# How to get bounds of a google static map?

How to get bounds in degrees of google static map which has been returned, for example, for following request

``````http://maps.googleapis.com/maps/api/staticmap?center=0.0,0.0&zoom=10&size=640x640&sensor=false
``````

As I know, full Earth map is 256x256 image. This means that n vertical pixels contain x degrees, but n horizontal pixels contain 2x degrees. Right?

As google says center defines the center of the map, equidistant from all edges of the map. As I understood equidistant in pixels (or in degrees?). And each succeeding zoom level doubles the precision in both horizontal and vertical dimensions. So, I can find delta value of Longitude of map for each zoom value as:

``````dLongitude = (HorizontalMapSizeInPixels / 256 ) * ( 360 / pow(2, zoom) );
``````

Same calculations for Latitude:

``````dLatitude = (VerticalMapSizeInPixels / 256 ) * ( 180 / pow(2, zoom) );
``````

VerticalMapSizeInPixels and HorizontalMapSizeInPixels are parameters of map size in URL.

It's good to calculate delta value of Longitude, but for Latitude it is wrong. I cannot find delta value of Latitude, there is some delta error.

As I know, full Earth map is 256x256 image.

Yes.

This means that n vertical pixels contain x degrees, but n horizontal pixels contain 2x degrees. Right?

No. One pixel will represent varying amounts of latitude depending on the latitude. One pixel at the Equator represents less latitude than one pixel near the poles.

The corners of the map will depend on center, zoom level and map size, and you'd need to use the Mercator projection to calculate them. If you don't want to load the full API, here's a MercatorProjection object:

``````var MERCATOR_RANGE = 256;

function bound(value, opt_min, opt_max) {
if (opt_min != null) value = Math.max(value, opt_min);
if (opt_max != null) value = Math.min(value, opt_max);
return value;
}

return deg * (Math.PI / 180);
}

return rad / (Math.PI / 180);
}

function MercatorProjection() {
this.pixelOrigin_ = new google.maps.Point( MERCATOR_RANGE / 2, MERCATOR_RANGE / 2);
this.pixelsPerLonDegree_ = MERCATOR_RANGE / 360;
this.pixelsPerLonRadian_ = MERCATOR_RANGE / (2 * Math.PI);
};

MercatorProjection.prototype.fromLatLngToPoint = function(latLng, opt_point) {
var me = this;

var point = opt_point || new google.maps.Point(0, 0);

var origin = me.pixelOrigin_;
point.x = origin.x + latLng.lng() * me.pixelsPerLonDegree_;
// NOTE(appleton): Truncating to 0.9999 effectively limits latitude to
// 89.189.  This is about a third of a tile past the edge of the world tile.
var siny = bound(Math.sin(degreesToRadians(latLng.lat())), -0.9999, 0.9999);
point.y = origin.y + 0.5 * Math.log((1 + siny) / (1 - siny)) * -me.pixelsPerLonRadian_;
return point;
};

MercatorProjection.prototype.fromPointToLatLng = function(point) {
var me = this;

var origin = me.pixelOrigin_;
var lng = (point.x - origin.x) / me.pixelsPerLonDegree_;
};

//pixelCoordinate = worldCoordinate * Math.pow(2,zoomLevel)
``````

You can save that to a separate file, for example "MercatorProjection.js", and then include it in your application.

``````<script src="MercatorProjection.js"></script>
``````

With the above file loaded, the following function calculates the SW and NE corners of a map of a given size and at a given zoom.

``````function getCorners(center,zoom,mapWidth,mapHeight){
var scale = Math.pow(2,zoom);
var centerPx = proj.fromLatLngToPoint(center);
var SWPoint = {x: (centerPx.x -(mapWidth/2)/ scale) , y: (centerPx.y + (mapHeight/2)/ scale)};
var SWLatLon = proj.fromPointToLatLng(SWPoint);
var NEPoint = {x: (centerPx.x +(mapWidth/2)/ scale) , y: (centerPx.y - (mapHeight/2)/ scale)};
var NELatLon = proj.fromPointToLatLng(NEPoint);
}
``````

and you'd call it like this:

``````var proj = new MercatorProjection();
var centerPoint = new G.LatLng(49.141404, -121.960988);
var zoom = 10;
getCorners(centerPoint,zoom,640,640);
``````
• How precise is this? I ported it to java, I must say I'm really happy with it! I'm only a few meters of. I wonder if that is the algorithm or me making a mistake. For some reason I had to multiple the scale in getCorners with 2.0 else the bounds where way to big. Commented Sep 9, 2015 at 14:51
• GOT IT I had a request with size=1024x1024. It gave me an image of 1080x1080 which I was not aware of! So I did bounds checking on a to small region. Resulting in a to small region... Commented Sep 9, 2015 at 20:18
• Hey @marcelo, I have a problem with your code translated to C#. More info on the problem here Commented May 3, 2016 at 16:17
• How would I use this to go from a lat long within the view to a pixel x, y? Commented May 31, 2016 at 2:44

