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Is there an easy way to convert an angle (in degrees) to be between -179 and 180? I'm sure I could use mod (%) and some if statements, but it gets ugly:


//Make angle between 0 and 360
angle%=360;

//Make angle between -179 and 180
if (angle>180) angle-=360;

It just seems like there should be a simple math operation that will do both statements at the same time. I may just have to create a static method for the conversion for now.

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4  
IMHO That's not ugly. That's quite clean and clear. –  C. Ross Feb 23 '10 at 19:22
4  
What if the starting angle is less then -179? –  Matthew Whited Feb 23 '10 at 19:26
    
After consulting the docs I am with Matthew Whited - angle % 360 yields a value between -359 and +359, not 0 and +359. Hence your solution fails to normalize initial values smaller then -179. –  Daniel Brückner Feb 23 '10 at 19:43
    
@Daniel: Good point. The given example is not good enough. Feel free to suggest something that is better. –  User1 Feb 23 '10 at 20:15

12 Answers 12

up vote 20 down vote accepted

I'm a little late to the party, I know, but...

Most of these answers are no good, because they try to be clever and concise and then don't take care of edge cases.

It's a little more verbose, but if you want to make it work, just put in the logic to make it work. Don't try to be clever.

int normalizeAngle(int angle)
{
    int newAngle = angle;
    while (newAngle <= -180) newAngle += 360;
    while (newAngle > 180) newAngle -= 360;
    return newAngle;
}

This works and is reasonably clean and simple, without trying to be fancy. Note that only zero or one of the while loops can ever be run.

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+1, best answer so far! –  Jim Lewis Feb 23 '10 at 19:53
1  
And it handles angles with non-integer degrees! –  Aniko Feb 23 '10 at 20:10
    
could you start with newAngle = angle % 360 at the beginning so you don't have to worry about normalizeAngle(Integer.MAX_VALUE) ? that would fall in the "don't take care of edge cases" category probably. –  Jimmy Feb 23 '10 at 21:28
2  
-1: This answer is ridiculously slow for angles that are not near 0. This is the solution for people who oppose division on religious grounds. –  GregS Feb 24 '10 at 1:10
3  
Its pretty slow for a large number. :( –  Peter Lawrey May 14 '10 at 6:21
// reduce the angle  
angle =  angle % 360; 

// force it to be the positive remainder, so that 0 <= angle < 360  
angle = (angle + 360) % 360;  

// force into the minimum absolute value residue class, so that -180 < angle <= 180  
if (angle > 180)  
    angle -= 360;  
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That's the correct answer with the least calculations necessary. –  tzot Aug 27 '10 at 7:50
    
Seems like the best solution here to me. –  Steve Nov 2 '11 at 6:07
2  
@PlatinumAzure: No, it is not redundant. Suppose the angle is -5000? –  GregS Feb 16 '12 at 22:57

Try this instead!

atan2(sin(angle), cos(angle))

atan2 has a range of [-π, π). This takes advantage of the fact that tan θ = sin θ / cos θ, and that atan2 is smart enough to know which quadrant θ is in.

Since you want degrees, you will want to convert your angle to and from radians:

atan2(sin(angle * PI/180.0), cos(angle * PI/180.0)) * 180.0/PI

Update My previous example was perfectly legitimate, but restricted the range to ±90°. atan2's range is the desired value of -179° to 180°. Preserved below.


Try this:

asin(sin(angle)))

The domain of sin is the real line, the range is [-1, 1]. The domain of asin is [-1, 1], and the range is [-PI/2, PI/2]. Since asin is the inverse of sin, your input isn't changed (much, there's some drift because you're using floating point numbers). So you get your input value back, and you get the desired range as a side effect of the restricted range of the arcsine.

Since you want degrees, you will want to convert your angle to and from radians:

asin(sin(angle * PI/180.0)) * 180.0/PI

(Caveat: Trig functions are bazillions of times slower than simple divide and subtract operations, even if they are done in an FPU!)

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+1 for taking advantage of limited-range functions for normalizing. A bit of overhead is involved, but this is by far the most concise answer that is actually correct. –  Platinum Azure Feb 23 '10 at 19:43
1  
+1 clean but slow. I'm tempted to choose this answer. –  User1 Feb 23 '10 at 20:17
    
Even better now, since the value is in the correct range. However, now you're doing three trig functions instead of two! –  Seth Feb 23 '10 at 21:22

Not that smart, too, but no if.

angle = (angle + 179) % 360 - 179;

But I am not sure how Java handles modulo for negative numbers. This works only if -1 modulo 360 equals 359.

