1
0
Fork 0
mirror of https://github.com/sdr-enthusiasts/docker-adsb-ultrafeeder.git synced 2024-11-24 23:00:11 +00:00
ADSB-Ultrafeeder is an all-in-one ADSB container with readsb, tar1090, graphs1090, autogain, multi-feeder, and mlat-hub built in
Find a file
2023-04-27 11:04:03 -04:00
.github fix 2023-04-27 11:04:03 -04:00
.vscode add telegraf image tag 2023-04-27 10:56:09 -04:00
rootfs Merge branch 'main' into dev 2023-04-19 15:27:31 -04:00
.DS_Store initial commit 2023-03-21 20:56:02 +01:00
.env updated doc 2023-04-18 20:49:18 -04:00
.gitattributes Initial commit 2023-03-21 10:27:29 +01:00
.hadolint.yaml intermediate commit 2023-04-18 14:16:23 -04:00
.markdownlint.json intermediate commit 2023-04-18 14:16:23 -04:00
buildnow.sh update build script 2023-03-28 16:03:29 -04:00
docker-compose.yml add - TAR1090_USEROUTEAPI=true to sample docker-compose.yml 2023-04-20 23:50:32 -04:00
Dockerfile bug fix 2023-03-28 16:06:11 -04:00
LICENSE Initial commit 2023-03-21 10:27:29 +01:00
README-grafana.md Update README-grafana.md 2023-04-24 22:44:49 -04:00
README.md We need alt to be above sea level 2023-04-22 22:40:48 +02:00

sdr-enthusiasts/docker-adsb-ultrafeeder

adsb-ultrafeeder is a ADS-B data collector container that can be used to:

  • retrieve ADS-B data from your SDR or other device
  • display it on a local map, including options to show tracks, heatmaps, and system performance graphs
  • forward the data to one or more aggregators using BEAST/BEAST-REDUCE/BEAST-REDUCE-PLUS format
  • send MLAT data to these aggregators
  • receive and consolidate MLAT results data (built-in mlathub)
  • Interface with external visualization tools such as Grafana using statistics data available in InfluxDB and Prometheus format

In order to accomplish this, the container makes use of the following underlying technologies:

It builds and runs on linux/amd64, linux/arm/v7 (linux/armhf) and linux/arm64 architectures.

ultrafeeder container architecture

Up-and-Running Quickly with docker-compose

  • An example docker-compose.yml file can be found in this repository.
  • The accompanying environment variable values are defined in the .env file in this repository

Once you have installed Docker, you can follow these lines of code to get up and running in very little time:

sudo mkdir -p -m 777 /opt/adsb
cd /opt/adsb
wget https://raw.githubusercontent.com/sdr-enthusiasts/docker-adsb-ultrafeeder/main/docker-compose.yml
wget https://raw.githubusercontent.com/sdr-enthusiasts/docker-adsb-ultrafeeder/main/.env

Then edit the docker-compose.yml and .env files and make any changes as needed. Please configure ALL variables in .env:

nano docker-compose.yml
nano .env

Finally, bring up the stack. This may take a minute as it will automatically download the container and start it up:

docker compose up -d

Ports

Some common ports are as follows (which may or may not be in use depending on your configuration). You can override the port mappings with the parameters shown in the Optional Networking Parameters section.

The general principle behind the port numbering, is:

  • 30xxx ports are connected to the main instance readsb that decodes and processes the SDR data
  • 31xxx ports are connected to the MLAT Hub
  • 92xx ports are for Prometheus statistics output
  • 80 contains the Tar1090 web interface
Port Details
30001/tcp Raw protocol input
30002/tcp Raw protocol output
30003/tcp SBS/Basestation protocol output
32006/tcp SBS/Basestation protocol input
30004/tcp
30104/tcp
Beast protocol input
30005/tcp Beast protocol output
30006/tcp Beast reduce protocol output
30047/tcp Json position output
31003/tcp MLATHUB SBS/Basestation protocol output
31004/tcp MLATHUB Beast protocol input
31005/tcp MLATHUB Beast protocol output
31006/tcp MLATHUB Beast-reduce protocol output
9273/tcp Prometheus web interface with data from readsb
9274/tcp Prometheus web interface with data from Telegraf
80/tcp Tar1090 (map) web interface

Any of these ports can be made available to the host system by using the ports: directive in your docker-compose.yml. The container's web interface is rendered to port 80 in the container. This can me mapped to a port on the host using the docker-compose ports directive. In the example docker-compose.yml file, the container's Tar1090 interface is mapped to 8080 on the host system, and ports 9273-9274 are exposed as-is:

    ports:
      - 8080:80               # to expose the web interface
      - 9273-9274:9273-9274   # to expose the statistics interface to Prometheus

Json position output:

  • outputs an aircraft object for every new position received for an aircraft if the --json-trace-interval has elapsed for that aircraft
  • to make it output every received position, set READSB_JSON_TRACE_INTERVAL to 0.1
  • each json object will be on a new line
  • https://github.com/wiedehopf/readsb/blob/dev/README-json.md

Aircraft.json:

Runtime Environment Variables

The sections below describe how to configure each part of the container functionality. Each section describes what's needed to come up with a minimally viable configuration, followed by additional / optional parameters that can also be set.