Thanks Marcelo for your answer. It has been quite helpful. In case anyone would be interested, here the Python version of the code (a rough translation of the PHP code, probably not as pythonic as it could be):

``````from __future__ import division
import math
MERCATOR_RANGE = 256

def  bound(value, opt_min, opt_max):
if (opt_min != None):
value = max(value, opt_min)
if (opt_max != None):
value = min(value, opt_max)
return value

return deg * (math.pi / 180)

return rad / (math.pi / 180)

class G_Point :
def __init__(self,x=0, y=0):
self.x = x
self.y = y

class G_LatLng :
def __init__(self,lt, ln):
self.lat = lt
self.lng = ln

class MercatorProjection :

def __init__(self) :
self.pixelOrigin_ =  G_Point( MERCATOR_RANGE / 2, MERCATOR_RANGE / 2)
self.pixelsPerLonDegree_ = MERCATOR_RANGE / 360
self.pixelsPerLonRadian_ = MERCATOR_RANGE / (2 * math.pi)

def fromLatLngToPoint(self, latLng, opt_point=None) :
point = opt_point if opt_point is not None else G_Point(0,0)
origin = self.pixelOrigin_
point.x = origin.x + latLng.lng * self.pixelsPerLonDegree_
# NOTE(appleton): Truncating to 0.9999 effectively limits latitude to
# 89.189.  This is about a third of a tile past the edge of the world tile.
point.y = origin.y + 0.5 * math.log((1 + siny) / (1 - siny)) * -     self.pixelsPerLonRadian_
return point

def fromPointToLatLng(self,point) :
origin = self.pixelOrigin_
lng = (point.x - origin.x) / self.pixelsPerLonDegree_
return G_LatLng(lat, lng)

#pixelCoordinate = worldCoordinate * pow(2,zoomLevel)

def getCorners(center, zoom, mapWidth, mapHeight):
scale = 2**zoom
proj = MercatorProjection()
centerPx = proj.fromLatLngToPoint(center)
SWPoint = G_Point(centerPx.x-(mapWidth/2)/scale, centerPx.y+(mapHeight/2)/scale)
SWLatLon = proj.fromPointToLatLng(SWPoint)
NEPoint = G_Point(centerPx.x+(mapWidth/2)/scale, centerPx.y-(mapHeight/2)/scale)
NELatLon = proj.fromPointToLatLng(NEPoint)
return {
'N' : NELatLon.lat,
'E' : NELatLon.lng,
'S' : SWLatLon.lat,
'W' : SWLatLon.lng,
}
``````

Usage :

``````>>> import MercatorProjection
>>> centerLat = 49.141404
>>> centerLon = -121.960988
>>> zoom = 10
>>> mapWidth = 640
>>> mapHeight = 640
>>> centerPoint = MercatorProjection.G_LatLng(centerLat, centerLon)
>>> corners = MercatorProjection.getCorners(centerPoint, zoom, mapWidth, mapHeight)
>>> corners
{'E': -65.710988,
'N': 74.11120692972199,
'S': 0.333879313530149,
'W': -178.210988}
>>> mapURL
``````
• Buggy : zoom should be defined as 2**scale, not 2^scale which is a bitwise XOR between 2 and scale Commented Jan 15, 2014 at 10:56

