# Getting distance between two points based on latitude/longitude

I tried implementing this formula: http://andrew.hedges.name/experiments/haversine/ The aplet does good for the two points I am testing: Yet my code is not working.

``````from math import sin, cos, sqrt, atan2

R = 6373.0

lat1 = 52.2296756
lon1 = 21.0122287
lat2 = 52.406374
lon2 = 16.9251681

dlon = lon2 - lon1
dlat = lat2 - lat1
a = (sin(dlat/2))**2 + cos(lat1) * cos(lat2) * (sin(dlon/2))**2
c = 2 * atan2(sqrt(a), sqrt(1-a))
distance = R * c

print "Result", distance
print "Should be", 278.546
``````

The distance it returns is 5447.05546147. Why?

Update: 04/2018: Vincenty distance is deprecated since GeoPy version 1.13 - you should use `geopy.distance.distance()` instead!

The answers above are based on the Haversine formula, which assumes the earth is a sphere, which results in errors of up to about 0.5% (according to `help(geopy.distance)`). Vincenty distance uses more accurate ellipsoidal models such as WGS-84, and is implemented in geopy. For example,

``````import geopy.distance

coords_1 = (52.2296756, 21.0122287)
coords_2 = (52.406374, 16.9251681)

print geopy.distance.geodesic(coords_1, coords_2).km
``````

will print the distance of `279.352901604` kilometers using the default ellipsoid WGS-84. (You can also choose `.miles` or one of several other distance units).

• Thanks. Can you please update your answer with coordinates I provided in question instead of Newport and Cleveland. It will give a better understanding to future readers. Apr 5, 2017 at 11:27
• The arbitrary locations of Newport and Cleveland come from the example geopy documentation in the PyPI listing: pypi.python.org/pypi/geopy May 29, 2017 at 14:41
• I had to modify Kurt Peek's answer to this: Capitalization required: `print geopy.distance.VincentyDistance(coords_1, coords_2).km 279.352901604`
– Jim
Jun 14, 2017 at 19:35
• You should probably use `geopy.distance.distance(…)` in code which is an alias of the currently best (=most accurate) distance formula. (Vincenty at the moment.) Jan 13, 2018 at 14:51
• Using geopy.distance.vincenty in geopy-1.18.1 outputs: Vincenty is deprecated and is going to be removed in geopy 2.0. Use `geopy.distance.geodesic` (or the default `geopy.distance.distance`) instead, which is more accurate and always converges. Mar 8, 2019 at 8:39

Edit: Just as a note, if you just need a quick and easy way of finding the distance between two points, I strongly recommend using the approach described in Kurt's answer below instead of re-implementing Haversine -- see his post for rationale.

This answer focuses just on answering the specific bug OP ran into.

It's because in Python, all the trig functions use radians, not degrees.

You can either convert the numbers manually to radians, or use the `radians` function from the math module:

``````from math import sin, cos, sqrt, atan2, radians

# approximate radius of earth in km
R = 6373.0

dlon = lon2 - lon1
dlat = lat2 - lat1

a = sin(dlat / 2)**2 + cos(lat1) * cos(lat2) * sin(dlon / 2)**2
c = 2 * atan2(sqrt(a), sqrt(1 - a))

distance = R * c

print("Result:", distance)
print("Should be:", 278.546, "km")
``````

The distance is now returning the correct value of `278.545589351` km.

• this is true in any programming language, and also in differential calculus. using degrees is the exception, and only used in human speech. Oct 17, 2013 at 5:19
• Word to the wise, this formula requires all degrees be positive. `radians(abs(52.123))` should do the trick... Jul 4, 2017 at 11:41
• Are you sure about all degrees (angles?) being positive? I think this is wrong. Consider if lat1, lon1 = 10, 10 (degrees) and lat2, lon2 = -10, -10 (degrees). By adding an abs() around the degrees, the distance would be zero, which is incorrect. Perhaps you meant to take the absolute value of dlon and/or dlat, but if you look at the dlon, dlat values in the calculation of a, sine is an even function, and cosine squared is an even function, so I don't see any benefit to taking an absolute value of dlat or dlon, either. May 23, 2020 at 21:22
• Just wondering if the distance above is the arc distance or plane distance between two locations? Jul 7, 2021 at 15:42
• There was a breaking change Removed `geopy.distance.vincenty`, use `geopy.distance.geodesic` instead. Would you update your answer? Feb 8 at 12:37