Note:

  • to enable a parameter, you can set it to any of 1, true, on, enabled, enable, yes, or y. In the table below, we'll simply use true for convenience.
  • to disable a parameter, you can set it to anything else or simply leave it undefined.

General Configuration

You need to make sure that the USB device can be accessed by the container. The best way to do so, is by adding the following to your docker-compose.yml file:

    device_cgroup_rules:
      - 'c 189:* rwm'
...
    volumes:
      - /dev:/dev:ro

The advantage of doing this (over simply adding a device: directive pointing at the USB port) is that the construction above will automatically recover if you "hot plug" your dongle. ⚠️This feature requires a recent version of docker-compose (version >=2.3). Make sure your system is up to date if dongles are not found. ⚠️

Basic Ultrafeeder Parameters

Mandatory Parameters

The following parameters must be set (mandatory) for the container to function:

Environment Variable Purpose Default
LAT or READSB_LAT The latitude of your antenna
LONG or READSB_LON The longitude of your antenna
ALT or READSB_ALT The altitude of your antenna above sea level. For example, 15m or 45ft
TZ Your local timezone in TZ-database-name format
Optional Parameters
Variable Description Controls which readsb option Default
ENABLE_TIMELAPSE1090 Optional / Legacy. Set to true to enable timelapse1090. Once enabled, can be accessed via http://dockerhost:port/timelapse/. Unset
READSB_EXTRA_ARGS Optional, allows to specify extra parameters for readsb Unset
READSB_DEBUG Optional, used to set debug mode. n: network, P: CPR, S: speed check Unset
S6_SERVICES_GRACETIME Optional, set to 30000 when saving traces / globe_history 3000
READSB_MAX_RANGE Optional. Maximum range (in nautical miles). 300
READSB_ENABLE_BIASTEE Set to true to enable bias tee on supporting interfaces Unset
READSB_RX_LOCATION_ACCURACY Accuracy of receiver location in metadata: 0=no location, 1=approximate, 2=exact --rx-location-accuracy=<n> 2
READSB_HEATMAP_INTERVAL Per plane interval for heatmap and replay (if you want to lower this, also lower json-trace-interval to this or a lower value) --heatmap=<sec> 15
READSB_MAX_RANGE Absolute maximum range for position decoding (in nm) --max-range=<dist> 300
READSB_STATS_EVERY Number of seconds between showing and resetting stats. --stats-every=<sec> Unset
READSB_STATS_RANGE Set this to true to collect range statistics for polar plot. --stats-range Unset
READSB_RANGE_OUTLINE_HOURS Change which past timeframe the range outline is based on --range-outline-hours 24
READSB_EXTRA_ARGS Optional, allows to specify extra parameters for readsb Unset
S6_SERVICES_GRACETIME Optional, set to 30000 when saving traces / globe_history 3000
LOGLEVEL verbose (all messages), error (errors only), none (minimal) verbose

READSB_EXTRA_ARGS just passes arguments to the commandline, you can check this file for more options for wiedehopf's readsb fork: https://github.com/wiedehopf/readsb/blob/dev/help.h

Getting ADSB data to the Ultrafeeder

There are two ways to provide ADSB data to the Ultrafeeder:

  • provide the container with access to a SDR or other hardware device that collects ADSB data
  • allow the container to connect to a ADSB data source in Beast, Raw, or SBS format

These methods are not mutually exclusive - you can use both at the same time if you want.

Connecting to a SDR or other hardware device

If you want to connect your SDR to the container, here's how to do that:

Mandatory parameters
Variable Description Controls which readsb option Default
READSB_DEVICE_TYPE If using an SDR, set this to rtlsdr, modesbeast, gnshulc depending on the model of your SDR. If not using an SDR, leave un-set. --device-type=<type> Unset
READSB_RTLSDR_DEVICE Select device by serial number. --device=<serial> Unset
READSB_BEAST_SERIAL only when type modesbeast or gnshulc is used: Path to Beast serial device. --beast-serial=<path> /dev/ttyUSB0
Optional/Additional Parameters
Variable Description Controls which readsb option Default
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_RTLSDR_PPM Set oscillator frequency correction in PPM. See Estimating PPM --ppm=<correction> Unset
AutoGain for RTLSDR Devices

If you have set READSB_GAIN=autogain, then the system will take signal strength measurements to determine the optimal gain. The AutoGain functionality is based on a (slightly) modified version of Wiedehopf's AutoGain. AutoGain will only work with rtlsdr style receivers.

