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I want to set the map view zoomed to 1km radius but cant figure out how?

The doc says that the zoom level 1 will map earths equator to 256 pixels. So how do I calculate which zoom level I need to set so that the map view shows area in 1KM radius?

UPDATE:
After reading a few blog posts I wrote the following code:

private int calculateZoomLevel() {
    double equatorLength = 6378140; // in meters
    double widthInPixels = screenWidth;
    double metersPerPixel = equatorLength / 256;
    int zoomLevel = 1;
    while ((metersPerPixel * widthInPixels) > 2000) {
        metersPerPixel /= 2;
        ++zoomLevel;
    }
    Log.i("ADNAN", "zoom level = "+zoomLevel);
    return zoomLevel;
}

The idea is that first I calculate Meters per pixel in the zoom level 1, which according to google shows equator of earth using 256 pixels. Now every subsequent zoom level magnifies by a level of 2 so I half the meters per pixel for every zoom level. I do this until I have a zoom level where meters per pixel multiplied by the screen width gives me less than 2000 i.e 2 Km across.

But I dont think that the zoom level I am getting is showing the map of 2Km radius. Can some one tell me what I am doing wrong here?

share|improve this question
1  
your idea is ok, but the problem is the equatorLength you have set, the correct value is around 40075004 meters. (wikipedia) –  Logko Jun 12 '11 at 22:11

5 Answers 5

I ended up using the utils from:

https://github.com/googlemaps/android-maps-utils

I extracted the class from the lib, so you don't need the whole library. Instead of setting zoom level, you use bounds. The result is the same.

Code to show exactly 1 kilometer:

animateToMeters(1000);

private void animateToMeters(int meters){
    int mapHeightInDP = 200;
    Resources r = getResources();
    int mapSideInPixels = (int) TypedValue.applyDimension(TypedValue.COMPLEX_UNIT_DIP, mapHeightInDP, r.getDisplayMetrics());

    LatLng point = new LatLng(0, 0);
    LatLngBounds latLngBounds = calculateBounds(point, meters);
    if(latLngBounds != null){
        cameraUpdate = CameraUpdateFactory.newLatLngBounds(latLngBounds, mapSideInPixels, mapSideInPixels, MARKER_BOUNDS);
        if(mMap != null)
            mMap.animateCamera(cameraUpdate); 
    }
}

private LatLngBounds calculateBounds(LatLng center, double radius) {
    return new LatLngBounds.Builder().
      include(SphericalUtil.computeOffset(center, radius, 0)).
      include(SphericalUtil.computeOffset(center, radius, 90)).
      include(SphericalUtil.computeOffset(center, radius, 180)).
      include(SphericalUtil.computeOffset(center, radius, 270)).build();
}

The class extracted (slightly changed) from the lib:

public class SphericalUtil {

    static final double EARTH_RADIUS = 6371009;

    /**
     * Returns hav() of distance from (lat1, lng1) to (lat2, lng2) on the unit sphere.
     */
    static double havDistance(double lat1, double lat2, double dLng) {
        return hav(lat1 - lat2) + hav(dLng) * cos(lat1) * cos(lat2);
    }

    /**
     * Returns haversine(angle-in-radians).
     * hav(x) == (1 - cos(x)) / 2 == sin(x / 2)^2.
     */
    static double hav(double x) {
        double sinHalf = sin(x * 0.5);
        return sinHalf * sinHalf;
    }

    /**
     * Computes inverse haversine. Has good numerical stability around 0.
     * arcHav(x) == acos(1 - 2 * x) == 2 * asin(sqrt(x)).
     * The argument must be in [0, 1], and the result is positive.
     */
    static double arcHav(double x) {
        return 2 * asin(sqrt(x));
    }

    private SphericalUtil() {}

    /**
     * Returns the heading from one LatLng to another LatLng. Headings are
     * expressed in degrees clockwise from North within the range [-180,180).
     * @return The heading in degrees clockwise from north.
     */
    public static double computeHeading(LatLng from, LatLng to) {
        // http://williams.best.vwh.net/avform.htm#Crs
        double fromLat = toRadians(from.latitude);
        double fromLng = toRadians(from.longitude);
        double toLat = toRadians(to.latitude);
        double toLng = toRadians(to.longitude);
        double dLng = toLng - fromLng;
        double heading = atan2(
                sin(dLng) * cos(toLat),
                cos(fromLat) * sin(toLat) - sin(fromLat) * cos(toLat) * cos(dLng));
        return wrap(toDegrees(heading), -180, 180);
    }

