB_GAIN=autogain

Auto-Gain system

An automatic gain adjustment system is included in this container, and can be activated by setting the environment variable READSB_GAIN to autogain. You should also map /run/autogain to persistant storage, otherwise the auto-gain system will start over each time the container is restarted.

Why is this written in bash? Because I wanted to keep the container size down and not have to install an interpreter like python. I don't know C/Go/Perl or any other languages.

Auto-gain will take several weeks to initially (over the period of a week or so) work out feasible maximum and minimum gain levels for your environment. It will then perform a fine-tune process to find the optimal gain level.

During each process, gain levels are ranked as follows:

  • The range achievable by each gain level
  • The signal-to-noise ratio of the receiver

The ranking process is done by sorting the gain levels for each statistic from worst to best, then awarding points. 0 points are awarded for the worst gain level, 1 point for the next gain level all the way up to several points for the best gain level (total number of points is the number of gain levels tested). The number of points for each gain level is totalled, and the optimal gain level is the level with the largest number of points. Any gain level with a percentage of "strong signals" outside of AUTOGAIN_PERCENT_STRONG_MESSAGES_MAX and AUTOGAIN_PERCENT_STRONG_MESSAGES_MIN is discarded.

Using this method, auto-gain tried to achieve the best balance of range, tracks and signal-to-noise ratio, whilst ensuring an appropriate number of "strong signals".

The auto-gain system will work as follows:

Initialisation Stage

In the initialisation process:

  1. readsb is set to maximum gain (AUTOGAIN_MAX_GAIN_VALUE).
  2. Results are collected up to AUTOGAIN_INITIAL_PERIOD (up to 2 hours by default).
  3. Check to ensure at least AUTOGAIN_INITIAL_MSGS_ACCEPTED messages have been locally accepted (1,000,000 by default). If not, continue collecting data for up to 24 hours. This combination of time and number of messages ensures we have enough data to make a valid initial assessment of each gain level.
  4. Gain level is lowered by one level.
  5. Gain levels are reviewed from lowest to highest gain level. If there have been gain levels resulting in a percentage of strong messages between AUTOGAIN_PERCENT_STRONG_MESSAGES_MAX and AUTOGAIN_PERCENT_STRONG_MESSAGES_MIN, and there have been three consecutive gain levels above AUTOGAIN_PERCENT_STRONG_MESSAGES_MAX, auto-gain lowers the maximum gain level.
  6. Gain levels are reviewed from highest to lowest gain level. If there have been gain levels resulting in a percentage of strong messages between AUTOGAIN_PERCENT_STRONG_MESSAGES_MAX and AUTOGAIN_PERCENT_STRONG_MESSAGES_MIN, and there have been three consecutive gain levels below AUTOGAIN_PERCENT_STRONG_MESSAGES_MIN, auto-gain discontinues testing gain levels.

Auto-gain then moves onto the fine-tuning stage.

Fine-Tuning Stage

In the fine-tuning process:

  1. readsb is set to maximum gain level chosen at the end of the initialisation process.
  2. Results are collected up to AUTOGAIN_FINETUNE_PERIOD (7 days by default).
  3. Check to ensure at least AUTOGAIN_FINETUNE_MSGS_ACCEPTED messages have been locally accepted (7,000,000 by default). If not, continue collecting data for up to 48 hours. This combination of time and number of messages ensures we have enough data to make an accurate assessment of each gain level, and by using 7 days this ensures any peaks/troughs in data due to quiet/busy days of the week do not skew results.
  4. Gain level is lowered by one level until the minimum gain level chosen at the end of the initialisation process is reached.

At this point, all of the tested gain levels are ranked based on the criterea discussed above.

The gain level with the most points is chosen, and readsb is set to this gain level.

Auto-gain then moves onto the finished stage.

Finished Stage

In the finished stage, auto-gain does nothing (as readsb is operating at optimal gain) for AUTOGAIN_FINISHED_PERIOD (1 year by default). After this time, auto-gain reverts to the initialisation stage and the entire process is completed again. This makes sure your configuration is always running at the optimal gain level as your RTLSDR ages.

State/Log/Stats Files

All files for auto-gain are located at /run/autogain within the container. They should not be modified by hand.

Forcing auto-gain to re-run from scratch

Run docker exec <container_name> rm /run/autogain/* to remove all existing auto-gain state data. Restart the container and auto-gain will detect this and re-start at initialisation stage.

Advanced Usage: Creating an MLAT Hub

There may be reasons you wish to use readsb to combine MLAT feeds from different collectors, to feed into visualisation tools (eg: mikenye/tar1090) or data collectors (eg: mikenye/adsb-to-influxdb).