Simple Python Version

Having spent a long time on a similar problem and using this thread for help, here is a simplified Python version of Marcelo (and Jmague)'s code:

``````import math
import requests

def latLngToPoint(mapWidth, mapHeight, lat, lng):

x = (lng + 180) * (mapWidth/360)
y = ((1 - math.log(math.tan(lat * math.pi / 180) + 1 / math.cos(lat * math.pi / 180)) / math.pi) / 2) * mapHeight

return(x, y)

def pointToLatLng(mapWidth, mapHeight, x, y):

lng = x / mapWidth * 360 - 180

n = math.pi - 2 * math.pi * y / mapHeight
lat = (180 / math.pi * math. atan(0.5 * (math.exp(n) - math.exp(-n))))

return(lat, lng)

def getImageBounds(mapWidth, mapHeight, xScale, yScale, lat, lng):

centreX, centreY = latLngToPoint(mapWidth, mapHeight, lat, lng)

southWestX = centreX - (mapWidth/2)/ xScale
southWestY = centreY + (mapHeight/2)/ yScale
SWlat, SWlng = pointToLatLng(mapWidth, mapHeight, southWestX, southWestY)

northEastX = centreX + (mapWidth/2)/ xScale
northEastY = centreY - (mapHeight/2)/ yScale
NElat, NElng = pointToLatLng(mapWidth, mapHeight, northEastX, northEastY)

return[SWlat, SWlng, NElat, NElng]

lat = 37.806716
lng = -122.477702
zoom = 16
picHeight = 640 #Resulting image height in pixels (x2 if scale parameter is set to 2)
picWidth = 640

mapHeight = 256 #Original map size - specific to Google Maps
mapWidth = 256

xScale = math.pow(2, zoom) / (picWidth/mapWidth)
yScale = math.pow(2, zoom) / (picHeight/mapWidth)

corners = getImageBounds(mapWidth, mapHeight, xScale, yScale, lat, lng)
``````

Here I have used x and y to represent pixel values and lat lng as, Latitude and Longitude. lat, lng, zoom, picHeight and picWidth can all be changed to your specific use case. Changing the scale/ maptype etc will not affect this calculation.

I used this code to tile Static Maps images with no gaps/ overlap. If you want to see more of it in use/ how it can work in that sense there is more information on my GitHub.

Here is a line by line translation of Marcelo's code in PHP, which can probably be cleaned up a bit. Works great! Thanks to Marcelo for doing the hard part.

``````define("MERCATOR_RANGE", 256);

return \$deg * (M_PI / 180);
}

return \$rad / (M_PI / 180);
}

function bound(\$value, \$opt_min, \$opt_max) {
if (\$opt_min != null) \$value = max(\$value, \$opt_min);
if (\$opt_max != null) \$value = min(\$value, \$opt_max);
return \$value;
}

class G_Point {
public \$x,\$y;
function G_Point(\$x=0, \$y=0){
\$this->x = \$x;
\$this->y = \$y;
}
}

class G_LatLng {
public \$lat,\$lng;
function G_LatLng(\$lt, \$ln){
\$this->lat = \$lt;
\$this->lng = \$ln;
}
}

class MercatorProjection {

function MercatorProjection() {
\$this->pixelOrigin_ = new G_Point( MERCATOR_RANGE / 2, MERCATOR_RANGE / 2);
\$this->pixelsPerLonDegree_ = MERCATOR_RANGE / 360;
\$this->pixelsPerLonRadian_ = MERCATOR_RANGE / (2 * M_PI);
}

public function fromLatLngToPoint(\$latLng, \$opt_point=null) {
\$me = \$this;

\$point = \$opt_point ? \$opt_point : new G_Point(0,0);

\$origin = \$me->pixelOrigin_;
\$point->x = \$origin->x + \$latLng->lng * \$me->pixelsPerLonDegree_;
// NOTE(appleton): Truncating to 0.9999 effectively limits latitude to
// 89.189.  This is about a third of a tile past the edge of the world tile.
\$point->y = \$origin->y + 0.5 * log((1 + \$siny) / (1 - \$siny)) * -\$me->pixelsPerLonRadian_;
return \$point;
}

public function fromPointToLatLng(\$point) {
\$me = \$this;

\$origin = \$me->pixelOrigin_;
\$lng = (\$point->x - \$origin->x) / \$me->pixelsPerLonDegree_;
return new G_LatLng(\$lat, \$lng);
}

//pixelCoordinate = worldCoordinate * pow(2,zoomLevel)
}

function getCorners(\$center, \$zoom, \$mapWidth, \$mapHeight){
\$scale = pow(2, \$zoom);
\$proj = new MercatorProjection();
\$centerPx = \$proj->fromLatLngToPoint(\$center);
\$SWPoint = new G_Point(\$centerPx->x-(\$mapWidth/2)/\$scale, \$centerPx->y+(\$mapHeight/2)/\$scale);
\$SWLatLon = \$proj->fromPointToLatLng(\$SWPoint);
\$NEPoint = new G_Point(\$centerPx->x+(\$mapWidth/2)/\$scale, \$centerPx->y-(\$mapHeight/2)/\$scale);
\$NELatLon = \$proj->fromPointToLatLng(\$NEPoint);
return array(
'N' => \$NELatLon->lat,
'E' => \$NELatLon->lng,
'S' => \$SWLatLon->lat,
'W' => \$SWLatLon->lng,
);
}
``````