    /**
     * Returns the LatLng resulting from moving a distance from an origin
     * in the specified heading (expressed in degrees clockwise from north).
     * @param from     The LatLng from which to start.
     * @param distance The distance to travel.
     * @param heading  The heading in degrees clockwise from north.
     */
    public static LatLng computeOffset(LatLng from, double distance, double heading) {
        distance /= EARTH_RADIUS;
        heading = toRadians(heading);
        // http://williams.best.vwh.net/avform.htm#LL
        double fromLat = toRadians(from.latitude);
        double fromLng = toRadians(from.longitude);
        double cosDistance = cos(distance);
        double sinDistance = sin(distance);
        double sinFromLat = sin(fromLat);
        double cosFromLat = cos(fromLat);
        double sinLat = cosDistance * sinFromLat + sinDistance * cosFromLat * cos(heading);
        double dLng = atan2(
                sinDistance * cosFromLat * sin(heading),
                cosDistance - sinFromLat * sinLat);
        return new LatLng(toDegrees(asin(sinLat)), toDegrees(fromLng + dLng));
    }

    /**
     * Returns the location of origin when provided with a LatLng destination,
     * meters travelled and original heading. Headings are expressed in degrees
     * clockwise from North. This function returns null when no solution is
     * available.
     * @param to       The destination LatLng.
     * @param distance The distance travelled, in meters.
     * @param heading  The heading in degrees clockwise from north.
     */
    public static LatLng computeOffsetOrigin(LatLng to, double distance, double heading) {
        heading = toRadians(heading);
        distance /= EARTH_RADIUS;
        // http://lists.maptools.org/pipermail/proj/2008-October/003939.html
        double n1 = cos(distance);
        double n2 = sin(distance) * cos(heading);
        double n3 = sin(distance) * sin(heading);
        double n4 = sin(toRadians(to.latitude));
        // There are two solutions for b. b = n2 * n4 +/- sqrt(), one solution results
        // in the latitude outside the [-90, 90] range. We first try one solution and
        // back off to the other if we are outside that range.
        double n12 = n1 * n1;
        double discriminant = n2 * n2 * n12 + n12 * n12 - n12 * n4 * n4;
        if (discriminant < 0) {
            // No real solution which would make sense in LatLng-space.
            return null;
        }
        double b = n2 * n4 + sqrt(discriminant);
        b /= n1 * n1 + n2 * n2;
        double a = (n4 - n2 * b) / n1;
        double fromLatRadians = atan2(a, b);
        if (fromLatRadians < -PI / 2 || fromLatRadians > PI / 2) {
            b = n2 * n4 - sqrt(discriminant);
            b /= n1 * n1 + n2 * n2;
            fromLatRadians = atan2(a, b);
        }
        if (fromLatRadians < -PI / 2 || fromLatRadians > PI / 2) {
            // No solution which would make sense in LatLng-space.
            return null;
        }
        double fromLngRadians = toRadians(to.longitude) -
                atan2(n3, n1 * cos(fromLatRadians) - n2 * sin(fromLatRadians));
        return new LatLng(toDegrees(fromLatRadians), toDegrees(fromLngRadians));
    }

    /**
     * Returns the LatLng which lies the given fraction of the way between the
     * origin LatLng and the destination LatLng.
     * @param from     The LatLng from which to start.
     * @param to       The LatLng toward which to travel.
     * @param fraction A fraction of the distance to travel.
     * @return The interpolated LatLng.
     */
    public static LatLng interpolate(LatLng from, LatLng to, double fraction) {
        // http://en.wikipedia.org/wiki/Slerp
        double fromLat = toRadians(from.latitude);
        double fromLng = toRadians(from.longitude);
        double toLat = toRadians(to.latitude);
        double toLng = toRadians(to.longitude);
        double cosFromLat = cos(fromLat);
        double cosToLat = cos(toLat);

        // Computes Spherical interpolation coefficients.
        double angle = computeAngleBetween(from, to);
        double sinAngle = sin(angle);
        if (sinAngle < 1E-6) {
            return from;
        }
        double a = sin((1 - fraction) * angle) / sinAngle;
        double b = sin(fraction * angle) / sinAngle;

        // Converts from polar to vector and interpolate.
        double x = a * cosFromLat * cos(fromLng) + b * cosToLat * cos(toLng);
        double y = a * cosFromLat * sin(fromLng) + b * cosToLat * sin(toLng);
        double z = a * sin(fromLat) + b * sin(toLat);

        // Converts interpolated vector back to polar.
        double lat = atan2(z, sqrt(x * x + y * y));
        double lng = atan2(y, x);
        return new LatLng(toDegrees(lat), toDegrees(lng));
    }

    /**
     * Returns distance on the unit sphere; the arguments are in radians.
     */
    private static double distanceRadians(double lat1, double lng1, double lat2, double lng2) {
        return arcHav(havDistance(lat1, lat2, lng1 - lng2));
    }

