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What can we learn by looking more closely at a Starlink dish's history of connection data? The scripts and such in this repo are what I have pulled together to find out.

There are two phases in this process, and the scripts for each phase are separated into the two subdirectories:

  • downloader collects data from the dish
  • viewer presents a visual representation of the aggregated data

These scripts were developed on a Mac running macOS 11.1 and a Raspberry Pi running Raspian 10 (buster). Some use zsh. I /think/ there's nothing zsh-specific about them (so they may also work as bash), but I haven't tested. The scripts use grpcurl and jq and python3, so you'll want those installed.

Downloader / collection

The Starlink dish presents a GRPC endpoint that Starlink's apps use to fetch the data they display. For more information about the requests and responses this endpoint serves, I recommend looking through the sparky8512/starlink-grpc-tools repo. The main request/response pair this repo cares about is get_history/dishGetHistory.

In the downloader directory, you'll find the fetch-data.sh script. This is a simple wrapper around grpcurl that downloads a JSON-ified dishGetHistory response into a file named for the date-time it was downloaded (YYYY-MM-DD-HHMMSS.json).

MacOS download automation

Also in the downloader directory is the file StarlinkData.plist. This is a launchd definition to run fetch-data.sh periodically. To use it:

  1. Copy StarlinkData.plist to ~/Library/LaunchAgents

  2. Edit ~/Library/LaunchAgents/StarlinkData.plist to correct the path to the fetch-data.sh script (i.e. replace /Users/bryan/projects with wherever you downloaded this repo).

  3. Run launchd load ~/Library/LaunchAgents/StarlinkData.plist

The file is set up to download history data at three minutes past the hour, every hour. If your Mac is asleep when one or more downloads are supposed to happen, they will be skipped, and instead one download will happen as soon as your Mac wakes up. Each download contains the last 12 hours of data, so as long as your Mac is awake once every 12 hours, you won't miss any data. Each download is a little under 4mb, so even if your Mac does every download, you'll still consume less than 100mb per day.

If you want to stop collecting data, run launchd unload ~/Library/LaunchAgents/StarlinkData.plist.

Linux download automation

Also in the downloader directory is the file crontab. This is an example crontab specification to run the fetch-data.sh script a few times per day.

Viewer / visual presentation

The viewer is an HTML/SVG app. It uses a small Python script to serve the collected data files to the app. If your data is stored in a directory named /path/to/your/data, start the Python script like so:

  1. cd viewer/
  2. ./server.py starlink:/path/to/your/data

If you have more than one directory containing data you'd like to view, pass additional arguments to server.py. The starlink before the colon in the example above is the name of that data that will show up above the file selection list in the viewer. Give each path a different name (e.g. ./server.py startlink:/path/to/starlink-data DSL:/path/to/dsl-data hotspot:/path/to/hotspot-data).

Open the page in your web browser: (http://localhost:8000/index.html)

If the page loads correctly, you should see a list of your collected data files in a box at the upper left. Click on any file to view it. If you select several files at once (via clicking and dragging, shift-clicking, command-clicking, or other means), the timespan they cover will be rendered together. The "current" entry at the top of the list will request a fresh dump of data from the dish.

If the rendering is successful, then below the selection box and the fields next to it at the top at the top, a large white space with a bunch of colored squares will appear.

Each red square is a 1-second interval where some number of pings was dropped, and the dish reported that they were dropped because of some obstruction. The more opaque the red, the more pings were dropped.

Consequtive seconds run from left to right, and then wrap around to start again at the left on the next line down. The "stripe" field determines how many seconds are placed on each line. The "offset" field determines how many seconds to skip at the start of the data. The left-hand "box size" field determines the width of each rectangle, and the right-hand field determines the height.

The checkboxes determine which data is displayed.

  • "obstructed": When the dish thought its view of the satellite was obstructed. Rectangles will be red.

  • "beta downtime": When the dish thought there should be a satellite available, but it was not responsive. Rectangles will be blue.

  • "no satellites": When the dish did not expect to have a satellite available. Rectangles will be green.

  • "signal-to-noise ratio": The dish's measurement of the signal-to-noise ratio. Rectangles will be darker grey when the signal was low and the noise was high.

  • "connected": Highlight areas where a connection was maintained at the specified quality for the at least the specified time.

A few text fields near these checkboxes alter how much of each category is displayed:

  • "min loss ratio": Determines what ratio of pings must be dropped in a sample in order for it to be rendered in the chart. The default of 1 means "all pings must be dropped", which seems to be the metric that Starlink uses for counting downtime. Valid values are decimals between 0 and 1.

  • "min downlink bps" and "min uplink bps": Each of these overrides the the decision of whether or not to show an outage, based on the measured downlink or uplink throughput. If downlink throughput for the second was higher than "min downlink bps", the outage is not rendered. If uplink throughput for the second was higher than "min uplink bps", the outage is not rendered.

