# How to convert from UTM to LatLng in python or Javascript

I have a bunch of files with coordinates in UTM form. For each coordinate I have easting, northing and zone. I need to convert this to LatLng for use with Google Map API to show the information in a map.

I have found some online calculators that does this, but no actual code or libraries. http://trac.osgeo.org/proj4js/ is a projection library for Javascript, but looking at the demo it doesn't include UTM projection.

I am still pretty fresh to the entire GIS domain, so what I want is something ala:

``````(lat,lng) = transform(easting, northing, zone)
``````
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What I found is the following site: http://home.hiwaay.net/~taylorc/toolbox/geography/geoutm.html It has a javascript converter, maybe you could check the algorithm there.

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This is the cleanest Javascript version I have seen. –  Cameron Lowell Palmer Jun 28 '12 at 17:56
As mentioned in @monkut 's answer, python.org includes GDAL's Swig bindings from python: pypi.python.org/pypi/GDAL –  ToolmakerSteve Mar 10 at 18:18

I ended up finding java code from IBM that solved it: http://www.ibm.com/developerworks/java/library/j-coordconvert/index.html

Just for reference, here is my python implementation of the method I needed:

``````import math

def utmToLatLng(zone, easting, northing, northernHemisphere=True):
if not northernHemisphere:
northing = 10000000 - northing

a = 6378137
e = 0.081819191
e1sq = 0.006739497
k0 = 0.9996

arc = northing / k0
mu = arc / (a * (1 - math.pow(e, 2) / 4.0 - 3 * math.pow(e, 4) / 64.0 - 5 * math.pow(e, 6) / 256.0))

ei = (1 - math.pow((1 - e * e), (1 / 2.0))) / (1 + math.pow((1 - e * e), (1 / 2.0)))

ca = 3 * ei / 2 - 27 * math.pow(ei, 3) / 32.0

cb = 21 * math.pow(ei, 2) / 16 - 55 * math.pow(ei, 4) / 32
cc = 151 * math.pow(ei, 3) / 96
cd = 1097 * math.pow(ei, 4) / 512
phi1 = mu + ca * math.sin(2 * mu) + cb * math.sin(4 * mu) + cc * math.sin(6 * mu) + cd * math.sin(8 * mu)

n0 = a / math.pow((1 - math.pow((e * math.sin(phi1)), 2)), (1 / 2.0))

r0 = a * (1 - e * e) / math.pow((1 - math.pow((e * math.sin(phi1)), 2)), (3 / 2.0))
fact1 = n0 * math.tan(phi1) / r0

_a1 = 500000 - easting
dd0 = _a1 / (n0 * k0)
fact2 = dd0 * dd0 / 2

t0 = math.pow(math.tan(phi1), 2)
Q0 = e1sq * math.pow(math.cos(phi1), 2)
fact3 = (5 + 3 * t0 + 10 * Q0 - 4 * Q0 * Q0 - 9 * e1sq) * math.pow(dd0, 4) / 24

fact4 = (61 + 90 * t0 + 298 * Q0 + 45 * t0 * t0 - 252 * e1sq - 3 * Q0 * Q0) * math.pow(dd0, 6) / 720

lof1 = _a1 / (n0 * k0)
lof2 = (1 + 2 * t0 + Q0) * math.pow(dd0, 3) / 6.0
lof3 = (5 - 2 * Q0 + 28 * t0 - 3 * math.pow(Q0, 2) + 8 * e1sq + 24 * math.pow(t0, 2)) * math.pow(dd0, 5) / 120
_a2 = (lof1 - lof2 + lof3) / math.cos(phi1)
_a3 = _a2 * 180 / math.pi

latitude = 180 * (phi1 - fact1 * (fact2 + fact3 + fact4)) / math.pi

if not northernHemisphere:
latitude = -latitude

longitude = ((zone > 0) and (6 * zone - 183.0) or 3.0) - _a3

return (latitude, longitude)
``````

And here I thought it was something simple like easting*x+zone*y or something.

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I don't blame you for thinking it was something simple. I converted last week from Lat/Lon to Easting/Northing for Miller Projection and I'm still celebrating inside. –  wonderchook Dec 7 '08 at 5:07
Why does your function require zone? Shouldn't you just need easting, northing, hemisphere? –  line break Jul 6 '10 at 9:37
@Franki: Because UTM coordinates are relative to predefined zones. UTM on Wikipedia. –  Hubro Jan 18 '13 at 10:01

http://trac.osgeo.org/proj4js/wiki/UserGuide#Supportedprojectionclasses

You may also want to take a look at GDAL. The gdal library has excellent python support, though it may be a bit overkill if you're only doing projection conversion.

