# Google Maps V3 - How to calculate the zoom level for a given bounds

I'm looking for a way to calculate the zoom level for a given bounds using the Google Maps V3 API, similar to getBoundsZoomLevel() in the V2 API.

Here is what I want to do:

``````// These are exact bounds previously captured from the map object
var sw = new google.maps.LatLng(42.763479, -84.338918);
var ne = new google.maps.LatLng(42.679488, -84.524313);
var bounds = new google.maps.LatLngBounds(sw, ne);
var zoom = // do some magic to calculate the zoom level

// Set the map to these exact bounds
map.setCenter(bounds.getCenter());
map.setZoom(zoom);

// NOTE: fitBounds() will not work
``````

Unfortunately, I can't use the fitBounds() method for my particular use case. It works well for fitting markers on the map, but it does not work well for setting exact bounds. Here is an example of why I can't use the fitBounds() method.

``````map.fitBounds(map.getBounds()); // not what you expect
``````
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The last example is excellent and very illustrative! +1. I have the same problem. –  TMS Mar 24 '12 at 7:47
Sorry, linked wrong question, this is the correct link. –  TMS Mar 24 '12 at 8:09
This question is not a duplicate. The answer to the other question is to use `fitBounds()`. This question asks what to do when `fitBounds()` is insufficient -- either because it over zooms or you don't want to zoom (you just want the bounds). –  John S Dec 22 '13 at 20:34

The zoom levels are discrete, with the scale doubling in each step. So in general you cannot fit the bounds you want exactly (unless you are very lucky with the particular map size).

Another issue is the ratio between side lengths e.g. you cannot fit the bounds exactly to a thin rectangle inside a square map.

There's no easy answer for how to fit exact bounds, because even if you are willing to change the size of the map div, you have to choose which size and corresponding zoom level you change to (roughly speaking, do you make it larger or smaller than it currently is?).

If you really need to calculate the zoom, rather than store it, this should do the trick:

The Mercator projection warps latitude, but any difference in longitude always represents the same fraction of the width of the map (the angle difference in degrees / 360). At zoom zero, the whole world map is 256x256 pixels, and zooming each level doubles both width and height. So after a little algebra we can calculate the zoom as follows, provided we know the map's width in pixels. Note that because longitude wraps around, we have to make sure the angle is positive.

``````var GLOBE_WIDTH = 256; // a constant in Google's map projection
var west = sw.lng();
var east = ne.lng();
var angle = east - west;
if (angle < 0) {
angle += 360;
}
var zoom = Math.round(Math.log(pixelWidth * 360 / angle / GLOBE_WIDTH) / Math.LN2);
``````
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I'm not using arbitrary bounds, I'm using the exact bounds taken previously from the map object. So, in theory, I should be able to pan and zoom the map to fit these bounds exactly. Or, in other words, move the map back to where it was before. –  Nick Clark May 19 '11 at 12:15
In that case, can't you use the map's getters and setters for center and zoom, rather than using bounds? –  Giles Gardam May 19 '11 at 12:43
Wouldn't you have to repeat this for the lat and then choose the min of the result of the 2? I don't think this would work for a tall narrow bounds..... –  whiteatom Mar 25 '12 at 3:15
Works great for me with a change of Math.round to Math.floor. Thanks a million. –  Pete Apr 27 '12 at 13:54
How can this be right if it doesn't take latitude into account? Near the equator it should be fine but the scale of the map at a given zoom level changes depending on the latitude! –  Eyal May 17 '12 at 8:19

Thanks to Giles Gardam for his answer, but it addresses only longitude and not latitude. A complete solution should calculate the zoom level needed for latitude and the zoom level needed for longitude, and then take the smaller (further out) of the two.

Here is a function that uses both latitude and longitude:

``````function getBoundsZoomLevel(bounds, mapDim) {
var WORLD_DIM = { height: 256, width: 256 };
var ZOOM_MAX = 21;

var sin = Math.sin(lat * Math.PI / 180);
var radX2 = Math.log((1 + sin) / (1 - sin)) / 2;
return Math.max(Math.min(radX2, Math.PI), -Math.PI) / 2;
}

function zoom(mapPx, worldPx, fraction) {
return Math.floor(Math.log(mapPx / worldPx / fraction) / Math.LN2);
}

var ne = bounds.getNorthEast();
var sw = bounds.getSouthWest();

var lngDiff = ne.lng() - sw.lng();
var lngFraction = ((lngDiff < 0) ? (lngDiff + 360) : lngDiff) / 360;

var latZoom = zoom(mapDim.height, WORLD_DIM.height, latFraction);
var lngZoom = zoom(mapDim.width, WORLD_DIM.width, lngFraction);

return Math.min(latZoom, lngZoom, ZOOM_MAX);
}
``````

Demo on jsfiddle

Parameters:

The "bounds" parameter value should be a `google.maps.LatLngBounds` object.