There are 2 distinct periods in which the container will attempt to figure out the gain:

  • The initial period of 2 hours, in which an adjustment is done every 5 minutes
  • The subsequent period, in which an adjustment is done once every day

Please note that in order for the initial period to complete, the container must run for 90 minutes without restarting.

When taking measurements, if the percentage of "strong signals" (i.e., ADSB messages with RSSI > 3 dB) is larger than 6%, AutoGain will reduce the receiver's gain by 1 setting. Similarly, if the percentage of strong signals is smaller than 2.5%, AutoGain will increment the receiver's gain by 1 setting. When AutoGain changes the gain value, the readsb component of the container will restart. This may show as a disconnect / reconnected in container logs.

We recommend running the initial period during times when there are a lot of planes overhead, so the system will get a good initial view of what signals look like when traffic is at its peak for your location. If you forgot to do this for any reason, feel free to give the AutoGain reset command (see below) during flights busy hour.

Although not recommended, you can change the measurement intervals and low/high cutoffs with these parameters:

Environment Variable Purpose Default
READSB_AUTOGAIN_INITIAL_TIMEPERIOD How long the Initial Time Period should last (in seconds) 7200
READSB_AUTOGAIN_INITIAL_INTERVAL The measurement interval to optimize gain during the initial period of 90 minutes (in seconds) 300
READSB_AUTOGAIN_SUBSEQUENT_INTERVAL The measurement interval to optimize gain during the subsequent period (in seconds) 86400
READSB_AUTOGAIN_LOW_PCT If the percentage of "strong signals" (stronger than 3dBFS RSSI) is below this number, gain will be increased 2.5
READSB_AUTOGAIN_HIGH_PCT If the percentage of "strong signals" (stronger than 3dBFS RSSI) is above this number, gain will be decreased 6.0

If you need to reset AutoGain and start over determining the gain, you can do so with this command:

docker exec -it ultrafeeder /usr/local/bin/autogain1090 reset

Connecting to external ADSB data sources

In addition to (or instead of) connecting to a SDR or hardware device to get ADSB data, the container also supports ingesting data from a TCP port. Here are some parameters that you need to configure if you want to make this happen:

All-in-One Configuration using ULTRAFEEDER_CONFIG

ULTRAFEEDER_CONFIG is a new parameter that can be used instead of separately defining READSB_NET_CONNECTOR, MLAT_NET_CONNECTOR, MLATHUB_NET_CONNECTOR/MLATHUB_CONFIG. These legacy parameters will still work; however, we wanted to provide a single parameter that enables configuration of incoming and outgoing ADSB data, MLAT-client data, and MLATHUB data.

Note that ULTRAFEEDER_CONFIG and ULTRAFEEDER_NET_CONNECTOR can be used interchangeably; in this documentation, we'll use ULTRAFEEDER_CONFIG as an example.

ULTRAFEEDER_CONFIG syntax:

The ULTRAFEEDER_CONFIG parameter can have multiple config strings, separated by a ;. Please note that the config strings cannot contain ; or , -- undefined things may happen if these characters are present.

- ULTRAFEEDER_CONFIG=adsb,host,port,protocol[,uuid=XXXXXXXX-XXXX-XXXX-XXXX-XXXXXXXXXXXX][,extra-arguments]
...or...
- ULTRAFEEDER_CONFIG=mlat,host,port[,return_port][,uuid=XXXXXXXX-XXXX-XXXX-XXXX-XXXXXXXXXXXX][,extra-arguments]
...or...
- ULTRAFEEDER_CONFIG=mlathub,host,port,protocol[,uuid=XXXXXXXX-XXXX-XXXX-XXXX-XXXXXXXXXXXX][,extra-arguments]

In the above configuration strings:

  • host is an IP address. Specify an IP/hostname/containername for incoming or outgoing connections.
  • port and return_port are TCP port numbers
  • protocol can be one of the following:
    • beast_reduce_out: Beast-format output with lower data throughput (saves bandwidth and CPU)
    • beast_reduce_plus_out: Beast-format output with extra data (UUID). This is the preferred format when feeding the "new" aggregator services
    • 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: SBS-format output
  • uuid=XXXXXXXX-XXXX-XXXX-XXXX-XXXXXXXXXXXX is an optional parameter that sets the UUID for this specific instance. It will override the global UUID parameter. This is only needed when you want to send different UUIDs to different aggregators.
  • extra-arguments can be any additional command line argument you want to pass to readsb, mlathub, or mlat-client. Example: --net-only. Please make sure to only once pass in an extra argument for each of the adsb|mlat|mlathub service.
Networking parameters
Environment Variable Purpose Default
BEASTHOST IP/Hostname of a Mode-S/Beast provider (dump1090/readsb)
BEASTPORT TCP port number of Mode-S/Beast provider (dump1090/readsb) 30005
MLATHOST Legacy parameter. IP/Hostname of an MLAT provider (mlat-client). Note - using this parameter will not make the MLAT data part of the consolidated mlathub. The preferred way of ingesting MLAT results is using the mlathub functionality of the container, see below for details
MLATPORT Legacy parameter used with MLATHOST. TCP port number of an MLAT provider (mlat-client) 30105
Alternate Configuration Method with READSB_NET_CONNECTOR