UPDATE

Just checked the docs and a % b yields a value between -(|b| - 1) and +(|b| - 1) hence the code is broken. To account for negative values returned by the modulo operator one has to use the following.

angle = ((angle + 179) % 360 + 360) % 360 - 179;

But ... no ... never ... Use something similar to your initial solution, but fixed for values smaller then -179.

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too cryptic IMO. –  missingfaktor Feb 23 '10 at 19:24
    
It should be "angle = (angle + 179) % 360 - 179". Otherwise 180 gets converted to -180. –  Romulo Ceccon Feb 23 '10 at 19:25
    
Already fixed that. –  Daniel Brückner Feb 23 '10 at 19:26
    
Too cryptic IMO. ... I absolutely agree. Still thinking about a better solution. –  Daniel Brückner Feb 23 '10 at 19:27
1  
this fails if the starting angle is less then -179 –  Matthew Whited Feb 23 '10 at 19:27

Maybe not helpful, but I always liked using non-degree angles.

An angle range from 0 to 255 can be kept in bounds using bitwise operations, or for a single byte variable, simple allowed to overflow.

An angle range from -128 to 127 isn't quite so easy with bitwise ops, but again, for a single-byte variable, you can let it overflow.

I thought it was a great idea many years back for games, where you're probably using a lookup table for angles. These days, not so good - the angles are used differently, and are float anyway.

Still - maybe worth a mention.

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+1 that is a very interesting idea, and if more granularity is needed than more bits can be used -- two bytes for example give 65536 distinct angles. –  GregS Feb 25 '10 at 2:03

A short way which handles negative numbers is

double mod = x - Math.floor((x + 179.0) / 360) * 360;

Cast to taste.

BTW: It appears that angles between (180.0, 181.0) are undefined. Shouldn't the range be (-180, 180] (exclusive, inclusive]

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int angle = -394;

// shortest
angle %= 360;
angle = angle < -170 ? angle + 360 : (angle > 180 ? angle - 380 : angle);

// cleanest
angle %= 360;
if (angle < -179) angle += 360;
else if (angle > 180) angle -= 360;
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Your 'shortest' answer should have angle < -179 instead of angle < -170. –  Cory B Jun 24 at 21:37

This works with both negative and decimal numbers and doesn't require loops, nor trigonometric functions:

angle -= Math.floor(angle / 360 + 0.5) * 360

The result is in the [-180, 180) interval. For (-180, 180] interval, you can use this instead:

angle -= Math.ceil(angle / 360 - 0.5) * 360

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Just a note that angle must be a float for this or integer math will kick in. Use angle -= Math.ceil((double)angle / 360 - 0.5) * 360 or something for best security. I love the answer, though. Should be #1 –  Cory B Jun 24 at 21:26

Here is an integer-only solution:

int normalize(int angle)
{
    angle %= 360;
    int fix = angle / 180; // Integer division!!
    return (fix) ? angle - (360 * (fix)) : angle;
}

Sometimes being clever is just more fun, Platinum Azure.

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How about

(angle % 360) - 179

This will actually return different results than the naive approach presented in the question, but it will keep the angle between the bounds specified. (I suppose that might make this the wrong answer, but I will leave it here in case it solves another persons' similar problem).

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2  
I think you mean ( (angle + 180) % 360 ) - 180 –  Jefromi Feb 23 '10 at 19:23
    
And there's the off-by-one issue (fixed in Daniel's answer). –  Jefromi Feb 23 '10 at 19:28

Well, one more solution, this one with just one division and no loops.

static double normalizeAngle(double angle)
{
    angle %= 360.0; // [0..360) if angle is positive, (-360..0] if negative
    if (angle > 180.0) // was positive
        return angle - 360.0; // was (180..360) => returning (-180..0)
    if (angle <= -180.0) // was negative
        return angle + 360.0; // was (-360..180] => returning (0..180]
    return angle; // (-180..180]
}
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I know that years have passed, but still.

This solution contains no loops, no subtracting, no modulo (allows to normalize to radians interval). Works for any input, including negative values, big values, edge cases.

double normalizedAngle = angle - (ceil((angle + M_PI)/(2*M_PI))-1)*2*M_PI;  // (-Pi;Pi]:
double normalizedAngle = angle - (ceil((angle + 180)/360)-1)*360;           // (-180;180]:

double normalizedAngle = angle - (floor((angle + M_PI)/(2*M_PI)))*2*M_PI;  // [-Pi;Pi):
double normalizedAngle = angle - (floor((angle + 180)/360))*360;           // [-180;180):
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