# How to find the smallest interval containing a set of values modulo N?

First the practical application that led me to the problem:

Given a set of angle measurements `v[i]` in the range of [0,360) degrees, what is the smallest interval containing all `v[i]?`

Note: the interval may be on both sides, close around 0.

Abstract description of the problem:

For a given set of values `v[i]`, what are the values `c` and `d`, such that

• for all `i`: `dist(v[i],c) <= d` and
• `d` is as small as possible and
• `dist(x,y) = abs(((x-y + N/2 + N) mod N) - N/2)` ?

This is trivial on an open (infinite) scale, where `dist(x,y) = abs(x-y)`:

``````calculate max and min of all v[i]
c = (max + min)/2;
d = (max - min)/2;
``````

But what's the best way to find c and d for a finite scale (modulo N) and a distance defintion as given above?

Is there maybe a way to do it O(n) (if n is the number of values)?

-
What is v[i] - an integer? An ordered pair [start_degree, end_degree]? –  mbeckish Jul 10 '09 at 20:18
v[i] is one measured value (integer or real doesn't matter). Lets suppose all values are stored in an array v. –  Curd Jul 10 '09 at 20:25
What's the purpose? Maybe stackoverflow.com/questions/491738/… is relevant? –  starblue Jul 11 '09 at 6:30

1. normalize all angles to [0, N)
2. sort angles (minimum first)
3. find neigborung pair with maximum distance:
3.1 You need always subtract (next - previous)
3.2 The last pair should be (last; first + N)
4. think that pair is what you need - only use opposite angle to that you found in step 3.

Am I wrong? In other words my solution is obvious -- you just find the biggest part of the pie and eat it :) all that left - is what you need.

-
Ok, slowly I think I get it. Maybe you could have described step 3 better: "find neigborung pair...". That's why you sorted in step 2. Then, yes, it actually becomes obvious. –  Curd Jul 10 '09 at 20:55
Sorry, I not good enough to express my thought in english freely :) However -- some bottlenecks -- i lied you can't using Tom Ritter's dist in this algorithm. (1) You need always subtract (next - previous) (2) the last pair should be (last; first + N) –  Mihail Jul 10 '09 at 21:16
I believe that if you had this set: { 1, 3, 359 }, your algorithm would return [1, 359] as the smallest interval, where it should be [359, 3]. –  Seth Jul 10 '09 at 21:19
Why? We have cycling through zero -- thus [359; 3] - is 4 degrees, and [1; 359] - only two - it's smaller. There will be no challenge without cycling :) –  Mihail Jul 10 '09 at 21:24
But [1, 359] doesn't include 3 :) –  Seth Jul 10 '09 at 21:27

I have an own solution, however, I am not quite satisfied with it as it assumes that d will never be larger than N/4:

``````if(v[0]>=N/4 && v[0]<(3*N)/4)
{
calculate min and max of all v[i]
c = (max + min)/2;
d = (max - min)/2;
}
else
{
calculate min and max of all (v[i] + N/2) % N
c = ((max + min)/2 - N/2;
d = ((max - min)/2 - N/2;
}
``````

Any better solution, especially one that would work also if d turns out to be > N/4?

-

Your problem seems equivalent to finding the maximum distance between two of your angles.

You should just be able to iterate through your v set, compute the distance between each element, then find the largest distance.

You might try something like this for your distance function:

``````void dist_mod_360(int a, int b)
{
const int n = 360;
return min((a - b) % n, (b - a) % n);
}
``````
-
No. My distance function is fine and it works perfectly (also close to 0 and 360). What I am looking for is a good (ideally O(n)) algorithm to find c and d. –  Curd Jul 10 '09 at 22:19
Guess you mean "compute the distance between each pair of elements". Ok. This is about what Mihail proposed. This, however, takes O(n*(n-1)) (if n is the number of values). –  Curd Jul 10 '09 at 22:23
``````angle = max(v) - min(v)
return angle if angle <=180 else 360 - angle # to get the smallest absolute value
``````
-