Instead of (or in addition to) using BEASTHOST, you can also define ADSB data ingests using the READSB_NET_CONNECTOR parameter. This is the preferred way if you have multiple sources or destinations for your ADSB data. This variable allows you to configure incoming and outgoing connections. The variable takes a semicolon (;) separated list of host,port,protocol[,uuid=XXXXXXXX-XXXX-XXXX-XXXX-XXXXXXXXXXXX], where:

  • host is an IP address. Specify an IP/hostname/containername for incoming or outgoing connections.
  • port is a TCP port number
  • protocol can be one of the following:
    • beast_reduce_out: Beast-format output with lower data throughput (saves bandwidth and CPU)
    • beast_reduce_plus_out: Beast-format output with extra data (UUID). This is the preferred format when feeding the "new" aggregator services
    • 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: SBS-format output
  • uuid=XXXXXXXX-XXXX-XXXX-XXXX-XXXXXXXXXXXX is an optional parameter that sets the UUID for this specific instance. It will override the global UUID parameter. This is only needed when you want to send different UUIDs to different aggregators.

NOTE: If you have a UAT dongle and use dump978 to decode this, you should use READSB_NET_CONNECTOR to ingest UAT data from dump978. See example below

    environment:
    ...
      - READSB_NET_CONNECTOR=dump978,37981,raw_in;another-data-aggregator.com,30005,beast_reduce_plus_out
    ...
Optional Networking Parameters

There are many optional parameters relating to the ingestion of data and the general networking functioning of the readsb program that implements this functionality.

Variable Description Controls which readsb option Default
READSB_NET_API_PORT https://github.com/wiedehopf/readsb/blob/dev/README-json.md#--net-api-port-query-formats --net-api-port=<ports> 30152
READSB_NET_BEAST_REDUCE_INTERVAL BeastReduce position update interval, longer means less data (valid range: 0.000 - 14.999) --net-beast-reduce-interval=<seconds> 1.0
READSB_NET_BEAST_REDUCE_FILTER_DIST Restrict beast-reduce output to aircraft in a radius of X nmi --net-beast-reduce-filter-dist=<nmi> Unset
READSB_NET_BEAST_REDUCE_FILTER_ALT Restrict beast-reduce output to aircraft below X ft --net-beast-reduce-filter-alt=<ft> Unset
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_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_SIZE TCP output flush size (maximum amount of internally buffered data before writing to network). --net-ro-size=<size> 1200
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> 35
READSB_NET_RAW_INPUT_PORT TCP raw input listen ports. --net-ri-port=<ports> 30001
READSB_NET_RAW_OUTPUT_PORT TCP raw output listen ports. --net-ro-port=<ports> 30002
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
READSB_NET_SBS_DISABLE_REDUCE Disable application of "reduce" logic to SBS/BaseStation output. (By default, this is enabled) --net-sbs-reduce Unset
REASSB_NET_VERBATIM Set this to true to forward messages unchanged. --net-verbatim Unset
READSB_NET_VRS_PORT TCP VRS JSON output listen ports. --net-vrs-port=<ports> Unset
READSB_WRITE_STATE_ONLY_ON_EXIT if set to anything, it will only write the status range outlines, etc. upon termination of readsb --write-state-only-on-exit Unset
READSB_JSON_INTERVAL Update interval for the webinterface in seconds / interval between aircraft.json writes --write-json-every=<sec> 1.0
READSB_JSON_TRACE_INTERVAL Per plane interval for json position output and trace interval for globe history --json-trace-interval=<sec> 15
READSB_FORWARD_MLAT_SBS If set to anthing, it will include MLAT results in the SBS/BaseStation output. This may be desirable if you feed SBS data to applications like VRS or PlaneFence Unset
UUID Sets the UUID that is sent on the beast_reduce_plus port if no individual UUIDs have been defined with the READSB_NET_CONNECTOR parameter. Similarly, it's also used with mlat-client (see below) if no individual UUIDs have been set with the MLAT_CONFIG parameter. unset
MLAT configuration