To do this, you can create a second container to act as an MLAT hub.

Here are example service definitions (from a docker-compose.yml file) for readsb, mlathub, adsb2influxdb and tar1090.

...
  readsb:
    image: ghcr.io/sdr-enthusiasts/docker-readsb-protobuf:latest
    tty: true
    container_name: readsb
    hostname: readsb
    restart: always
    devices:
      - /dev/bus/usb:/dev/bus/usb
    ports:
      - 8079:8080
      - 30003:30003
      - 30005:30005
    networks:
      - adsbnet
    environment:
      - TZ=Australia/Perth
      - READSB_DCFILTER=true
      - READSB_DEVICE_TYPE=rtlsdr
      - READSB_FIX=true
      - READSB_GAIN=autogain
      - READSB_LAT=-33.33333
      - READSB_LON=111.11111
      - READSB_MAX_RANGE=600
      - READSB_MODEAC=true
      - READSB_RX_LOCATION_ACCURACY=2
      - READSB_STATS_RANGE=true
      - READSB_NET_ENABLE=true
      - READSB_NET_CONNECTOR=mlathub,30105,beast_in
    volumes:
      - readsbpb_rrd:/run/collectd
      - readsbpb_autogain:/run/autogain
    tmpfs:
      - /run/readsb:size=64M
      - /var/log:size=32M

  mlathub:
    image: ghcr.io/sdr-enthusiasts/docker-readsb-protobuf:latest
    tty: true
    container_name: mlathub
    hostname: mlathub
    restart: always
    ports:
      - 30105:30105
    networks:
      - adsbnet
    environment:
      - TZ=Australia/Perth
      - DISABLE_PERFORMANCE_GRAPHS=true
      - DISABLE_WEBAPP=true
      - READSB_NET_ENABLE=true
      - READSB_NET_ONLY=true
      - READSB_FORWARD_MLAT=true
      - READSB_NET_CONNECTOR=piaware,30105,beast_in;adsbx,30105,beast_in;rbfeeder,30105,beast_in
      - READSB_NET_BEAST_OUTPUT_PORT=30105

  adsb2influxdb:
    image: mikenye/adsb-to-influxdb:latest
    tty: true
    container_name: adsb2influxdb
    restart: always
    environment:
      - TZ=Australia/Perth
      - INFLUXDBURL=http://influxdb:8086
      - ADSBHOST=readsb
      - MLATHOST=mlathub
    networks:
      - adsbnet

  tar1090:
    image: mikenye/tar1090:latest
    tty: true
    container_name: tar1090
    restart: always
    depends_on:
      - readsb
    environment:
      - TZ=Australia/Perth
      - BEASTHOST=readsb
      - MLATHOST=mlathub
      - LAT=-33.33333
      - LONG=111.11111
    volumes:
      - "tar1090_heatmap:/var/globe_history"
    tmpfs:
      - /run:exec,size=64M
      - /var/log:size=32M
    networks:
      - adsbnet
    ports:
      - 8078:80

In this example:

  • readsb reads and demodulates the ADSB data from the RTLSDR.
  • Other services (such as adsbx, piaware and rbfeeder - not shown) pull ADSB data from readsb, perform multilateration, and have their resulting MLAT data published on TCP port 30105.
  • mlathub connects to the services providing MLAT results (via READSB_NET_CONNECTOR), and combines them into a single feed, available on TCP port 30105 (via READSB_NET_BEAST_OUTPUT_PORT=30105).
  • readsb pulls these MLAT results (via a READSB_NET_CONNECTOR) so MLAT results show up in its webapp. It is important to note that MLAT results are NOT fed to feeders, which is the desired approach.
  • adsb2influxdb pulls these MLAT results (via MLATHOST) so MLAT metrics are sent to InfluxDB.
  • tar1090 pulls these MLAT results (via MLATHOST) so MLAT positions show up in tar1090's web interface.

You must make absolutely certain that READSB_FORWARD_MLAT is NOT set on your main readsb instance! This is why we perform the MLAT hub functionality in a separate instance of readsb. You do not want to cross-contaminate MLAT results between feeders. Doing so will almost certainly result in your MLAT results being rejected, and/or may end up getting you ignored/banned from feeding services.

PlutoSDR Support

If using PlutoSDR, you will need to configure a host entry for pluto.local.

If using docker run, you can add the command line argument --add-host pluto.local:<IP_OF_PLUTO_HOST>.

If using docker compose, you can add the following to the readsb: service definition:

    extra_hosts:
      - "pluto.local:<IP_OF_PLUTO_HOST>"

Replace <IP_OF_PLUTO_HOST> with the IP address of your PlutoSDR host.