The "mapDim" parameter value should be an object with "height" and "width" properties that represent the height and width of the DOM element that displays the map. You may want to decrease these values if you want to ensure padding. That is, you may not want map markers within the bounds to be too close to the edge of the map.

If you are using the jQuery library, the `mapDim` value can be obtained as follows:

``````var \$mapDiv = \$('#mapElementId');
var mapDim = { height: \$mapDiv.height(), width: \$mapDiv.width() };
``````

If you are using the Prototype library, the mapDim value can be obtained as follows:

``````var mapDim = \$('mapElementId').getDimensions();
``````

Return Value:

The return value is the maximum zoom level that will still display the entire bounds. This value will be between `0` and the maximum zoom level, inclusive.

The maximum zoom level is 21. (I believe it was only 19 for Google Maps API v2.)

Explanation:

Google Maps uses a Mercator projection. In a Mercator projection the lines of longitude are equally spaced, but the lines of latitude are not. The distance between lines of latitude increase as they go from the equator to the poles. In fact the distance tends towards infinity as it reaches the poles. A Google Maps map, however, does not show latitudes above approximately 85 degrees North or below approximately -85 degrees South. (reference) (I calculate the actual cutoff at +/-85.05112877980658 degrees.)

This makes the calculation of the fractions for the bounds more complicated for latitude than for longitude. I used a formula from Wikipedia to calculate the latitude fraction. I am assuming this matches the projection used by Google Maps. After all, the Google Maps documentation page I link to above contains a link to the same Wikipedia page.

Other Notes:

1. Zoom levels range from 0 to the maximum zoom level. Zoom level 0 is the map fully zoomed out. Higher levels zoom the map in further. (reference)
2. At zoom level 0 the entire world can be displayed in an area that is 256 x 256 pixels. (reference)
3. For each higher zoom level the number of pixels needed to display the same area doubles in both width and height. (reference)
4. Maps wrap in the longitudinal direction, but not in the latitudinal direction.
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excellent answer, this should be the top voted as it accounts for both longitude and latitude. Worked perfectly so far. –  Peter Wooster May 11 '13 at 21:59
@John S - This is a fantastic solution and I'm contemplating using this over the native google maps fitBounds method available to me as well. I noticed fitBounds is sometimes one zoom level back (zoomed out), but I assume that's from the padding which it's adding. Is the only difference then between this and fitBounds method, just the amount of padding you want to add which accounts for the change in zoom level between the two? –  johntrepreneur Jun 25 '13 at 19:40
@John S - Is it safe to assume this will start with exactly zero padding then for the contained LatLngBounds bounding box? –  johntrepreneur Jun 25 '13 at 19:44
@johntrepreneur - I can only imagine that `fitBounds` is allowing for some kind of padding, but I would say yes, this method should be using the same calculations otherwise. –  John S Jun 25 '13 at 21:35
@johntrepreneur - Advantage #1: You can use this method before you even create the map, so you can provide its result to the initial map settings. With `fitBounds`, you need to create the map and then wait for the "bounds_changed" event. –  John S Jun 25 '13 at 21:40

For version 3 of the API, this is simple and working:

``````var latlngList = [];

latlngList.each(function(n){
bounds.extend(n);
});

map.setCenter(bounds.getCenter()); //or use custom center
map.fitBounds(bounds);
``````
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Yeah! it's working :) –  Kannika Mar 27 at 3:47
That should be the accepted answer –  Gaul Mar 27 at 9:10

Thanks, that helped me a lot in finding the most suitable zoom factor to correctly display a polyline. I find the maximum and minimum coordinates among the points I have to track and, in case the path is very "vertical", I just added few lines of code:

``````var GLOBE_WIDTH = 256; // a constant in Google's map projection
var west = <?php echo \$minLng; ?>;
var east = <?php echo \$maxLng; ?>;
*var north = <?php echo \$maxLat; ?>;*
*var south = <?php echo \$minLat; ?>;*
var angle = east - west;
if (angle < 0) {
angle += 360;
}
*var angle2 = north - south;*
*if (angle2 > angle) angle = angle2;*
var zoomfactor = Math.round(Math.log(960 * 360 / angle / GLOBE_WIDTH) / Math.LN2);
``````

Actually, the ideal zoom factor is zoomfactor-1.

