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Is there an algorithm to determine the minimum bounding rectangle around a set of latitude/longitude coordinates?

It is OK to assume a flat earth since the coordinates will not be too far apart. Pseudocode is OK, but if someone has done this in Objective-C, that would be even better. What I am trying to do is set the zoom level of a map based on the number of points that will be displayed on the map.

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1  
I'm sure this is no longer of great concern to you (2 years later), but you should know it is possible - in theory at least - for all listed answers to fail spectacularly. Consider one or more polygons over the Pacific with a lower-left X of +170 and an upper-right X of -170. It will melt your brain trying to make your bounding box fit. This article: stonybrook.edu/libmap/coordinates/seriesa/no2/a2.htm (Global Gotchas section) implies the problem cannot, and shouldn't need to, be solved. –  tomfumb Dec 10 '11 at 2:47

7 Answers 7

This will find the smallest latitude/longitude for your top left point and the largest latitude/longitude for your bottom right point.

double minLat = 900;
double minLon = 900;
double maxLat = -900;
double maxLon = -900;
foreach(Point point in latloncollection )
{
    minLat = Math.min( minLat, point.lat );
    minLon = Math.min( minLon, point.lon );
    maxLat = Math.max( maxLat, point.lat );
    maxLon = Math.max( maxLon, point.lon );
}
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Even if we know for sure that lat and lon absolute values won't go above 900, I think it would be nicer to initiate the min and max values to the first point of the list, and then try to find better ones starting at the second item in the list. –  mbritto Jul 7 '12 at 15:23

This is the method that I use in one of my apps.

- (void)centerMapAroundAnnotations
{
    // if we have no annotations we can skip all of this
    if ( [[myMapView annotations] count] == 0 )
    	return;

    // then run through each annotation in the list to find the
    // minimum and maximum latitude and longitude values
    CLLocationCoordinate2D min;
    CLLocationCoordinate2D max; 
    BOOL minMaxInitialized = NO;
    NSUInteger numberOfValidAnnotations = 0;

    for ( id<MKAnnotation> a in [myMapView annotations] )
    {
    	// only use annotations that are of our own custom type
    	// in the event that the user is browsing from a location far away
        // you can omit this if you want the user's location to be included in the region 
    	if ( [a isKindOfClass: [ECAnnotation class]] )
    	{
    		// if we haven't grabbed the first good value, do so now
    		if ( !minMaxInitialized )
    		{
    			min = a.coordinate;
    			max = a.coordinate;
    			minMaxInitialized = YES;
    		}
    		else // otherwise compare with the current value
    		{
    			min.latitude = MIN( min.latitude, a.coordinate.latitude );
    			min.longitude = MIN( min.longitude, a.coordinate.longitude );

    			max.latitude = MAX( max.latitude, a.coordinate.latitude );
    			max.longitude = MAX( max.longitude, a.coordinate.longitude );
    		}
    		++numberOfValidAnnotations;
    	}
    }

    // If we don't have any valid annotations we can leave now,
    // this will happen in the event that there is only the user location
    if ( numberOfValidAnnotations == 0 )
    	return;

    // Now that we have a min and max lat/lon create locations for the
    // three points in a right triangle
    CLLocation* locSouthWest = [[CLLocation alloc] 
    							initWithLatitude: min.latitude 
    							longitude: min.longitude];
    CLLocation* locSouthEast = [[CLLocation alloc] 
    							initWithLatitude: min.latitude 
    							longitude: max.longitude];
    CLLocation* locNorthEast = [[CLLocation alloc] 
    							initWithLatitude: max.latitude 
    							longitude: max.longitude];

    // Create a region centered at the midpoint of our hypotenuse
    CLLocationCoordinate2D regionCenter;
    regionCenter.latitude = (min.latitude + max.latitude) / 2.0;
    regionCenter.longitude = (min.longitude + max.longitude) / 2.0;

    // Use the locations that we just created to calculate the distance
    // between each of the points in meters.
    CLLocationDistance latMeters = [locSouthEast getDistanceFrom: locNorthEast];
    CLLocationDistance lonMeters = [locSouthEast getDistanceFrom: locSouthWest];

    MKCoordinateRegion region;
    region = MKCoordinateRegionMakeWithDistance( regionCenter, latMeters, lonMeters );

    MKCoordinateRegion fitRegion = [myMapView regionThatFits: region];
    [myMapView setRegion: fitRegion animated: YES];