For people (like me) coming here via search engine and just looking for a solution which works out of the box, I recommend installing `mpu`. Install it via `pip install mpu --user` and use it like this to get the haversine distance:

``````import mpu

# Point one
lat1 = 52.2296756
lon1 = 21.0122287

# Point two
lat2 = 52.406374
lon2 = 16.9251681

# What you were looking for
dist = mpu.haversine_distance((lat1, lon1), (lat2, lon2))
print(dist)  # gives 278.45817507541943.
``````

An alternative package is `gpxpy`.

If you don't want dependencies, you can use:

``````import math

def distance(origin, destination):
"""
Calculate the Haversine distance.

Parameters
----------
origin : tuple of float
(lat, long)
destination : tuple of float
(lat, long)

Returns
-------
distance_in_km : float

Examples
--------
>>> origin = (48.1372, 11.5756)  # Munich
>>> destination = (52.5186, 13.4083)  # Berlin
>>> round(distance(origin, destination), 1)
504.2
"""
lat1, lon1 = origin
lat2, lon2 = destination
radius = 6371  # km

dlat = math.radians(lat2 - lat1)
dlon = math.radians(lon2 - lon1)
a = (math.sin(dlat / 2) * math.sin(dlat / 2) +
math.sin(dlon / 2) * math.sin(dlon / 2))
c = 2 * math.atan2(math.sqrt(a), math.sqrt(1 - a))
d = radius * c

return d

if __name__ == '__main__':
import doctest
doctest.testmod()
``````

The other alternative package is `haversine`

``````from haversine import haversine, Unit

lyon = (45.7597, 4.8422) # (lat, lon)
paris = (48.8567, 2.3508)

haversine(lyon, paris)
>> 392.2172595594006  # in kilometers

haversine(lyon, paris, unit=Unit.MILES)
>> 243.71201856934454  # in miles

# you can also use the string abbreviation for units:
haversine(lyon, paris, unit='mi')
>> 243.71201856934454  # in miles

haversine(lyon, paris, unit=Unit.NAUTICAL_MILES)
>> 211.78037755311516  # in nautical miles
``````

They claim to have performance optimization for distances between all points in two vectors

``````from haversine import haversine_vector, Unit

lyon = (45.7597, 4.8422) # (lat, lon)
paris = (48.8567, 2.3508)
new_york = (40.7033962, -74.2351462)

haversine_vector([lyon, lyon], [paris, new_york], Unit.KILOMETERS)

>> array([ 392.21725956, 6163.43638211])
``````
• Is there a way to change the given Highet of one of the points?
– user12177026
Dec 6, 2019 at 20:38
• You could simply add the height difference to the distance. I would not do that, though. May 5, 2020 at 12:27
• "Lyon, Paris, 392.2172595594006 km", wow the last digit is not even the size of an atom of hydrogen. Very accurate!
– mins
Oct 25, 2020 at 23:31
• wow can you hep me ? , is posible obtain the corresponding distance in decimal degrees over a custom point in map ?, ex : get the decimal degree for point x, y like tha distance in meters is 300 mts Jul 14 at 16:05

I arrived at a much simpler and robust solution which is using `geodesic` from `geopy` package since you'll be highly likely using it in your project anyways so no extra package installation needed.

Here is my solution:

``````from geopy.distance import geodesic

origin = (30.172705, 31.526725)  # (latitude, longitude) don't confuse
dist = (30.288281, 31.732326)

print(geodesic(origin, dist).meters)  # 23576.805481751613
print(geodesic(origin, dist).kilometers)  # 23.576805481751613
print(geodesic(origin, dist).miles)  # 14.64994773134371
``````

geopy

• Thanks buddy for mentioning that latitude is first then longitude. Cheers! Dec 24, 2021 at 4:57

There are multiple ways to calculate the distance based on the coordinates i.e latitude and longitude