The Ultrafeeder contains a capability to send MLAT data to MLAT servers to be processed, and to receive the MLAT results and integrate those with an MLAT Hub and the tar1090 map. It will create a separate instance of mlat-client for each defined MLAT server. The parameters for these mlat-client instances is as follows:

    environment:
    ...
      - MLAT_NET_CONNECTOR=
           mlat-server1.com,port1,return_port1,uuid=1234-5678-90123,--extra-argument hello;
           mlat-server2.com,port2,return_port2,uuid=5678-9012-34567,--extra-argument hello
    ...

where:

  • mlat-server.com is the domain name or ip address of the target MLAT server (mandatory)
  • port is the port (TCP or UDP) of the target MLAT server (mandatory)
  • return_port is the port at which the MLAT results are made available in BEAST format. We recommend to sequentially number them starting at 39000 (optional)
  • uuid=xxxx defines a unique user ID for this MLAT server instance. If included, the string must start with uuid= (optional)
  • extra-arguments are any additional command line arguments that you would like to use for this MLAT Client instance (optional)

Note - the three optional parameters (return_port, uuid=, and extra-arguments) can be given in any order.

If no UUID is specified with the MLAT_CONFIG parameter, it will use the value of the UUID parameter if it exists. If that fails, no UUID parameter is included with mlat-client.

Web Gui (tar1090) Configuration

The Container creates an interactive web interface displaying the aircraft, based on Wiedehopf's widely used tar1090 software.

The web interface is rendered to port 80 in the container. This can me mapped to a port on the host using the docker-compose ports directive.

All of the variables below are optional.

Note - due to design limitations of readsb, the tar1090 graphical interface will by default ONLY show MLAT results from the aggregators/MLAT sources that were defined with the MLAT_NET_CONNECTOR parameter. If you want to show any additional MLAT results (for example, those from piaware), you should add a separate READSB_NET_CONNECTOR entry for them.

tar1090 Core Configuration

Environment Variable Purpose Default
READSB_JSON_INTERVAL Update data update interval for the webinterface in seconds 1.0
UPDATE_TAR1090 At startup update tar1090 and tar1090db to the latest versions true
INTERVAL Interval at which the track history is saved 8
HISTORY_SIZE How many points in time are stored in the track history 450
ENABLE_978 Change to yes to enable UAT/978 display in tar1090. This will also enable UAT-specific graphs in graphs1090 no
URL_978 The URL needs to point at where you would normally find the skyview978 webinterface, for example http://192.168.0.29/skyaware978. Note -- do not use localhost or `127.0.0.1
GZIP_LVL 1-9 are valid, lower lvl: less CPU usage, higher level: less network bandwidth used when loading the page 3
PTRACKS Shows the last $PTRACKS hours of traces you have seen at the ?pTracks URL 8
TAR1090_FLIGHTAWARELINKS Set to true to enable FlightAware links in the web interface null
TAR1090_ENABLE_AC_DB Set to true to enable extra information, such as aircraft type and registration, to be included in in aircraft.json output. Will use more memory; use caution on older Pis or similar devices. false
HEYWHATSTHAT_PANORAMA_ID Your heywhatsthat.com panorama ID. See https://github.com/wiedehopf/tar1090#heywhatsthatcom-range-outline
HEYWHATSTHAT_ALTS Comma separated altitudes for multiple outlines. Use no units or ft for feet, m for meters, or km for kilometers. Only integer numbers are accepted, no decimals please 12192m (=40000 ft)
HTTP_ACCESS_LOG Optional. Set to true to display HTTP server access logs. false
HTTP_ERROR_LOG Optional. Set to false to hide HTTP server error logs. true

tar1090 config.js Configuration - Title

Environment Variable Purpose Default
TAR1090_PAGETITLE Set the tar1090 web page title tar1090
TAR1090_PLANECOUNTINTITLE Show number of aircraft in the page title false
TAR1090_MESSAGERATEINTITLE Show number of messages per second in the page title false

tar1090 config.js Configuration - Output

Environment Variable Purpose Default
TAR1090_DISPLAYUNITS The DisplayUnits setting controls whether nautical (ft, NM, knots), metric (m, km, km/h) or imperial (ft, mi, mph) units are used in the plane table and in the detailed plane info. Valid values are "nautical", "metric", or "imperial". nautical