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+1 PROJ4 can do almost anything you've ever dreamed of, so if proj4js is a true port, it will be able to do it too. –  MarkJ Jul 13 '09 at 8:13
+1 proj4s is the way to go. no point reinventing the wheel.. the proj4s reads from a config file which can have any projection added - type the reference into spatialreference.org to get a proj4js string e.g. spatialreference.org/ref/epsg/4326/proj4js –  geographika Feb 17 '10 at 2:31

I'm new to this as well and have been studying up on the subject recently.

Here's a method I found using the python gdal pacakge (the osr package is included in gdal). The gdal package is pretty powerful, but the documentation could be better.

This is derived from a discussion here: http://www.mail-archive.com/gdal-dev@lists.osgeo.org/msg12398.html

``````import osr

def transform_utm_to_wgs84(easting, northing, zone):
utm_coordinate_system = osr.SpatialReference()
utm_coordinate_system.SetWellKnownGeogCS("WGS84") # Set geographic coordinate system to handle lat/lon
is_northern = northing > 0
utm_coordinate_system.SetUTM(zone, is_northern)

wgs84_coordinate_system = utm_coordinate_system.CloneGeogCS() # Clone ONLY the geographic coordinate system

# create transform component
utm_to_wgs84_transform = osr.CoordinateTransformation(utm_coordinate_system, wgs84_coordinate_system) # (<from>, <to>)
return utm_to_wgs84_transform.TransformPoint(easting, northing, 0) # returns lon, lat, altitude
``````

And here's the method for converting from a lat, lon in wgs84 (what most gps units report) to utm:

``````def transform_wgs84_to_utm(lon, lat):
def get_utm_zone(longitude):
return (int(1+(longitude+180.0)/6.0))

def is_northern(latitude):
"""
Determines if given latitude is a northern for UTM
"""
if (latitude < 0.0):
return 0
else:
return 1

utm_coordinate_system = osr.SpatialReference()
utm_coordinate_system.SetWellKnownGeogCS("WGS84") # Set geographic coordinate system to handle lat/lon
utm_coordinate_system.SetUTM(get_utm_zone(lon), is_northern(lat))

wgs84_coordinate_system = utm_coordinate_system.CloneGeogCS() # Clone ONLY the geographic coordinate system

# create transform component
wgs84_to_utm_transform = osr.CoordinateTransformation(wgs84_coordinate_system, utm_coordinate_system) # (<from>, <to>)
return wgs84_to_utm_transform.TransformPoint(lon, lat, 0) # returns easting, northing, altitude
``````

I also found that if you've already got django/gdal installed and you know the EPSG code for the UTM zone you're working on, you can just use the `Point()` transform() method.

``````from django.contrib.gis.geos import Point
utm2epsg = {"54N": 3185, ...}
p = Point(lon, lat, srid=4326) # 4326 = WGS84 epsg code
p.transform(utm2epsg["54N"])
``````
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in the last line is a 's' missing in transform –  ustroetz Apr 15 '13 at 17:08

You could use Proj4js, as follows.

The following code will convert from UTM to longitude latitude

``````<html>
<script src="proj4.js"></script>

<script>
var utm = "+proj=utm +zone=32";
var wgs84 = "+proj=longlat +ellps=WGS84 +datum=WGS84 +no_defs";
console.log(proj4(utm,wgs84,[539884, 4942158]));
</script>
<body>

</body>
</html>
``````

In this code, the UTM zone is 32, as should be obvious. The Easting is 539884, and the Northing is 4942158. The result is:

``````[9.502832656648073, 44.631671014204365]
``````

Which is to say 44.631671014204365N, 9.502832656648073E. Which I have verified is correct.

If you need other projections, you can find their strings here.

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There is a perl module via CPAN called Geography::NationalGrid which can convert easting/northing to lat/longs. That may help.

Alternatively there are lots of scripts on the movable-type site that let you convert lat/long and easting/northings.