Grafana Dashboard

If you're using INFLUXDBURL and pushing metrics into InfluxDB, I've put together an example Grafana dashboard, which can be found here:

https://grafana.com/grafana/dashboards/13168

InfluxDB Schema

If INFLUXDBURL is set, an instance of Telegraf will be started within the container, and metrics will be written to the InfluxDB.

The database readsb will be created if it does not exist.

Within this database are the following measurements:

aircraft Measurement

Tags and fields used for this measurement should match Virtual Radar Server's JSON response ("the new way").

Tag Key Type Description
Call String The aircraft's callsign.
Gnd Boolean True if the aircraft is on the ground.
Icao String The ICAO of the aircraft.
Mlat Boolean True if the latitude and longitude appear to have been calculated by an MLAT server and were not transmitted by the aircraft.
SpdTyp Number The type of speed that Spd represents. Only used with raw feeds. 0/missing = ground speed, 1 = ground speed reversing, 2 = indicated air speed, 3 = true air speed.
Sqk Number The squawk as a decimal number (e.g. a squawk of 7654 is passed as 7654, not 4012).
Tisb Boolean True if the last message received for the aircraft was from a TIS-B source.
TrkH Boolean True if Trak is the aircraft's heading, false if it's the ground track. Default to ground track until told otherwise.
VsiT Number 0 = vertical speed is barometric, 1 = vertical speed is geometric. Default to barometric until told otherwise.
host String The hostname of the container.
Field Key Type Description
Alt float The altitude in feet at standard pressure.
Cmsgs float The count of messages received for the aircraft.
GAlt float The altitude adjusted for local air pressure, should be roughly the height above mean sea level.
InHg float The air pressure in inches of mercury that was used to calculate the AMSL altitude from the standard pressure altitude.
Lat float The aircraft's latitude over the ground.
Long float The aircraft's longitude over the ground.
PosTime float The time (at UTC in JavaScript ticks) that the position was last reported by the aircraft.
Sig float The signal level for the last message received from the aircraft, as reported by the receiver. Not all receivers pass signal levels. The value's units are receiver-dependent.
Spd float The ground speed in knots.
TAlt float The target altitude, in feet, set on the autopilot / FMS etc.
TTrk float The track or heading currently set on the aircraft's autopilot or FMS.
Trak float Aircraft's track angle across the ground clockwise from 0Β° north.
Trt float Transponder type - 0=Unknown, 1=Mode-S, 2=ADS-B (unknown version), 3=ADS-B 0, 4=ADS-B 1, 5=ADS-B 2.
Vsi float Vertical speed in feet per minute.

autogain Measurement

Tag Key Type Description
host String The hostname of the container.
Field Key Type Description
autogain_current_value float The current gain level as set by autogain.
autogain_max_value float The maximum gain level as set by autogain.
autogain_min_value float The minimum gain level as set by autogain.
autogain_pct_strong_messages_max float The maximum percentage of strong messages.
autogain_pct_strong_messages_min float The minimum percentage of strong messages.

polar_range Measurement

Tag Key Type Description
bearing Number The bearing value is between 00 and 71. Each bearing represents 5Β° on the compass, with 00 as North.
host String The hostname of the container.
Field Key Type Description
range float The range (in metres) at a specific bearing.

readsb Measurement

Tag Key Type Description
host String The hostname of the container.

Field keys should be as-per the StatisticEntry message schema from readsb.proto.