tar1090 config.js Configuration - Map Settings

Environment Variable Purpose Default
TAR1090_BINGMAPSAPIKEY Provide a Bing Maps API key to enable the Bing imagery layer. You can obtain a free key (with usage limits) at https://www.bingmapsportal.com/ (you need a "basic key"). null
TAR1090_DEFAULTCENTERLAT Default center (latitude) of the map. This setting is overridden by any position information provided by dump1090/readsb. All positions are in decimal degrees. 45.0
TAR1090_DEFAULTCENTERLON Default center (longitude) of the map. This setting is overridden by any position information provided by dump1090/readsb. All positions are in decimal degrees. 9.0
TAR1090_DEFAULTZOOMLVL The google maps zoom level, 0 - 16, lower is further out. 7
TAR1090_SITESHOW Center marker. If dump1090 provides a receiver location, that location is used and these settings are ignored. Set to true to show a center marker. false
TAR1090_SITELAT Center marker. If dump1090 provides a receiver location, that location is used and these settings are ignored. Position of the marker (latitude). 45.0
TAR1090_SITELON Center marker. If dump1090 provides a receiver location, that location is used and these settings are ignored. Position of the marker (longitude). 9.0
TAR1090_SITENAME The tooltip of the center marker. My Radar Site
TAR1090_RANGE_OUTLINE_COLOR Colour for the range outline. #0000DD
TAR1090_RANGE_OUTLINE_WIDTH Width for the range outline. 1.7
TAR1090_RANGE_OUTLINE_COLORED_BY_ALTITUDE Range outline is coloured by altitude. false
TAR1090_RANGE_OUTLINE_DASH Range outline dashing. Syntax [L, S] where L is the pixel length of the line, and S is the pixel length of the space. Unset
TAR1090_ACTUAL_RANGE_OUTLINE_COLOR Colour for the actual range outline #00596b
TAR1090_ACTUAL_RANGE_OUTLINE_WIDTH Width of the actual range outline 1.7
TAR1090_ACTUAL_RANGE_OUTLINE_DASH Dashed style for the actual range outline. Unset for solid line. [5,5] for a dashed line with 5 pixel lines and spaces in between Unset
TAR1090_MAPTYPE_TAR1090 Which map is displayed to new visitors. Valid values for this setting are osm, esri, carto_light_all, carto_light_nolabels, carto_dark_all, carto_dark_nolabels, gibs, osm_adsbx, chartbundle_sec, chartbundle_tac, chartbundle_hel, chartbundle_enrl, chartbundle_enra, chartbundle_enrh, and only with bing key bing_aerial, bing_roads. carto_light_all
TAR1090_MAPDIM Default map dim state, true or false. true
TAR1090_MAPDIMPERCENTAGE The percentage amount of dimming used if the map is dimmed, 0-1 0.45
TAR1090_MAPCONTRASTPERCENTAGE The percentage amount of contrast used if the map is dimmed, 0-1 0
TAR1090_DWDLAYERS Various map layers provided by the DWD geoserver can be added here. Preview and available layers. Multiple layers are also possible. Syntax: dwd:layer1,dwd:layer2,dwd:layer3 dwd:RX-Produkt
TAR1090_LABELZOOM Displays aircraft labels only until this zoom level, 1-15 (values >15 don't really make sense)
TAR1090_LABELZOOMGROUND Displays ground traffic labels only until this zoom level, 1-15 (values >15 don't really make sense)

tar1090 config.js Configuration - Range Rings

Environment Variable Purpose Default
TAR1090_RANGERINGS false to hide range rings true
TAR1090_RANGERINGSDISTANCES Distances to display range rings, in miles, nautical miles, or km (depending settings value 'TAR1090_DISPLAYUNITS'). Accepts a comma separated list of numbers (no spaces, no quotes). 100,150,200,250
TAR1090_RANGERINGSCOLORS Colours for each of the range rings specified in TAR1090_RANGERINGSDISTANCES. Accepts a comma separated list of hex colour values, each enclosed in single quotes (eg TAR1090_RANGERINGSCOLORS='#FFFFF','#00000'). No spaces. Unset

tar1090 config.js Configuration - Route Display

Environment Variable Purpose Default
TAR1090_USEROUTEAPI Set to true to enable route lookup for callsigns Unset
TAR1090_ROUTEAPIURL API URL used https://api.adsb.lol/api/0/routeset

Configuring graphs1090

graphs1090 Environment Parameters

Variable Description Default
GRAPHS1090_DARKMODE If set to true, graphs1090 will be rendered in "dark mode". Unset
GRAPHS1090_RRD_STEP Interval in seconds to feed data into RRD files. 60
GRAPHS1090_SIZE Set graph size, possible values: small, default, large, huge, custom. default
GRAPHS1090_ALL_LARGE Make the small graphs as large as the big ones by setting to yes. no
GRAPHS1090_FONT_SIZE Font size (relative to graph size). 10.0
GRAPHS1090_MAX_MESSAGES_LINE Set to true to draw a reference line at the maximum message rate. Unset
GRAPHS1090_LARGE_WIDTH Defines the width of the larger graphs. 1096
GRAPHS1090_LARGE_HEIGHT Defines the height of the larger graphs. 235
GRAPHS1090_SMALL_WIDTH Defines the width of the smaller graphs. 619
GRAPHS1090_SMALL_HEIGHT Defines the height of the smaller graphs. 324
GRAPHS1090_DISK_DEVICE Defines which disk device (mmc0, sda, sdc, etc) is shown. Leave empty for default device Unset
GRAPHS1090_ETHERNET_DEVICE Defines which (wired) ethernet device (eth0, enp0s, etc) is shown. Leave empty for default device Unset
GRAPHS1090_WIFI_DEVICE Defines which (wireless) WiFi device (wlan0, wlp3s0, etc) is shown. Leave empty for default device Unset
GRAPHS1090_DISABLE Set to true to disable the GRAPHS1090 web page and data collection Unset
ENABLE_AIRSPY Optional, set to any non-empty value if you want to enable the special AirSpy graphs. See below for additional configuration requirements Unset