## Install and import

``````from geopy import distance
from math import sin, cos, sqrt, atan2, radians
from sklearn.neighbors import DistanceMetric
import osrm
import numpy as np
``````

## Define coordinates

``````lat1, lon1, lat2, lon2, R = 20.9467,72.9520, 21.1702, 72.8311, 6373.0
coordinates_from = [lat1, lon1]
coordinates_to = [lat2, lon2]
``````

## Using haversine

``````dlon = radians(lon2) - radians(lon1)

a = sin(dlat / 2)**2 + cos(lat1) * cos(lat2) * sin(dlon / 2)**2
c = 2 * atan2(sqrt(a), sqrt(1 - a))

distance_haversine_formula = R * c
print('distance using haversine formula: ', distance_haversine_formula)
``````

## Using haversine with sklearn

``````dist = DistanceMetric.get_metric('haversine')

distance_sklearn = R * dist.pairwise(X)
print('distance using sklearn: ', np.array(distance_sklearn).item(1))
``````

## Using OSRM

``````osrm_client = osrm.Client(host='http://router.project-osrm.org')
coordinates_osrm = [[lon1, lat1], [lon2, lat2]] # note that order is lon, lat

osrm_response = osrm_client.route(coordinates=coordinates_osrm, overview=osrm.overview.full)
dist_osrm = osrm_response.get('routes').get('distance')/1000 # in km
print('distance using OSRM: ', dist_osrm)
``````

## Using geopy

``````distance_geopy = distance.distance(coordinates_from, coordinates_to).km
print('distance using geopy: ', distance_geopy)

distance_geopy_great_circle = distance.great_circle(coordinates_from, coordinates_to).km
print('distance using geopy great circle: ', distance_geopy_great_circle)
``````

## Output

``````distance using haversine formula:  26.07547017310917
distance using sklearn:  27.847882224769783
distance using OSRM:  33.091699999999996
distance using geopy:  27.7528030550408
distance using geopy great circle:  27.839182219511834
``````
``````import numpy as np

def Haversine(lat1,lon1,lat2,lon2, **kwarg):
"""
This uses the ‘haversine’ formula to calculate the great-circle distance between two points – that is,
the shortest distance over the earth’s surface – giving an ‘as-the-crow-flies’ distance between the points
(ignoring any hills they fly over, of course!).
Haversine
formula:    a = sin²(Δφ/2) + cos φ1 ⋅ cos φ2 ⋅ sin²(Δλ/2)
c = 2 ⋅ atan2( √a, √(1−a) )
d = R ⋅ c
where   φ is latitude, λ is longitude, R is earth’s radius (mean radius = 6,371km);
note that angles need to be in radians to pass to trig functions!
"""
R = 6371.0088
lat1,lon1,lat2,lon2 = map(np.radians, [lat1,lon1,lat2,lon2])

dlat = lat2 - lat1
dlon = lon2 - lon1
a = np.sin(dlat/2)**2 + np.cos(lat1) * np.cos(lat2) * np.sin(dlon/2) **2
c = 2 * np.arctan2(a**0.5, (1-a)**0.5)
d = R * c
return round(d,4)
``````
• Hi do you think there is a way to do the calcul in getting data directly from the template ? Nov 3, 2020 at 16:21

You can use Uber's H3,`point_dist()` function to compute the spherical distance between two (lat, lng) points. We can set return unit ('km', 'm', or 'rads'). The default unit is Km.

Example :

``````import h3

coords_1 = (52.2296756, 21.0122287)
coords_2 = (52.406374, 16.9251681)
distance = h3.point_dist(coords_1, coords_2, unit='m') # to get distance in meters
``````

Hope this will usefull!

In the year 2022, one can post mixed `javascript+python` code that solves this problem using more recent python library, namely, `geographiclib`. The general benefit is that the users can run and see the result on the web page that runs on modern devices.

``````async function main(){
let pyodide = await loadPyodide();

console.log(pyodide.runPythonAsync(`
import micropip
await micropip.install('geographiclib')
from geographiclib.geodesic import Geodesic
lat1 = 52.2296756;
lon1 = 21.0122287;
lat2 = 52.406374;
lon2 = 16.9251681;
ans = Geodesic.WGS84.Inverse(lat1, lon1, lat2, lon2)
dkm = ans["s12"] / 1000
print("Geodesic solution", ans)
print(f"Distance = {dkm:.4f} km.")
`));

}

main();``````
``<script src="https://cdn.jsdelivr.net/pyodide/v0.21.0/full/pyodide.js"></script>``

(Year 2022, live javascript version) Here is the code that solves this problem using more recent javascript library. The general benefit is that the users can run and see the result on the web page that runs on modern devices.