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I liked `var zoomfactor = Math.floor(Math.log(960 * 360 / angle / GLOBE_WIDTH) / Math.LN2)-1;`. Still, very helpful. –  Mojowen Jun 29 '12 at 20:30

Valerio is almost right with his solution, but there is some logical mistake.

you must firstly check wether angle2 is bigger than angle, before adding 360 at a negative.

otherwise you always have a bigger value than angle

So the correct solution is:

``````var west = calculateMin(data.longitudes);
var east = calculateMax(data.longitudes);
var angle = east - west;
var north = calculateMax(data.latitudes);
var south = calculateMin(data.latitudes);
var angle2 = north - south;
var zoomfactor;
var delta = 0;
var horizontal = false;

if(angle2 > angle) {
angle = angle2;
delta = 3;
}

if (angle < 0) {
angle += 360;
}

zoomfactor = Math.floor(Math.log(960 * 360 / angle / GLOBE_WIDTH) / Math.LN2) - 2 - delta;
``````

Delta is there, because i have a bigger width than height.

-

`map.getBounds()` is not momentary operation, so I use in similar case event handler. Here is my example in Coffeescript

``````@map.fitBounds(@bounds)
@map.setZoom(12) if @map.getZoom() > 12
``````
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Since all of the other answers seem to have issues for me with one or another set of circumstances (map width/height, bounds width/height, etc.) I figured I'd put my answer here...

There was a very useful javascript file here: http://www.polyarc.us/adjust.js

I used that as a base for this:

``````var com = com || {};
com.local = com.local || {};
com.local.gmaps3 = com.local.gmaps3 || {};

com.local.gmaps3.CoordinateUtils = new function() {

var OFFSET = 268435456;
var RADIUS = OFFSET / Math.PI;

/**
* Gets the minimum zoom level that entirely contains the Lat/Lon bounding rectangle given.
*
* @param {google.maps.LatLngBounds} boundary the Lat/Lon bounding rectangle to be contained
* @param {number} mapWidth the width of the map in pixels
* @param {number} mapHeight the height of the map in pixels
* @return {number} the minimum zoom level that entirely contains the given Lat/Lon rectangle boundary
*/
this.getMinimumZoomLevelContainingBounds = function ( boundary, mapWidth, mapHeight ) {
var zoomIndependentSouthWestPoint = latLonToZoomLevelIndependentPoint( boundary.getSouthWest() );
var zoomIndependentNorthEastPoint = latLonToZoomLevelIndependentPoint( boundary.getNorthEast() );
var zoomIndependentNorthWestPoint = { x: zoomIndependentSouthWestPoint.x, y: zoomIndependentNorthEastPoint.y };
var zoomIndependentSouthEastPoint = { x: zoomIndependentNorthEastPoint.x, y: zoomIndependentSouthWestPoint.y };
var zoomLevelDependentSouthEast, zoomLevelDependentNorthWest, zoomLevelWidth, zoomLevelHeight;
for( var zoom = 21; zoom >= 0; --zoom ) {
zoomLevelDependentSouthEast = zoomLevelIndependentPointToMapCanvasPoint( zoomIndependentSouthEastPoint, zoom );
zoomLevelDependentNorthWest = zoomLevelIndependentPointToMapCanvasPoint( zoomIndependentNorthWestPoint, zoom );
zoomLevelWidth = zoomLevelDependentSouthEast.x - zoomLevelDependentNorthWest.x;
zoomLevelHeight = zoomLevelDependentSouthEast.y - zoomLevelDependentNorthWest.y;
if( zoomLevelWidth <= mapWidth && zoomLevelHeight <= mapHeight )
return zoom;
}
return 0;
};

function latLonToZoomLevelIndependentPoint ( latLon ) {
return { x: lonToX( latLon.lng() ), y: latToY( latLon.lat() ) };
}

function zoomLevelIndependentPointToMapCanvasPoint ( point, zoomLevel ) {
return {
x: zoomLevelIndependentCoordinateToMapCanvasCoordinate( point.x, zoomLevel ),
y: zoomLevelIndependentCoordinateToMapCanvasCoordinate( point.y, zoomLevel )
};
}

function zoomLevelIndependentCoordinateToMapCanvasCoordinate ( coordinate, zoomLevel ) {
return coordinate >> ( 21 - zoomLevel );
}

function latToY ( lat ) {
return OFFSET - RADIUS * Math.log( ( 1 + Math.sin( lat * Math.PI / 180 ) ) / ( 1 - Math.sin( lat * Math.PI / 180 ) ) ) / 2;
}

function lonToX ( lon ) {
return OFFSET + RADIUS * lon * Math.PI / 180;
}

};
``````

You can certainly clean this up or minify it if needed, but I kept the variable names long in an attempt to make it easier to understand.

If you are wondering where OFFSET came from, apparently 268435456 is half of earth's circumference in pixels at zoom level 21 (according to http://www.appelsiini.net/2008/11/introduction-to-marker-clustering-with-google-maps).

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