    /**
     * Returns the angle between two LatLngs, in radians. This is the same as the distance
     * on the unit sphere.
     */
    static double computeAngleBetween(LatLng from, LatLng to) {
        return distanceRadians(toRadians(from.latitude), toRadians(from.longitude),
                               toRadians(to.latitude), toRadians(to.longitude));
    }

    /**
     * Returns the distance between two LatLngs, in meters.
     */
    public static double computeDistanceBetween(LatLng from, LatLng to) {
        return computeAngleBetween(from, to) * EARTH_RADIUS;
    }

    /**
     * Returns the length of the given path, in meters, on Earth.
     */
    public static double computeLength(List<LatLng> path) {
        if (path.size() < 2) {
            return 0;
        }
        double length = 0;
        LatLng prev = path.get(0);
        double prevLat = toRadians(prev.latitude);
        double prevLng = toRadians(prev.longitude);
        for (LatLng point : path) {
            double lat = toRadians(point.latitude);
            double lng = toRadians(point.longitude);
            length += distanceRadians(prevLat, prevLng, lat, lng);
            prevLat = lat;
            prevLng = lng;
        }
        return length * EARTH_RADIUS;
    }

    /**
     * Returns the area of a closed path on Earth.
     * @param path A closed path.
     * @return The path's area in square meters.
     */
    public static double computeArea(List<LatLng> path) {
        return abs(computeSignedArea(path));
    }

    /**
     * Returns the signed area of a closed path on Earth. The sign of the area may be used to
     * determine the orientation of the path.
     * "inside" is the surface that does not contain the South Pole.
     * @param path A closed path.
     * @return The loop's area in square meters.
     */
    public static double computeSignedArea(List<LatLng> path) {
        return computeSignedArea(path, EARTH_RADIUS);
    }

    /**
     * Returns the signed area of a closed path on a sphere of given radius.
     * The computed area uses the same units as the radius squared.
     * Used by SphericalUtilTest.
     */
    static double computeSignedArea(List<LatLng> path, double radius) {
        int size = path.size();
        if (size < 3) { return 0; }
        double total = 0;
        LatLng prev = path.get(size - 1);
        double prevTanLat = tan((PI / 2 - toRadians(prev.latitude)) / 2);
        double prevLng = toRadians(prev.longitude);
        // For each edge, accumulate the signed area of the triangle formed by the North Pole
        // and that edge ("polar triangle").
        for (LatLng point : path) {
            double tanLat = tan((PI / 2 - toRadians(point.latitude)) / 2);
            double lng = toRadians(point.longitude);
            total += polarTriangleArea(tanLat, lng, prevTanLat, prevLng);
            prevTanLat = tanLat;
            prevLng = lng;
        }
        return total * (radius * radius);
    }

    /**
     * Returns the signed area of a triangle which has North Pole as a vertex.
     * Formula derived from "Area of a spherical triangle given two edges and the included angle"
     * as per "Spherical Trigonometry" by Todhunter, page 71, section 103, point 2.
     * See http://books.google.com/books?id=3uBHAAAAIAAJ&pg=PA71
     * The arguments named "tan" are tan((pi/2 - latitude)/2).
     */
    private static double polarTriangleArea(double tan1, double lng1, double tan2, double lng2) {
        double deltaLng = lng1 - lng2;
        double t = tan1 * tan2;
        return 2 * atan2(t * sin(deltaLng), 1 + t * cos(deltaLng));
    }

    /**
     * Wraps the given value into the inclusive-exclusive interval between min and max.
     * @param n   The value to wrap.
     * @param min The minimum.
     * @param max The maximum.
     */
    static double wrap(double n, double min, double max) {
        return (n >= min && n < max) ? n : (mod(n - min, max - min) + min);
    }

    /**
     * Returns the non-negative remainder of x / m.
     * @param x The operand.
     * @param m The modulus.
     */
    static double mod(double x, double m) {
        return ((x % m) + m) % m;
    }
}
share|improve this answer
    
Hi, mapSideInPixels, could you let me know where can I find it? –  user1099015 Oct 8 at 10:04
    
I changed my code updated my code: int mapSideInPixels = (int) TypedValue.applyDimension(TypedValue.COMPLEX_UNIT_DIP, mapHeightInDP, r.getDisplayMetrics()); –  Oritm Oct 8 at 14:01
    
Could you let me know your define MARKER_BOUNDS? thanks so much! –  user1099015 Oct 9 at 8:21
    
its just the space between the border between the markers and the map. It does not really matter. Consider voting my answer up, so other people notice the answer! –  Oritm Oct 9 at 11:40

although this answer is logical and i find it working but the results are not accurate i dont know why but i tired this approach and this technique is far more accurate.