Enabling UAT data

ADS-B over UAT data is transmitted in the 978 MHz band, and this is used in the USA only. To display the corresponding graphs, you should:

  1. Set the following environment parameters:
  - ENABLE_978=yes
  - URL_978=http://dump978/skyaware978
  1. Install the docker-dump978 container. Note - only containers downloaded/deployed on/after Feb 8, 2023 will work.

Note that you must configure URL_978 to point at a working skyaware978 website with aircraft.json data feed. This means that the URL http://dump978/skyaware978/data/aircraft.json must return valid JSON data to this tar1090 container.

Enabling AirSpy graphs

Users of AirSpy devices can enable extra graphs1090 graphs by configuring the following:

  • Set the following environment parameter:
      - ENABLE_AIRSPY=yes
  • To provide the container access to the AirSpy statistics, map a volume in your docker-compose.yml file as follows:
    volumes:
      - /run/airspy_adsb:/run/airspy_adsb
      ...

Enabling Disk IO and IOPS data

To allow the container access to the Disk IO data, you should map the following volume:

    volumes:
      - /proc/diskstats:/proc/diskstats:ro
      ...

Configuring the Core Temperature graphs

By default, the system will use the temperature available at Thermal Zone 0. This generally works well on Raspberry Pi devices, and no additional changes are needed.

On different devices, the Core Temperature is mapped to a different Thermal Zone. To ensure the Core Temperature graph works, follow these steps

First check out which Thermal Zone contains the temperature you want to monitor. On your host system, do this:

for i in /sys/class/thermal/thermal_zone* ; do echo "$i - $(cat ${i}/type) - $(cat ${i}/temp 2>/dev/null)"; done

Something similar to this will be show:

/sys/class/thermal/thermal_zone0 - acpitz - 25000
/sys/class/thermal/thermal_zone1 - INT3400 Thermal - 20000
/sys/class/thermal/thermal_zone2 - TSKN - 43050
/sys/class/thermal/thermal_zone3 - NGFF - 32050
/sys/class/thermal/thermal_zone4 - TMEM - 39050
/sys/class/thermal/thermal_zone5 - pch_skylake - 40500
/sys/class/thermal/thermal_zone6 - B0D4 - 54050
/sys/class/thermal/thermal_zone7 - iwlwifi_1 -
/sys/class/thermal/thermal_zone8 - x86_pkg_temp - 57000

Repeat this a few times to ensure that the temperature varies and isn't hardcoded to a value. In our case, either Thermal Zone 5 (pch_skylake is the Intel Core name) or Thermal Zone 8 (the temp of the entire SOC package) can be used. Once you have determined which Thermal Zone number you want to use, map it to a volume like this. Make sure that the part to the left of the first : reflects your Thermal Zone directory; the part to the right of the first : should always be /sys/class/thermal/thermal_zone0:ro.

Note that you will have to add - privileged: true capabilities to the container. This is less than ideal as it will give the container access to all of your system devices and processes. Make sure you feel comfortable with this before you do this.

    privileged: true
    volumes:
      - /sys/class/thermal/thermal_zone8:/sys/class/thermal/thermal_zone0:ro
      ...

Note - on some systems (DietPi comes to mind), /sys/class/thermal/ may not be available.

timelapse1090 Configuration

Legacy: We recommend AGAINST enabling this feature as it has been replaced with http://dockerhost:port/?replay. timelapse1090 writes a lot of data to disk, which could shorten the lifespan of your Raspiberry Pi SD card. The replacement functionality is better and doesn't cause any additional disk writes.