``````// Using WGS84 ellipsoid model for computation
var geod84 = geodesic.Geodesic.WGS84;
// Input data
lat1 = 52.2296756;
lon1 = 21.0122287;
lat2 = 52.406374;
lon2 = 16.9251681;
// Do the classic `geodetic inversion` computatioin
geod84inv = geod84.Inverse(lat1, lon1, lat2, lon2);
// Present the solution (only the geodetic distance)
console.log("The distance is " + (geod84inv.s12/1000).toFixed(5) + " km.");``````
``````<script type="text/javascript" src="https://cdn.jsdelivr.net/npm/geographiclib-geodesic@2.0.0/geographiclib-geodesic.min.js">
</script>``````

The most simple way is with haversine package.

``````
import haversine as hs

coord_1 = (lat, lon)
coord_2 = (lat, lon)
x = hs.haversine(coord_1,coord_2)
print(f'The distance is {x} km')
``````

Another intereting use of mixed `javascript+python` through `pyodide` and `webassembly` implementation to obtain the solution using Python's libraries `pandas+geographiclib` is also feasible. I made extra effort using `pandas` to prep the input data and when output is available, append them to the `solution` column. Pandas provides many useful features for input/output for common needs. Its method `toHtml` is handy to present the final solution on the web page

EDIT I found that the execution of the code in this answer is not successful on some iphone and ipad devices. But on newer midrange Android devices will run fine. I will find a way to correct this issue and update this soon.

My sidenote, I am aware that my answers are not direct answer to the OP question like some other answers. But lately the outside world said that many answers in StackOvereflow are outdated and tried to steer people away from here.

``````async function main(){
let pyodide = await loadPyodide();
console.log(pyodide.runPythonAsync(`
import micropip
import pandas as pd
import js
print("Pandas version: " + pd.__version__)
await micropip.install('geographiclib')
from geographiclib.geodesic import Geodesic
import geographiclib as gl
print("Geographiclib version: " + gl.__version__)
data = {'Description': ['Answer to the question', 'Bangkok to Tokyo'],
'From_long': [21.0122287, 100.6],
'From_lat': [52.2296756, 13.8],
'To_long': [16.9251681, 139.76],
'To_lat': [52.406374, 35.69],
'Distance_km': [0, 0]}
df1 = pd.DataFrame(data)
collist = ['Description','From_long','From_lat','To_long','To_lat']
div2 = js.document.createElement("div")
div2content = df1.to_html(buf=None, columns=collist, col_space=None, header=True, index=True)
div2.innerHTML = div2content
js.document.body.append(div2)
arr="<i>by Swatchai</i>"

def dkm(frLat,frLon,toLat,toLon):
print("frLon,frLat,toLon,toLat:", frLon, "|", frLat, "|", toLon, "|", toLat)
dist = Geodesic.WGS84.Inverse(frLat, frLon, toLat, toLon)
return dist["s12"] / 1000

collist = ['Description','From_long','From_lat','To_long','To_lat','Distance_km']
dist = []
for ea in zip(df1['From_lat'].values, df1['From_long'].values, df1['To_lat'].values, df1['To_long'].values):
ans = dkm(*ea)
print("ans=", ans)
dist.append(ans)

df1['Distance_km'] = dist
# Update content
div2content = df1.to_html(buf=None, columns=collist, col_space=None, header=True, index=False)
div2.innerHTML = div2content
js.document.body.append(div2)

# Using Haversine Formula
from math import sin, cos, sqrt, atan2, radians, asin
# approximate radius of earth in km from wikipedia
R = 6371
``````<script src="https://cdn.jsdelivr.net/pyodide/v0.21.0/full/pyodide.js"></script>