    // Clean up
    [locSouthWest release];
    [locSouthEast release];
    [locNorthEast release];
}
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Great code snippet, thanks for sharing it. –  Goles Feb 24 '10 at 13:27
1  
Just received a message from Butch Anton -- getDistanceFrom: has been deprecated as of iPhone OS 3.2. Your code should now use distanceFromLocation: instead. –  jessecurry Jul 22 '10 at 13:31
public BoundingRectangle calculateBoundingRectangle()
    {
        Coordinate bndRectTopLeft = new Coordinate();
        Coordinate bndRectBtRight = new Coordinate();

        // Initialize bounding rectangle with first point
        Coordinate firstPoint = getVertices().get(0);
        bndRectTopLeft.setLongitude(firstPoint.getLongitude());
        bndRectTopLeft.setLatitude(firstPoint.getLatitude());
        bndRectBtRight.setLongitude(firstPoint.getLongitude());
        bndRectBtRight.setLatitude(firstPoint.getLatitude());

        double tempLong;
        double tempLat;
        // Iterate through all the points
        for (int i = 0; i < getVertices().size(); i++)
        {
            Coordinate curNode = getVertices().get(i);

            tempLong = curNode.getLongitude();
            tempLat = curNode.getLatitude();
            if (bndRectTopLeft.getLongitude() > tempLong) bndRectTopLeft.setLongitude(tempLong);
            if (bndRectTopLeft.getLatitude() < tempLat) bndRectTopLeft.setLatitude(tempLat);
            if (bndRectBtRight.getLongitude() < tempLong) bndRectBtRight.setLongitude(tempLong);
            if (bndRectBtRight.getLatitude() > tempLat) bndRectBtRight.setLatitude(tempLat);

        }

        bndRectTopLeft.setLatitude(bndRectTopLeft.getLatitude());
        bndRectBtRight.setLatitude(bndRectBtRight.getLatitude());

        // Throw an error if boundaries contains poles
        if ((Math.toRadians(topLeft.getLatitude()) >= (Math.PI / 2)) || (Math.toRadians(bottomRight.getLatitude()) <= -(Math.PI / 2)))
        {
            // Error
            throw new Exception("boundaries contains poles");
        }
        // Now calculate bounding x coordinates
        // Calculate it along latitude circle for the latitude closure to the
        // pole
        // (either north or south). For the other end the loitering distance
        // will be slightly higher
        double tempLat1 = bndRectTopLeft.getLatitude();
        if (bndRectBtRight.getLatitude() < 0)
        {
            if (tempLat1 < (-bndRectBtRight.getLatitude()))
            {
                tempLat1 = (-bndRectBtRight.getLatitude());
            }
        }

        bndRectTopLeft.setLongitude(bndRectTopLeft.getLongitude());
        bndRectBtRight.setLongitude(bndRectBtRight.getLongitude());
        // What if international date line is coming in between ?
        // It will not affect any calculation but the range for x coordinate for the bounding rectangle will be -2.PI to +2.PI
        // But the bounding rectangle should not cross itself
        if ((Math.toRadians(bottomRight.getLongitude()) - Math.toRadians(topLeft.getLongitude())) >= (2 * Math.PI))
        {
            // Throw some error
            throw new Exception("Bounding Rectangle crossing itself");
        }

        return new BoundingRectangle(bndRectTopLeft, bndRectBtRight);
    }

This will handle exception if region crossing poles...

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Since the OP wants to use the bounding rectangle to set on the map, the algorithm needs to take into account the fact that latitude and longitudes are in a spherical coordinate system and the map uses a 2 dimensional coordinate system. None of the solutions posted so far take this into account and thus end up with a wrong bounding rectangle but fortunately it is quite easy to create a valid solution using the MKMapPointForCoordinate method found in this sample code from the WWDC 2013 "Whats new in MapKit" session video.