Environment Variable Purpose Default
ENABLE_TIMELAPSE1090 Optional / Legacy. Set to true to enable timelapse1090. Once enabled, can be accessed via http://dockerhost:port/timelapse/ Unset
TIMELAPSE1090_INTERVAL Snapshot interval in seconds 10
TIMELAPSE1090_HISTORY Time saved in hours 24

Web Pages

If you have configured the container as described above, you should be able to browse to the following web pages: You should now be able to browse to:

Paths

No paths need to be mapped through to persistent storage. However, if you don't want to lose your range outline and aircraft tracks/history and heatmap / replay data on container restart, you can optionally map these paths:

Path Purpose
/opt/adsb/ultrafeeder/globe_history:/var/globe_history Holds range outline data, heatmap / replay data and traces if enabled.
Note: this data won't be automatically deleted, you will need to delete it eventually if you map this path.
/opt/adsb/ultrafeeder/timelapse1090:/var/timelapse1090 Holds timelapse1090 data if enabled. (We recommend against enabling this feature, see above)
/opt/adsb/ultrafeeder/collectd:/var/lib/collectd Holds graphs1090 & performance data
/proc/diskstats:/proc/diskstats:ro Makes disk statistics available to graphs1090
/sys/class/thermal/thermal_zone8:/sys/class/thermal/thermal_zone0:ro Only needed on some systems to display the CPU temperature in graphs1090, see here

Configuring the built-in MLAT Hub

An "MLAT Hub" is an aggregator of MLAT results from several sources. Since the container is capable of sending MLAT data to multiple ADSB aggregators (like adsb.lol/fi/one, etc), we built in a capability to:

  • collect the MLAT results from all of these services
  • ingest MLAT results from other containers (FlightAware, Radarbox, etc.)
  • make the consolidated MLAT results available on a port in Beast or SBS (BaseStation) format
  • create outbound connections using any supported format to send your Beast data wherever you want

Note - due to design limitations of readsb, the tar1090 graphical interface will by default ONLY show MLAT results from the aggregators/MLAT sources that were defined with the MLAT_NET_CONNECTOR parameter. If you want to show any additional MLAT results (for example, those from piaware), you should add a separate READSB_NET_CONNECTOR for them. Adding these sources only to MLATHUB_NET_CONNECTOR will make the data available on the MLATHUB, but won't display them on your tar1090 map.

Generally, there is little to configure, but there are a few parameters that you can set or change:

Variable Description Default if omitted
MLATHUB_SBS_OUT_PORT TCP port where the consolidated MLAT results will be available in SBS (BaseStation) format 31003
MLATHUB_BEAST_IN_PORT TCP port you where you can send additional MLAT results to, in Beast format 31004
MLATHUB_BEAST_OUT_PORT TCP port where consolidated MLAT results will be available in Beast format 31005
MLATHUB_BEAST_REDUCE_OUT_PORT TCP port where consolidated MLAT results will be available in Beast format with reduced data rates 31006
MLATHUB_NET_CONNECTOR List of semi-colon (;) separated IP or host, port, and protocols where MLATHUB will connect to ingest or send MLAT data. It follows the same syntax as described in the READSB_NET_CONNECTOR syntax section above. Unset

Metrics

This image contains Telegraf, which will be used to capture metrics from readsb if an output is enabled.

Output to InfluxDBv2

In order for Telegraf to output metrics to an InfluxDBv2 time-series database, the following environment variables can be used:

Variable Description
INFLUXDBV2_URL The URL of the InfluxDB instance
INFLUXDBV2_TOKEN The token for authentication
INFLUXDBV2_BUCKET Destination bucket to write into
INFLUXDBV2_ORG InfluxDB Organization to write into

Output to Prometheus and configuring Grafana

In order for Telegraf to serve a Prometheus endpoint, the following environment variables can be used:

Variable Description
PROMETHEUS_ENABLE Set to true for a Prometheus endpoint on http://0.0.0.0:9273/metrics

Please see the separate instruction document for step by step instructions on how to set up and configure a Grafana Dashboard.

Message decoding introspection

You can look at individual messages and what information they contain, either for all or for an individual aircraft by hex:

# only for hex 3D3ED0
docker exec -it ultrafeeder /usr/local/bin/viewadsb --show-only 3D3ED0

# for all aircraft
docker exec -it ultrafeeder /usr/local/bin/viewadsb --no-interactive

# show position / CPR debugging for hex 3D3ED0
docker exec -it ultrafeeder /usr/local/bin/viewadsb --cpr-focus 3D3ED0

Logging

All logs are to the container's stdout and can be viewed with docker logs -t [-f] container.

Getting help

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

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

Acknowledgements

  • The SDR-Enthusiasts team (Mike Nye, Fred Clausen) for all the foot and leg work done to create the base images on which the container is built
  • Wiedehopf for modifying, creating, maintaining, and adding features to many of the components of this container including readsb, tar1090, graphs1090, autogain, and many more components
  • John Norrbin for his ideas, testing, feature requests, more testing, nagging, pushing, prodding, and overall efforts to make this a high quality container and for the USB "hotplug" configuration
  • The community at the SDR-Enthusiasts Discord Server for helping out, testing, asking questions, and generally driving to make this a better product
  • Of course the Open Source community at large, including Salvatore Sanfilippo and Oliver Jowett (mutability) who wrote the excellent base code for dump1090 from which much of this is derived