  • "max snr": Determines highest signal-to-noise ratio worth rendering. The default of 0 renders only the darkest grey boxes, when signal is completely absent. Valid values are 0 to 9.

  • "Min Clear Sec": The number of contiguous seconds that must elapse for a region to be highlighted as connected (part one of "the specified quality")

  • "Max Down Sec": The number of contiguous seconds in which ping loss is equal to or higher than "min loss ratio" before a contiguous connected region is considered broken.

The connected highlighting may be best explained by an example. If highlighting is enabled with "obstructed" enabled, "min loss ratio" at 1, "Min Clear Sec" at 1800, and "Max Down Sec" at 2, then any region highlighted is a region at least 30 minutes long in which no obstruction causing total ping loss for more than two seconds occurred. This example is a metric I'm using to quantify how often a good-quality medium-length video call is possible.

If you place your mouse over the rendering, a tooltip will display the offset into the data array, as well as the date and time of that sample, at the position of your pointer.

A histogram is rendered below the timeseries chart. This histogram shows the count of the number of times a span of each type, for the given duration, was observed. Colors are the same as the timeseries graph. Example: If a red bar of height 10 at the "1s" mark is displayed, that means that a one-second obstruction was observed 10 times in the data. A blue bar of height 1 at the "10m" mark is displayed, one ten-minute-long beta downtime was observed.

The histogram obeys the same filtering rules as the timeseries data, except instea of shading, any sample that would have been rendered is added to any span to which it is adjacent. That is, if "min loss ratio" is set to 0.5, and over three seconds an obstruction causes ping losses of 0.75, 1, and 0.9, a three-second obstruction span will be recorded.

Connection spans also obey the same filtering rules as the timeseries data. If "Max Down Sec" is set to 2, then outages (of any type, including mixed-cause) lasting two seconds or less will not interrupt a connection. For example, two 5-second spans of connectivity interrupted by a 1-second span of beta downtime will be recorded as one 11-second span of connectivity (5 + 5 + 1). The one-second beta downtime will also be counted, since that area of the graph can be ignored without affecting other data. "Min Clear Sec" is ignored for the purposes of the histogram, since recording smaller spans here does not prevent charting longer spans.

Below the histogram is a table of "adjacencies". Each cell counts the number of times where a span of the type of that row abuts a span of the type of that column. Percentages are of the total adjacencies for the row.

Below the adjacencies table is a table of "overrulings". This provides a count of the number of times that downlink or uplink throughput was high enough to decide that a high ping loss rate did not indicate a lack of connection. The "downlink" and "uplink" counts are independent

  • if both rates were high enough, the overruling is counted in both columns. The "either" count is the total number of overrulings (count an overruling by both downlink and uplink rate only once), and the "not" count is the number of outages that were still counted.

Reducer / aggregation

If you would like to reclaim some disk space, a tool is included for removing the duplicated samples in each hour's data file. That tool is in the reducer/ directory.

To use it, first change to the directory where your data files live, then run reducer/extract-unique-times.zsh, passing as its first argument the directory where you would like the deduped data to end up (don't use "." because you'll overwrite the files there), and passing as its second through Nth arguments the files that you would like to deduplicate.

For example, if I wanted to deduplicate all files for February 2021 from my data/ directory into my dedupe/ directory, I would do the following:

  1. cd data/
  2. ../reducer/extract-unique-times.zsh ../dedupe 2021-02*.json

In addition to removing duplicate data, ring buffers are unraveled, so that the oldest sample is always the first in the arrays, and the newest data is always the last.

Results

The original idea behind the viewer wass that the beam between the dish and the satellite is something like a CRT, sweeping across the scenery as the satellite moves past. If the satellites are moving in semi-constant rings, while the earth turns beneath them, then each successive satellite in a ring passes just a little lower on the west horizon, or just a little higher on the east horizon. This should produce a succession of sweeps across the scene. If the dish connects to the next dish in the ring at a regular interval, then syncing up the sweep with the viewer should produce a scan of that region of the sky.

It didn't quite work out, as you can read at (http://blog.beerriot.com/2021/02/14/starlink-raster-scan/). But, I've been using the viewer to continue to get a clearer picture of the quality of my connection.

Pinger

Recently added is another utility in the pinger/ subdirectory. This is intended to be a quick-hack way to compare the connectedness of a non-starlink connection.

The main script in the subdirectory, collect-pings.py pings 8.8.8.8 once per second. Every 3600 pings (approximately once per hour), it writes a file to disk that records which of those pings succeeded. The file is not exactly the same format as Starlink's history response, but the ping_returncode field is close enough to popPingDropRate to allow the viewer to render it in the same format.

The other two files in the subdirectory are support to keep this ping recording utility running in the background. The background-collection.sh script checks for a running collect-pings.py and starts a new one if it doesn't find one. The check is performed by writing the PID of the collect-pings.py process to a file, and then querying for that PID. The crontab file contains an example of how to automatically run background-collection.sh to make sure collect-pings.py gets restarted if it stops.