MKMapRect MapRectBoundingMapPoints(MKMapPoint points[], NSInteger pointCount){
    double minX = INFINITY, maxX = -INFINITY, minY = INFINITY, maxY = -INFINITY;
    NSInteger i;
    for(i = -; i< pointCount; i++){
        MKMapPoint p = points[i];
        minX = MIN(p.x,minX);
        minY = MIN(p.y,minY);
        maxX = MAX(p.x,maxX);
        maxY = MAX(p.y,maxY);
    }
    return MKMapRectMake(minX,minY,maxX - minX,maxY-minY);
}


CLLocationCoordinate2D london = CLLocationCoordinate2DMake(51.500756,-0.124661);
CLLocationCoordinate2D paris = CLLocationCoordinate2DMake(48.855228,2.34523);
MKMapPoint points[] = {MKMapPointForCoordinate(london),MKMapPointForCoordinate(paris)};
MKMapRect rect = MapRectBoundingMapPoints(points,2);
rect = MKMapRectInset(rect,
    -rect.size.width * 0.05,
    -rect.size.height * 0.05);
MKCoordinateRegion coordinateRegion = MKCoordinateRegionForMapRect(rect);

You can easily change the method to work on an NSArray of annotations if you prefer. E.g. here is the method I am using in my application:

- (MKCoordinateRegion)regionForAnnotations:(NSArray*)anns{
    MKCoordinateRegion r;
    if ([anns count] == 0){
        return r;
    }

    double minX = INFINITY, maxX = -INFINITY, minY = INFINITY, maxY = -INFINITY;
    for(id<MKAnnotation> a in anns){
        MKMapPoint p = MKMapPointForCoordinate(a.coordinate);
        minX = MIN(p.x,minX);
        minY = MIN(p.y,minY);
        maxX = MAX(p.x,maxX);
        maxY = MAX(p.y,maxY);
    }
    MKMapRect rect = MKMapRectMake(minX,minY,maxX - minX,maxY-minY);
    rect = MKMapRectInset(rect,
                          -rect.size.width * 0.05,
                          -rect.size.height * 0.05);
    return MKCoordinateRegionForMapRect(rect);
}
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For what you want to do, you could probably just find the minimum and maximum values for Lat and Long and use those as the bounds of your rectangle. For more sophisticated solutions, see:

http://stackoverflow.com/questions/1298003/calculate-minimum-area-rectangle-for-a-polygon

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If you're in Objective-C then you might be able to use Objective-C++ instead, in which case you can use the STL to do a lot of the heavy lifting for you:

#include <vector>
#include <algorithm>

std::vector<float> latitude_set;
std::vector<float> longitude_set;

latitude_set.push_back(latitude_a);
latitude_set.push_back(latitude_b);
latitude_set.push_back(latitude_c);
latitude_set.push_back(latitude_d);
latitude_set.push_back(latitude_e);

longitude_set.push_back(longitude_a);
longitude_set.push_back(longitude_b);
longitude_set.push_back(longitude_c);
longitude_set.push_back(longitude_d);
longitude_set.push_back(longitude_e);

float min_latitude = *std::min_element(latitude_set.begin(), latitude_set.end());
float max_latitude = *std::max_element(latitude_set.begin(), latitude_set.end());

float min_longitude = *std::min_element(longitude_set.begin(), longitude_set.end());
float max_longitude = *std::max_element(longitude_set.begin(), longitude_set.end());
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Regular C++ has libraries as well. Also, how is coding this statically a good idea? –  Foredecker Aug 20 '09 at 0:18
    
This is standard-compliant C++. The static filling of latitude and longitude vectors serve merely for the example... you can add items to the vector any way you'd prefer. –  fbrereto Aug 20 '09 at 2:42
    
I'm not sure I see the heavy lifting angle when the simpler ObjC code is lighter... any way you cut it you are looking at all point values. –  Kendall Helmstetter Gelner Aug 20 '09 at 7:55

All you need to do is get the left-most, top-most, right-most, and bottom-most values. You could accomplish this pretty easily by sorting, and so long as the set isn't too big, it wouldn't be very expensive.

If you give your lat/long class methods called compareLatitude: and compareLongitude:, it'd be even easier.

CGFloat north, west, east, south;  
[latLongCollection sortUsingSelector:@selector(compareLongitude:)];  
west = [[latLongCollection objectAtIndex:0] longitude];  
east = [[latLongCollection lastObject] longitude];  
[latLongCollection sortUsingSelector:@selector(compareLatitude:)];  
south = [[latLongCollection objectAtIndex:0] latitude];  
north = [[latLongCollection lastObject] latitude];

Something like that should work, assuming your collection of coordinates is an NSMutableArray.

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my array is NSMutableArray of MKAnnotation objects. I'd have to think of the best way to implement those selector methods to do the comparison. It's not too much different than just iterating through the list manually, but this is a little more "elegant." –  Matthew Belk Aug 20 '09 at 3:06

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