Field Key Type Description
cpr_airborne float Total number of airborne CPR messages received
cpr_global_bad float Global positions that were rejected because they were inconsistent
cpr_global_ok float Global positions successfuly derived
cpr_global_range float Global positions that were rejected because they exceeded the receiver max range
cpr_global_skipped float Global position attempts skipped because we did not have the right data (e.g. even/odd messages crossed a zone boundary)
cpr_global_speed float Global positions that were rejected because they failed the inter-position speed check
cpr_local_aircraft_relative float Local positions found relative to a previous aircraft position
cpr_local_ok float Local (relative) positions successfully found
cpr_local_range float Local positions not used because they exceeded the receiver max range or fell into the ambiguous part of the receiver range
cpr_local_skipped float Local (relative) positions not used because we did not have the right data
cpr_local_speed float Local positions not used because they failed the inter-position speed check
cpr_surface float Total number of surface CPR messages received
cpu_background float Milliseconds spent doing network I/O, processing received network messages, and periodic tasks.
cpu_demod float Milliseconds spent doing demodulation and decoding in response to data from a SDR dongle.
cpu_reader float Milliseconds spent reading sample data over USB from a SDR dongle.
local_accepted float The number of valid Mode S messages accepted from a local SDR with N-bit errors corrected.
local_modeac float Number of Mode A / C messages decoded.
local_modes float Number of Mode S preambles received. This is not the number of valid messages!
local_noise float Calculated receiver noise floor level.
local_peak_signal float Peak signal power of a successfully received message, in dbFS; always negative.
local_samples_dropped float Number of sample blocks dropped before processing. A nonzero value means CPU overload.
local_samples_processed float Number of sample blocks processed.
local_signal float Mean signal power of successfully received messages, in dbFS; always negative.
local_strong_signals float Number of messages received that had a signal power above -3dBFS.
local_unknown_icao float Number of Mode S messages which looked like they might be valid but we didn't recognize the ICAO address and it was one of the message types where we can't be sure it's valid in this case.
max_distance_in_metres float Maximum range in metres
max_distance_in_nautical_miles float Maximum range in nautical miles
messages float Total number of messages accepted by readsb from any source
remote_accepted float Number of valid Mode S messages accepted over the network with N-bit errors corrected.
remote_modeac float Number of Mode A / C messages received.
remote_modes float Number of Mode S messages received.
tracks_mlat_position float Tracks consisting of a position derived from MLAT
tracks_new float Total tracks (aircrafts) created. Each track represents a unique aircraft and persists for up to 5 minutes.
tracks_single_message float Tracks consisting of only a single message. These are usually due to message decoding errors that produce a bad aircraft address.
tracks_with_position float Tracks consisting of a position.

Estimating PPM

Every RTL-SDR dongle will have a small frequency error as it is cheaply mass produced and not tested for accuracy. This frequency error is linear across the spectrum, and can be adjusted in most SDR programs by entering a PPM (parts per million) offset value. This image allows you to adjust the PPM figure using the READSB_RTLSDR_PPM environment variable.

To estimate your RTL-SDR's PPM, you can:

  • Stop the readsb container if it is running (freeing up the RTL-SDR for use)
  • Running docker run --rm -it --entrypoint /scripts/estimate_rtlsdr_ppm.sh --device /dev/bus/usb ghcr.io/sdr-enthusiasts/docker-readsb-protobuf:latest. This takes about 30 minutes.
  • Updating your readsb container with the suggested PPM value

Example output is as follows:

$ docker run --rm -it --entrypoint /scripts/estimate_rtlsdr_ppm.sh --device /dev/bus/usb ghcr.io/sdr-enthusiasts/docker-readsb-protobuf:latest

Running rtl_test -p for 30 minutes

Found 1 device(s):
  0:  Realtek, RTL2832U, SN: 00001000

Using device 0: Generic RTL2832U
Found Rafael Micro R820T tuner
Supported gain values (29): 0.0 0.9 1.4 2.7 3.7 7.7 8.7 12.5 14.4 15.7 16.6 19.7 20.7 22.9 25.4 28.0 29.7 32.8 33.8 36.4 37.2 38.6 40.2 42.1 43.4 43.9 44.5 48.0 49.6
[R82XX] PLL not locked!
Sampling at 2048000 S/s.
Reporting PPM error measurement every 10 seconds...
Press ^C after a few minutes.
Reading samples in async mode...
real sample rate: 2048129 current PPM: 63 cumulative PPM: 63
real sample rate: 2047957 current PPM: -21 cumulative PPM: 20
real sample rate: 2048125 current PPM: 61 cumulative PPM: 34
...<lines removed for brevity>...
real sample rate: 2047998 current PPM: -1 cumulative PPM: 1
real sample rate: 2047992 current PPM: -3 cumulative PPM: 0
real sample rate: 2048005 current PPM: 3 cumulative PPM: 1
Signal caught, exiting!

User cancel, exiting...
Samples per million lost (minimum): 0

Results:

PPM setting of: -2, Score of: 1
PPM setting of: 10, Score of: 1
PPM setting of: 20, Score of: 1
PPM setting of: 34, Score of: 1
PPM setting of: 6, Score of: 1
PPM setting of: 63, Score of: 1
PPM setting of: 8, Score of: 1
PPM setting of: 9, Score of: 1
PPM setting of: -1, Score of: 2
PPM setting of: 3, Score of: 4
PPM setting of: 4, Score of: 4
PPM setting of: 5, Score of: 4
PPM setting of: 7, Score of: 4
PPM setting of: 2, Score of: 8
PPM setting of: 0, Score of: 51
PPM setting of: 1, Score of: 94

Estimated optimum PPM setting: 1

In this instance, the RTL-SDR has a PPM of 1, so we would set the environment variable READSB_RTLSDR_PPM=1.

Getting help

Please feel free to open an issue on the project's GitHub.

I also have a Discord channel, feel free to join and converse.

Changelog

See the project's commit history.

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