Usage:

``````\$centerLat = 49.141404;
\$centerLon = -121.960988;
\$zoom = 10;
\$mapWidth = 640;
\$mapHeight = 640;
\$centerPoint = new G_LatLng(\$centerLat, \$centerLon);
\$corners = getCorners(\$centerPoint, \$zoom, \$mapWidth, \$mapHeight);
``````

For big zoom factors (>=8), where non-uniformity of map scale on y axis can be neglected, there is much easier method, where we just takes into accout 1/cos(latitude) correction for pixels/(degrees of latitude) resolution. Initial resolution for zoom=0 is 256 pixels per 360 degrees both for x and y at 0 lattitude.

``````def get_static_map_bounds(lat, lng, zoom, sx, sy):
# lat, lng - center
# sx, sy - map size in pixels

# 256 pixels - initial map size for zoom factor 0
sz = 256 * 2 ** zoom

#resolution in degrees per pixel
res_lat = cos(lat * pi / 180.) * 360. / sz
res_lng = 360./sz

d_lat = res_lat * sy / 2
d_lng = res_lng * sx / 2

return ((lat-d_lat, lng-d_lng), (lat+d_lat, lng+d_lng))
``````

Here is translation to Delphi/Pascal with some optimizations to correspond more strict Pascal language and memory management.

``````unit Mercator.Google.Maps;

interface

uses System.Math;

type TG_Point = class(TObject)
private
Fx: integer;
Fy: integer;
public
property x: integer read Fx write Fx;
property y: integer read Fy write Fy;

constructor Create(Ax: integer = 0; Ay: integer = 0);
end;

type TG_LatLng = class(TObject)
private
FLat: double;
FLng: double;
public
property Lat: double read FLat write FLat;
property Lng: double read FLng write FLng;

constructor Create(ALat: double; ALng: double);
end;

type TMercatorProjection = class(TObject)
private
pixelOrigin_: TG_Point;

function bound(value: double; opt_min: double; opt_max: double): double;
public
constructor Create;
procedure fromLatLngToPoint(latLng: TG_LatLng; var point: TG_Point);
procedure fromPointToLatLng(point: TG_point; var latLng: TG_LatLng);
procedure getCorners(center: TG_LatLng; zoom: integer; mapWidth: integer; mapHeight: integer;
var NELatLon: TG_LatLng; var SWLatLon: TG_LatLng);
end;

implementation

const MERCATOR_RANGE = 256;

constructor TG_Point.Create(Ax: Integer = 0; Ay: Integer = 0);
begin
inherited Create;
Fx := Ax;
Fy := Ay
end;

// **************

constructor TG_LatLng.Create(ALat: double; ALng: double);
begin
inherited Create;
FLat := ALat;
FLng := ALng
end;

// **************

constructor TMercatorProjection.Create;
begin
inherited Create;

pixelOrigin_ := TG_Point.Create( Round(MERCATOR_RANGE / 2), Round(MERCATOR_RANGE / 2));
pixelsPerLonDegree_ := MERCATOR_RANGE / 360;
pixelsPerLonRadian_ := MERCATOR_RANGE / (2 * PI);
end;

begin
Result := deg * (PI / 180);
end;

begin
Result := rad / (PI / 180);
end;

// keep value insid defined bounds
function TMercatorProjection.bound(value: double; opt_min: double; opt_max: double): double;
begin
if Value < opt_min then Result := opt_min
else if Value > opt_max then Result := opt_max
else Result := Value;
end;

procedure TMercatorProjection.fromLatLngToPoint(latLng: TG_LatLng; var point: TG_Point);
var
siny: double;
begin
if Assigned(point) then
begin
point.x := Round(pixelOrigin_.x + latLng.lng * pixelsPerLonDegree_);
// NOTE(appleton): Truncating to 0.9999 effectively limits latitude to
// 89.189.  This is about a third of a tile past the edge of the world tile.
point.y := Round(pixelOrigin_.y + 0.5 * ln((1 + siny) / (1 - siny)) * -pixelsPerLonRadian_);
end;
end;

procedure TMercatorProjection.fromPointToLatLng(point: TG_point; var latLng: TG_LatLng);
var
begin
if Assigned(latLng) then
begin
latLng.lng := (point.x - pixelOrigin_.x) / pixelsPerLonDegree_;
end;
end;

//pixelCoordinate = worldCoordinate * pow(2,zoomLevel)

procedure TMercatorProjection.getCorners(center: TG_LatLng; zoom: integer; mapWidth: integer; mapHeight: integer;
var NELatLon: TG_LatLng; var SWLatLon: TG_LatLng);
var
scale: double;
centerPx, SWPoint, NEPoint: TG_Point;
begin
scale := power(2, zoom);

centerPx := TG_Point.Create(0, 0);
try
fromLatLngToPoint(center, centerPx);
SWPoint := TG_Point.Create(Round(centerPx.x-(mapWidth/2)/scale), Round(centerPx.y+(mapHeight/2)/scale));
NEPoint := TG_Point.Create(Round(centerPx.x+(mapWidth/2)/scale), Round(centerPx.y-(mapHeight/2)/scale));
try
fromPointToLatLng(SWPoint, SWLatLon);
fromPointToLatLng(NEPoint, NELatLon);
finally
SWPoint.Free;
NEPoint.Free;
end;
finally
centerPx.Free;
end;
end;

end.
``````

