135

Given 2 angles in the range -PI -> PI around a coordinate, what is the value of the smallest of the 2 angles between them?

Taking into account that the difference between PI and -PI is not 2 PI but zero.

Example:

Imagine a circle, with 2 lines coming out from the center, there are 2 angles between those lines, the angle they make on the inside aka the smaller angle, and the angle they make on the outside, aka the bigger angle. Both angles when added up make a full circle. Given that each angle can fit within a certain range, what is the smaller angles value, taking into account the rollover

  • 2
    I read 3 times before I understood what you meant. Please add an example, or explain better... – Kobi Dec 10 '09 at 6:12
  • Imagine a circle, with 2 lines comign out from the center, there are 2 angles between those lines, the angle they make on the inside aka the smaller angle, and the angle they make on the outside, aka the bigger angle. Both angles when added up make a full circle. Given that each angle can fit within a certain range, what is the smaller angles value, taking into account the rollover – Tom J Nowell Dec 10 '09 at 6:14
  • Possible duplicate of How to calculate the angle between a line and the horizontal axis? – Jim G. Jul 9 '17 at 20:33
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    @JimG. this isn't the same question, in this question the angle P1 used in the other question would be the incorrect answer, it would be the other, smaller angle. Also, there is no guarantee that the angle is with the horizontal axis – Tom J Nowell Jul 9 '17 at 21:46
187

This gives a signed angle for any angles:

a = targetA - sourceA
a = (a + 180) % 360 - 180

Beware in many languages the modulo operation returns a value with the same sign as the dividend (like C, C++, C#, JavaScript, full list here). This requires a custom mod function like so:

mod = (a, n) -> a - floor(a/n) * n

Or so:

mod = (a, n) -> (a % n + n) % n

If angles are within [-180, 180] this also works:

a = targetA - sourceA
a += (a>180) ? -360 : (a<-180) ? 360 : 0

In a more verbose way:

a = targetA - sourceA
a -= 360 if a > 180
a += 360 if a < -180
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  • Simpler and makes more sense read out loud, though effectively the same thing, first bti figures out the angle, second part makes sure its always the smaller of the 2 possible angles – Tom J Nowell Oct 25 '11 at 11:48
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    although one might want to do a % 360, e.g. if I had the angle 0 and the target angle 721, the correct answer would be 1, the answer given by the above would be 361 – Tom J Nowell Oct 25 '11 at 11:51
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    A more concise, though potentially more expensive, equivalent of the latter approach's second statement, is a -= 360*sgn(a)*(abs(a) > 180). (Come to think of it, if you've branchless implementations of sgn and abs, then that characteristic might actually start to compensate for needing two multiplications.) – mmirate Jul 25 '16 at 19:51
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    The "Signed angle for any angle" example seems to work in most scenarios, with one exception. In scenario double targetA = 2; double sourceA = 359; 'a' will be equal to -357.0 instead of 3.0 – Stevoisiak Apr 26 '17 at 21:49
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    In C++ you can use std::fmod(a,360), or fmod(a,360) to use floating point modulo. – Joeppie Mar 23 '18 at 12:27
143

x is the target angle. y is the source or starting angle:

atan2(sin(x-y), cos(x-y))

It returns the signed delta angle. Note that depending on your API the order of the parameters for the atan2() function might be different.

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    x-y gives you the difference in angle, but it may be out of the desired bounds. Think of this angle defining a point on the unit circle. The coordinates of that point are (cos(x-y), sin(x-y)). atan2 returns the angle for that point (which is equivalent to x-y) except its range is [-PI, PI]. – Max Sep 2 '13 at 16:17
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    This passes the test suite gist.github.com/bradphelan/7fe21ad8ebfcb43696b8 – bradgonesurfing Jul 13 '15 at 8:43
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    a one line simple solution and solved for me(not the selected answer ;) ). but tan inverse is a costly process. – Mohan Kumar Jun 20 '16 at 16:32
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    For me, the most elegant solution. Shame it might be computationally expensive. – focs Jul 4 '16 at 8:51
  • For me the most elegant solution as well! Solved my problem perfectly (wanted to have a formula that gives me the signed turn angle which is the smaller one from the two possible turn directions/angles). – Jürgen Brauer May 4 '17 at 7:46
39

If your two angles are x and y, then one of the angles between them is abs(x - y). The other angle is (2 * PI) - abs(x - y). So the value of the smallest of the 2 angles is:

min((2 * PI) - abs(x - y), abs(x - y))

This gives you the absolute value of the angle, and it assumes the inputs are normalized (ie: within the range [0, 2π)).

