# How do you calculate the median of a set of angles?

I have a list of angles and want to get rid of outlier. My first idea is to calculate the median. Unfortunately there is the "wrap around" problem. I don't know of a "correct" way to define the median for a set of angles (or clock-positions).

My idea is to first calculate the mean, and use this to break the circle on the opposite side.

``````Example:
{6, 50, 52, 54, 60, 250} (in degree, 0-360)
average ~ 39
new range [-219, 219) -> new order 250, 6, 50, 52, 54, 60, 250
52 or 54 as median
``````

Is this a good approach, or are there maybe better ones i don't know of?

Somewhat related: This Question showed ways to calculate the Mean of angles.

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This isn't really a programming problem. Perhaps math.stackexchange.com might be a better place to ask. It might also be worth asking whether the question makes sense and whether something else rather than median might make more sense. I would imagine though that you will get similar issues for working out your mean. eg for angles 1,2,3 you might get a simple mean of 2. For 359, 0,1 you might get a mean of 120 which is probably not what you want. – Chris May 6 '14 at 12:02
@Chris: Check the other answer regarding discussion for the mean, example: 355,0,90 would yield 25 deg. You might be right regarding the math exchange. Since i have to program it, i wanted to ask here first though. ;) – Sebastian Schmitz May 6 '14 at 12:08
If you want how to implement it once you have the answer then this is definitely the place to go. I suspect this is the sort of edge case that programmers rarely come across but mathematicians might have come across it much more (or at least some). – Chris May 6 '14 at 15:16

You can use the approach shown in the question you linkes: Calculate the average as the angle of accumulated unit vectors of your angles. In my opinion, this approach is not very suited to large sets of vectors.

There's another approach that works with weighted interpolations. It doesn't require any trigonometric functions, which means that you can work with your data in degrees without converting them to radians.

In this approach, all angles must be between 0° and 360°. If they lie outside, they must be brought into this range, e.g. -5° becomes 355°. Then you do a pairwise weighted average, where you adjust the angles when their difference is more than a semicircle, so that you always avarage over the shorter arc between the angles. After averaging, the resulting angle is brought into the range 0° to 360°.

``````def angle_interpol(a1, w1, a2, w2):
"""Weighted avarage of two angles a1, a2 with weights w1, w2

diff = a2 - a1
if diff > 180: a1 += 360
elif diff < -180: a1 -= 360

aa = (w1 * a1 + w2 * a2) / (w1 + w2)

if aa > 360: aa -= 360
elif aa < 0: aa += 360

return aa

def angle_mean(angle):
"""Unweighted average of a list of angles"""

if not angle: return 0

aa = 0.0
ww = 0.0

for a in angle:
aa = angle_interpol(aa, ww, a, 1)
ww += 1

return aa
``````

If you look at your example {6°, 50°, 52°, 54°, 60°, 250°}, you'll notice that all points lie on the same semicircle between 250° (or -110°) and 70°. With the proposed avarage method, the average angle is 18.67°. This is also the linear average of {6, 50, 52, 54, 60, -110}, which seems reasonable. The median would be between 50 and 52. The outlier is still the angle at 250°, but it is closer to the average if you come from -110° than if you come from 250°.

Another example is {0°, 0°, 90°}. The vector approach calculates `atan(0.5)`, i.e. approximately 26.6° as average. The proposed approach determines 30° as average.

Calculating a circular average is only meaningful if your data is not evenly distributed in the feasible angle range. The arctan approach has a singularity if the angles cancel each other out; the approach proposed above just produces garbage.

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To get the median of a set of numbers you sort them and then take the middle one. That is, if you have 7 numbers in sorted order, the median is the 3rd number.

You could do the same with angles, but the result makes little sense because the concept of "first angle" is not well defined when you have more than one angle.

To define the first angle you could sort the angles and find the largest gap between consecutive angles. The angle next to the largest gap between two angles intuitively feels like a good candidate to be a "first" angle.

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