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``````////////////////////////////////////////////////////////////////////////////////////////////
//
// ToLL - function to compute Latitude and Longitude given UTM Northing and Easting in meters
//
//  Description:
//    This member function converts input north and east coordinates
//    to the corresponding Northing and Easting values relative to the defined
//    UTM zone.  Refer to the reference in this file's header.
//
//  Parameters:
//    north   - (i) Northing (meters)
//    east    - (i) Easting (meters)
//    utmZone - (i) UTM Zone of the North and East parameters
//    lat     - (o) Latitude in degrees
//    lon     - (o) Longitude in degrees
//
function ToLL(north,east,utmZone)
{
// This is the lambda knot value in the reference
var LngOrigin = DegToRad(utmZone * 6 - 183)

// The following set of class constants define characteristics of the
// ellipsoid, as defined my the WGS84 datum.  These values need to be
// changed if a different dataum is used.

var FalseNorth = 0.  // South or North?
//if (lat < 0.) FalseNorth = 10000000.  // South or North?
//else          FalseNorth = 0.

var Ecc = 0.081819190842622       // Eccentricity
var EccSq = Ecc * Ecc
var Ecc2Sq = EccSq / (1. - EccSq)
var Ecc2 = Math.sqrt(Ecc2Sq)      // Secondary eccentricity
var E1 = ( 1 - Math.sqrt(1-EccSq) ) / ( 1 + Math.sqrt(1-EccSq) )
var E12 = E1 * E1
var E13 = E12 * E1
var E14 = E13 * E1

var SemiMajor = 6378137.0         // Ellipsoidal semi-major axis (Meters)
var FalseEast = 500000.0          // UTM East bias (Meters)
var ScaleFactor = 0.9996          // Scale at natural origin

// Calculate the Cassini projection parameters

var M1 = (north - FalseNorth) / ScaleFactor
var Mu1 = M1 / ( SemiMajor * (1 - EccSq/4.0 - 3.0*EccSq*EccSq/64.0 -
5.0*EccSq*EccSq*EccSq/256.0) )

var Phi1 = Mu1 + (3.0*E1/2.0 - 27.0*E13/32.0) * Math.sin(2.0*Mu1)
+ (21.0*E12/16.0 - 55.0*E14/32.0)           * Math.sin(4.0*Mu1)
+ (151.0*E13/96.0)                          * Math.sin(6.0*Mu1)
+ (1097.0*E14/512.0)                        * Math.sin(8.0*Mu1)

var sin2phi1 = Math.sin(Phi1) * Math.sin(Phi1)
var Rho1 = (SemiMajor * (1.0-EccSq) ) / Math.pow(1.0-EccSq*sin2phi1,1.5)
var Nu1 = SemiMajor / Math.sqrt(1.0-EccSq*sin2phi1)

// Compute parameters as defined in the POSC specification.  T, C and D

var T1 = Math.tan(Phi1) * Math.tan(Phi1)
var T12 = T1 * T1
var C1 = Ecc2Sq * Math.cos(Phi1) * Math.cos(Phi1)
var C12 = C1 * C1
var D  = (east - FalseEast) / (ScaleFactor * Nu1)
var D2 = D * D
var D3 = D2 * D
var D4 = D3 * D
var D5 = D4 * D
var D6 = D5 * D

// Compute the Latitude and Longitude and convert to degrees
var lat = Phi1 - Nu1*Math.tan(Phi1)/Rho1 *
( D2/2.0 - (5.0 + 3.0*T1 + 10.0*C1 - 4.0*C12 - 9.0*Ecc2Sq)*D4/24.0
+ (61.0 + 90.0*T1 + 298.0*C1 + 45.0*T12 - 252.0*Ecc2Sq - 3.0*C12)*D6/720.0 )

var lon = LngOrigin +
( D - (1.0 + 2.0*T1 + C1)*D3/6.0
+ (5.0 - 2.0*C1 + 28.0*T1 - 3.0*C12 + 8.0*Ecc2Sq + 24.0*T12)*D5/120.0) / Math.cos(Phi1)

// Create a object to store the calculated Latitude and Longitude values
var sendLatLon = new PC_LatLon(lat,lon)

// Returns a PC_LatLon object
return sendLatLon
}

////////////////////////////////////////////////////////////////////////////////////////////
//
//  RadToDeg - function that inputs a value in radians and returns a value in degrees
//
{
return ( value * 180.0 / Math.PI )
}

////////////////////////////////////////////////////////////////////////////////////////////
//
// PC_LatLon - this psuedo class is used to store lat/lon values computed by the ToLL
//  function.
//
function PC_LatLon(inLat,inLon)
{
this.lat       = inLat     // Store Latitude in decimal degrees
this.lon       = inLon     // Store Longitude in decimal degrees
}
``````
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