If you want to preserve the sign (ie: direction) of the angle and also accept angles outside the range [0, 2π) you can generalize the above. Here's Python code for the generalized version:

PI = math.pi
TAU = 2*PI
def smallestSignedAngleBetween(x, y):
    a = (x - y) % TAU
    b = (y - x) % TAU
    return -a if a < b else b

Note that the % operator does not behave the same in all languages, particularly when negative values are involved, so if porting some sign adjustments may be necessary.

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    @bradgonesurfing That is/was true, but to be fair your tests checked for things that weren't specified in the original question, specifically non-normalized inputs and sign-preservation. The second version in the edited answer should pass your tests. – Laurence Gonsalves Jul 23 '15 at 19:20
  • The second version also doesn't work for me. Try 350 and 0 for example. It should return -10 but returns -350 – kjyv Oct 26 '19 at 0:06
  • @kjyv I can't reproduce the behavior you describe. Can you post the exact code? – Laurence Gonsalves Nov 11 '19 at 23:51
  • Ah, I'm sorry. I've tested exactly your version with rad and degrees in python again and it worked fine. So must have been a mistake in my translation to C# (don't have it anymore). – kjyv Nov 13 '19 at 13:11
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    Note that, as of Python 3, you can actually use tau natively! Just write from math import tau. – mhartl Jan 8 at 19:15
8

I rise to the challenge of providing the signed answer:

def f(x,y):
  import math
  return min(y-x, y-x+2*math.pi, y-x-2*math.pi, key=abs)
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    Ah... the answer is a Python function by the way. Sorry, I was in Python mode for a moment. Hope that's okay. – David Jones Jan 5 '10 at 16:20
  • I shall plug the new formula into my code upstairs and see what becomes of it! ( thankyou ^_^ ) – Tom J Nowell Jan 5 '10 at 17:25
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    I'm pretty sure PeterB's answer is correct too. And evilly hackish. :) – David Jones Jan 5 '10 at 18:04
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    But this one contains no trig functions :) – nornagon Mar 10 '10 at 23:34
  • What is the equivalent formula for java? if angles are in degree.? – Soley Mar 16 '15 at 21:08
6

For UnityEngine users, the easy way is just to use Mathf.DeltaAngle.

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  • Has no signed output tho – kjyv Oct 25 '19 at 22:44
5

Arithmetical (as opposed to algorithmic) solution:

angle = Pi - abs(abs(a1 - a2) - Pi);
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1

An efficient code in C++ that works for any angle and in both: radians and degrees is:

inline double getAbsoluteDiff2Angles(const double x, const double y, const double c)
{
    // c can be PI (for radians) or 180.0 (for degrees);
    return c - fabs(fmod(fabs(x - y), 2*c) - c);
}
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-1

There is no need to compute trigonometric functions. The simple code in C language is:

#include <math.h>
#define PIV2 M_PI+M_PI
#define C360 360.0000000000000000000
double difangrad(double x, double y)
{
double arg;

arg = fmod(y-x, PIV2);
if (arg < 0 )  arg  = arg + PIV2;
if (arg > M_PI) arg  = arg - PIV2;

return (-arg);
}
double difangdeg(double x, double y)
{
double arg;
arg = fmod(y-x, C360);
if (arg < 0 )  arg  = arg + C360;
if (arg > 180) arg  = arg - C360;
return (-arg);
}

let dif = a - b , in radians

dif = difangrad(a,b);

let dif = a - b , in degrees

dif = difangdeg(a,b);

difangdeg(180.000000 , -180.000000) = 0.000000
difangdeg(-180.000000 , 180.000000) = -0.000000
difangdeg(359.000000 , 1.000000) = -2.000000
difangdeg(1.000000 , 359.000000) = 2.000000

No sin, no cos, no tan,.... only geometry!!!!

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    Bug! Since you #define PIV2 as "M_PI+M_PI", not "(M_PI+M_PI)", the line arg = arg - PIV2; expands to arg = arg - M_PI + M_PI, and so does nothing. – canton7 Jan 19 '14 at 11:53

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