# Calculating Speed Based on Randomly-Timed Received Position Coordinates

I'm writing an application that has a need to know the speed you're traveling. My application talks to several pieces of equipment, all with different built-in GPS receivers. Where the hardware I'm working with reports speed, I use that parameter. But in some cases, I have hardware which does NOT report speed, simply latitude and longitude.

What I have been doing in that case, is marking the time that I receive the first coordinate, then waiting for another coordinate to come in. I then calculation the distance traveled and divide by the elapsed time.

The problem I'm running into is that some of the hardware reports position quickly (5-10 times per second) while some reports position slowly (0.5 times per second). When I'm receiving the GPS position quickly, my algorithm fails to accurately calculate the speed due to the inherent inaccuracies of GPS receivers. In order words, the position will naturally move due to GPS inaccuracy, and since the elapsed time span from the last received position is so small, my algorithm thinks we've moved far over a short time - meaning we are going fast (when in reality we may be standing still).

How can I go about averaging the speed to avoid this problem? It seems like the process will have to be adaptive based on how fast the points come in. For example if I simply average the last 5 points collected to do my speed calculation, it will probably work great for "fast" reporting units but it will hurt my accuracy for "slow" reporting units.

Any ideas?

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Read abount Data Mining it may helps you. – Hossein Narimani Rad Apr 2 '13 at 13:52
@HosseinNarimaniRad do you feel like you just recommended to `read about algorithms` ? – Ilya Ivanov Apr 2 '13 at 13:53
It's a broad question and there are lost of ways of doing it. It's not a question that can be answered here. It can be a research area (e.g. Map Matching). It can be a project and ... – Hossein Narimani Rad Apr 2 '13 at 13:56
Can you give more specific directions? Data Mining is a huge and broad topic, with lots of disciplines involved. – Ilya Ivanov Apr 2 '13 at 14:01
You could change the code so whenever it receives a position it will calculate the speed based on the position at least half a second ago, you will then have to maintain a list of coordinates and timestamps. – Casperah Apr 2 '13 at 14:02

Use a simple filter:

Take a position only if it is more than 10 meters away from last taken position.

Then caluclate the distance between lastGood and thisGood, and divide by timeDiff.

Your further want to ignore all speeds under 5km/h were GPS is most noisy.

You further can optimize by calcuklating the direction between last and this, if it stays stable you take it. This helps filtering.

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I would average the speed over the last X seconds. Let's pick X=3. For your fast reporters that means averaging your speed with about 20 data points. For your slow reporters, that may only get you 6 data points. This should keep the accuracy fairly even across the board.

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I like the "spirit" of this answer. However, averaging speed won't work because the speeds are all big positive numbers (associated with different directions). – Ivan Apr 2 '13 at 14:15
So you need to calculate the xvector and yvector separately and average them before combining vectors into a numeric speed? Then you can have negative vectors canceling out positive vectors. In the case where you're sitting still and getting random points within 20m of your current position the negative vectors would help. – Denise Skidmore Apr 2 '13 at 19:32

I'd try using the average POSITION over the last X seconds.

This should "average out" the random noise associated with the high frequency location input....which should yield a better speed computation.

(Obviously you'd use "averaged" positions to compute your speed)

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You probably have an existing data point structure to pull a linq query from?

In light of the note that we need to account for negative vectors, and the suggestion to account for known margins of error here is a more complex example:

``````class GPS
{
List<GPSData> recentData;
TimeSpan speedCalcZone = new TimeSpan(100000);
decimal acceptableError = .5m;

{
var vectors = (from point in recentData
where point.timestamp > DateTime.Now - speedCalcZone
select new
{
});
var averageXVector = (from vector in vectors
select vector.xVector).Average();
var averageYVector = (from vector in vectors
select vector.yVector).Average();
var averagedSpeed = Math.Sqrt(Math.Pow(averageXVector, 2) + Math.Pow(averageYVector, 2));

return averagedSpeed;
}
}
``````

But as pointed out in comments, there is no one magic algorithm, you have to tweak it for your circumstances and needs.

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You're looking for one ideal algorithm that may not exist for one very simple reason: you can't invent data where there isn't any and some times you can't even tell where the data ends and error begins.

That being said there are ways to reduce the "noise" as you've discovered with averaging 5 consecutive measurements, I'd add to that you can throw away the "outliers" and choose 3 of the 5 that are closest to each-other.

The question here is what would work best (or acceptably well) for your situation. If you're tracking trucks moving around the continent a few mph won't matter as the errors will cancel themselves out, but if you're tracking a flying drone that moves between buildings the difference can be quite significant.

Here are some more ideas, you can pick and choose how far you can go, I'm assuming the truck scenario and the idea is to get most probable speed when you don't have an accurate reading: - discard "improbable" speeds - tall buildings can reflect GPS signal causing speeds of over 100mph when you're just walking, having a "highway map" (see below) can help managing the cut-off value - transmit, store and calculate with error ranges rather than point values (some GPS reports error range). - keep average error per location - keep average error per reporting device - keep average speed per location, you'll end up having a map of highways vs other roads - you can correlate location speed and direction

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