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I have doubles that represent latitudes and longitudes.
I can easily limit longitudes to (-180.0, 180.0] with the following function.

double limitLon(double lon)
{
  return fmod(lon - 180.0, 360.0) + 180.0;
}

This works because one end is exclusive and the other is inclusive. fmod includes 0 but not -360.0.

Can anyone think of an elegant method for latitude?
The required interval is [-90.0, 90.0]. A closed form solution would be best, i.e. no loop. I think fmod() is probably a non-starter because both ends are inclusive now.

Edit: As was pointed out, one can't go to 91 degrees latitude anyway. Technically 91 should map to 89.0. Oh boy, that changes things.

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1  
What would you expect 91 to translate to? If you go over the pole by one degree you'd be back at 89 not -89. – D Stanley Nov 13 '12 at 20:54
    
Excellent point. Latitudes do not wrap since you can't really "cross" a pole. One can, however, cross the international date line. – William Nov 13 '12 at 20:55
    
did you mean fmod(lon + 180.0, 360.0) - 180.0; ? – Paul Apr 26 at 15:59
up vote 2 down vote accepted

How about using the sin and inverse functions?

asin(sin((lat/180.0)*3.14159265)) * (180.0/3.14159265);
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asin returns radians, sin expect radians. – lhf Nov 13 '12 at 20:56
    
Easy enough to convert. – William Nov 13 '12 at 21:00
    
This is certainly the right track. The trigonometry functions are inclusive on both ends. – William Nov 13 '12 at 21:02
1  
I executed this, as written with lat set to 90, on Mac OS X 10.6.8, and it returned a value slightly over 90, (90.0000001 and a bit more), largely because the value written for π, 3.14159265, is too small. Correcting this to 3.1415926535897932384626433 resulted in 90. However, it should be noted that this expression still introduces rounding errors (with other values for lat) even with that change. – Eric Postpischil Nov 14 '12 at 1:34
1  
This error (90.0000001) amounts to about 11 millimetres on Planet Earth. Just sayin. – TonyK Nov 20 '12 at 16:19

There is a much, much more efficient way to do this than using sin and arcsin. The most expensive operation is a single division. The observation that the required interval is closed is key.

  • Divide by 360 and take the remainder. This yields a number in the interval [0, 360), which is half-open, as observed.

  • Fold the interval in half. If the remainder is >=180, subtract it from 360. This maps the interval [180, 360) to the interval (0, 180]. The union of this interval with the bottom half is the closed interval [0, 180].

  • Subtract 90 from the result. This interval is [-90, 90], as desired.

This is, indeed, the exact same function as arcsin(sin(x)), but without the expense or any issue with numeric stability.

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Neither answer provided (D Stanley, eh9) works ... though for eh9's I might be misinterpreting something. Try them with multiple values.

The proper answers are unfortunately expensive. See the following from Microsoft Research: http://research.microsoft.com/en-us/projects/wraplatitudelongitude/.

From there, the answers are:
latitude_new = atan(sin(latitude)/fabs(cos(latitude))) -- note the absolute value around cos(latitude)

longitude_new = atan2(sin(latitude),cos(latitude))

Note that in C you may want to use atan2f (float vs double). Also, all trig functions take radians.

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I just came back to close that parenthesis missing from the source ... thanks @Makyen (and for the code display fix). – AdamC Jun 29 '15 at 15:34

Using trig functions sin()/cos() is expensive in time and introduces loss of precision. Much better to use the remainder() function. Note the result has the same sign as x and magnitude less than the magnitude of y, if able.

OP was on the right track! The below solution is easy to adjust per the edge values of -180 and + 180.0.

#include <math.h>

// Reduce to (-180.0, 180.0]
double Limit_Longitude(double longitude_degrees) {
  // A good implementation of `fmod()` will introduce _no_ loss of precision.
  // -360.0 <= longitude_reduced <=- 360.0
  double longitude_reduced = fmod(longitude_degrees, 360.0);

  if (longitude_reduced > 180.0) {
    longitude_reduced -= 360.0;
  } else if (longitude_reduced <= -180.0) {
    longitude_reduced += 360.0;
  }
  return longitude_reduced;
}

Limiting Latitude to [-90 to +90] is trickier as a latitude of +91 degrees is going over the North Pole but switching the longitude +/- 180 degrees. To preserve longitude precision, adjust by 180 toward 0 degrees.

void Limit_Latitude_Longitude(double *latitude_degrees,
    double *longitude_degrees) {
  *latitude_degrees = Limit_Longitude(*latitude_degrees);
  int flip = 0;
  if (*latitude_degrees > 90.0) {
    *latitude_degrees = 180.0 - *latitude_degrees;
    flip = 1;
  } else if (*latitude_degrees < -90.0) {
    *latitude_degrees = -180.0 - *latitude_degrees;
    flip = 1;
  }
  if (flip) {
    *longitude_degrees += *longitude_degrees > 0 ? -180.0 : 180.0;
  }
  *longitude_degrees = Limit_Longitude(*longitude_degrees);
}
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