1) Make a circle on object with desired radius

Circle circle = mGoogleMap.addCircle(new CircleOptions().center(new LatLng(latitude, longitude)).radius(getRadiusInMeters()).strokeColor(Color.RED));           
        circle.setVisible(true);
        getZoomLevel(circle);

2) Pass that object to this function and set the zoom level Here's a link

public int getZoomLevel(Circle circle) {
if (circle != null){
    double radius = circle.getRadius();
    double scale = radius / 500;
    zoomLevel =(int) (16 - Math.log(scale) / Math.log(2));
}
return zoomLevel;
}
share|improve this answer
1  
Just what i needed. I find the iOS library more efficient on what needs to be shown on the map –  Oritm Aug 3 at 15:50
    
@Oritm thank you and please give the link of the library so it may help others. –  Syed Raza Mehdi Aug 6 at 8:10
    
What i meant is: The default iOS library (when programming on a mac, with xCode ;)) is better than the default Android SDK. –  Oritm Aug 6 at 12:25
1  
nice calculation, i have made changes of my own so that it will be accurate though ... ` public static float zoomLevel(Circle circle){ float zoomLevel = 15; if (circle != null){ double radius = circle.getRadius(); double scale = radius / 500; zoomLevel =(float) (16 - Math.log(scale) / Math.log(2)); Log.i(TAG, "Zoom level = " + zoomLevel ); } return zoomLevel - 0.5f ; }` –  Spurdow Aug 16 at 7:19
1  
theres an excess of 0.5f and float is the returned value , because zoom level is also float. –  Spurdow Aug 16 at 7:20

I've converted the accepted answer to return a double value, since the Android Google Maps library uses floating point zoom levels, and also account for latitudes away from the equator.

public static double getZoomForMetersWide (
  final double desiredMeters,
  final double mapWidth,
  final double latitude )
{
  final double latitudinalAdjustment = Math.cos( Math.PI * latitude / 180.0 );

  final double arg = EQUATOR_LENGTH * mapWidth * latitudinalAdjustment / ( desiredMeters * 256.0 );

  return Math.log( arg ) / Math.log( 2.0 );
}

As an aside, for best results on Android don't pass the view's real pixel count, but the dimension scaled for the device's pixel density.

DisplayMetrics metrics = getResources().getDisplayMetrics();
float mapWidth = mapView.getWidth() / metrics.scaledDensity;

Hope this helps someone.

share|improve this answer
    
What is EQUATOR_LENGTH? –  Sarge Borsch Feb 10 at 14:48
    
The length of the equator in meters, about 6378140 –  sho Feb 18 at 22:22
    
Is mapWidth required in pixel or dp. –  maremmle Oct 20 at 10:17
    
Latitude? is that center map on screen? –  user1099015 Oct 27 at 4:48

Google maps seems to work closely to miles/pixel. At zoom=13, 1 mile= 100 pixels. 2 miles = 200 pixels. Each zoom leven increases or decreases by a factor of 2. Therefore, at Zoom 14, 1 mile = 200 pixels and at zoom 12, 1 mile = 50 pixels.

share|improve this answer
up vote 20 down vote accepted

The following code is what ended up using. Given the screen width and the fact that at zoom level 1 the equator of Earth is 256 pixels long and every subsequent zoom level doubles the number of pixels needed to represent earths equator, the following function returns the zoom level where the screen will show an area of 2Km width.

private int calculateZoomLevel(int screenWidth) {
    double equatorLength = 40075004; // in meters
    double widthInPixels = screenWidth;
    double metersPerPixel = equatorLength / 256;
    int zoomLevel = 1;
    while ((metersPerPixel * widthInPixels) > 2000) {
        metersPerPixel /= 2;
        ++zoomLevel;
    }
    Log.i("ADNAN", "zoom level = "+zoomLevel);
    return zoomLevel;
}
share|improve this answer
    
Sorry, but why is the equator 256 pixels at zoom level 1? –  Radu Dec 22 '12 at 14:32
1  
developers.google.com/maps/documentation/javascript/… this may point to the fact that the zoom level 1 map has 256x256 pixels. Is that the reason? –  Radu Dec 22 '12 at 14:38
    
Yes. Its also mentioned in Android reference here developers.google.com/maps/documentation/android/v1/reference/… –  binW Dec 24 '12 at 6:19
1  
@Inn_vita: you can simply change the value 2000 to 20000 i.e instead of using "while ((metersPerPixel * widthInPixels) > 2000)" use "while ((metersPerPixel * widthInPixels) > 20000) –  binW Jun 13 '13 at 17:26
1  
well, its not possible to make exactly 1km. In each iteration the visible are reduces to half. So as long as its greater than 2000 the half of it will be greater than 1000 but if it goes below 2000, the half will be less than 1000 which is not desireable. So I use the smallest zoom value that is equal or bigger than 1km radius. –  binW Jun 14 '13 at 7:55

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