Usage example:

``````            with TMercatorProjection.Create do
try
CLatLon := TG_LatLng.Create(Latitude, Longitude);
SWLatLon := TG_LatLng.Create(0,0);
NELatLon := TG_LatLng.Create(0,0);
try
getCorners(CLatLon, Zoom,
MapWidth, MapHeight,
SWLatLon, NELatLon);
finally
ShowMessage('SWLat='+FloatToStr(SWLatLon.Lat)+' | SWLon='+FloatToStr(SWLatLon.Lng));
ShowMessage('NELat='+FloatToStr(NELatLon.Lat)+' | NELon='+FloatToStr(NELatLon.Lng));

SWLatLon.Free;
NELatLon.Free;
CLatLon.Free;
end;
finally
Free;
end;
``````

#### Here is the NodeJS version, inspired from the "Simple Python Version" above.

``````import { create, all } from "mathjs";

// create a new instance
const math = create(all, {});

function latLngToPoint(mapWidth, mapHeight, lat, lng) {
const x = (lng + 180) * (mapWidth / 360);
const y = ((1 - math.log(math.tan(lat * math.pi / 180) + 1 / math.cos(lat * math.pi / 180)) / math.pi) / 2) * mapHeight;
return [x, y];
}

function pointToLatLng(mapWidth, mapHeight, x, y) {
const lng = x / mapWidth * 360 - 180;
const n = math.pi - 2 * math.pi * y / mapHeight;
const lat = (180 / math.pi * math.atan(0.5 * (math.exp(n) - math.exp(-n))));
return [lat, lng];
}

function getImageBounds(mapWidth, mapHeight, xScale, yScale, lat, lng) {
const [centreX, centreY] = latLngToPoint(mapWidth, mapHeight, lat, lng);

const southWestX = centreX - (mapWidth / 2) / xScale;
const southWestY = centreY + (mapHeight / 2) / yScale;
const [SWlat, SWlng] = pointToLatLng(mapWidth, mapHeight, southWestX, southWestY);

const northEastX = centreX + (mapWidth / 2) / xScale;
const northEastY = centreY - (mapHeight / 2) / yScale;
const [NElat, NElng] = pointToLatLng(mapWidth, mapHeight, northEastX, northEastY);

return [SWlat, SWlng, NElat, NElng];
}
const lat = 37.806716
const lng = -122.477702

const zoom = 16;
const picHeight = 640; // Resulting image height in pixels (x2 if scale parameter is set to 2)
const picWidth = 640;

const mapHeight = 256; // Original map size - specific to Google Maps
const mapWidth = 256;

const xScale = math.pow(2, zoom) / (picWidth / mapWidth);
const yScale = math.pow(2, zoom) / (picHeight / mapWidth);

const corners = getImageBounds(mapWidth, mapHeight, xScale, yScale, lat, lng);

console.log(corners);

``````