# How can I quickly estimate the distance between two (latitude, longitude) points?

I want to be able to get a estimate of the distance between two (latitude, longitude) points. I want to undershoot, as this will be for A* graph search and I want it to be fast. The points will be at most 800 km apart.

• Should we infer these points lie on a sphere? – phs Apr 1 '13 at 2:45
• – Aaron D Apr 1 '13 at 2:45
• Yes, on earth, but speed. AFAIK complex math is not fast enough. – fread2281 Apr 1 '13 at 2:48
• I suggest you measure first before concluding it's not fast enough. – phs Apr 1 '13 at 2:50
• Sometimes it's possible to know enough about an implementation and algorithm to know performance won't be good enough even prior to benchmarking. For instance, one case where the haversine distance method isn't appropriate is when attempting to match large datasets on proximity, as the haversine algorithm doesn't allow any predicate pushdowns or partition matching in most querying engines. We found that leveraging approximate distances with pushdowns to produce a cartesian clustering base took ~1/50th the time on a 250k record dataset. The accepted answer would take over a week to run here. – bsplosion Mar 13 '19 at 13:18

The answers to Haversine Formula in Python (Bearing and Distance between two GPS points) provide Python implementations that answer your question.

Using the implementation below I performed 100,000 iterations in less than 1 second on an older laptop. I think for your purposes this should be sufficient. However, you should profile anything before you optimize for performance.

from math import radians, cos, sin, asin, sqrt
def haversine(lon1, lat1, lon2, lat2):
"""
Calculate the great circle distance between two points
on the earth (specified in decimal degrees)
"""
# convert decimal degrees to radians
lon1, lat1, lon2, lat2 = map(radians, [lon1, lat1, lon2, lat2])
# haversine formula
dlon = lon2 - lon1
dlat = lat2 - lat1
a = sin(dlat/2)**2 + cos(lat1) * cos(lat2) * sin(dlon/2)**2
c = 2 * asin(sqrt(a))
# Radius of earth in kilometers is 6371
km = 6371* c
return km

To underestimate haversine(lat1, long1, lat2, long2) * 0.90 or whatever factor you want. I don't see how introducing error to your underestimation is useful.

• So, this isn't a "quick" method, it's the "standard" method, correct? (and slower than my equally accurate method, when comparing in Excel anyhow) – ashleedawg Sep 20 '18 at 21:53
• @ashleedawg - The Haversine formula is a particular method for estimating distance between two points assuming Earth is a sphere. I invite you to look at the wikipedia page on Haversine formula if you want to explore other methods. Haversine is common but there is not a "standard" formula. If your "equally accurate method" is good, why not post it as an answer here? – Aaron D Oct 15 '18 at 22:40

Since the distance is relatively small, you can use the equirectangular distance approximation. This approximation is faster than using the Haversine formula. So, to get the distance from your reference point (lat1/lon1) to the point your are testing (lat2/lon2), use the formula below. Important Note: you need to convert all lat/lon points to radians:

R = 6371  // radius of the earth in km
x = (lon2 - lon1) * cos( 0.5*(lat2+lat1) )
y = lat2 - lat1
d = R * sqrt( x*x + y*y )


Since 'R' is in km, the distance 'd' will be in km.

• Note that the equirectangular approximation will overshoot, not undershoot. You can derive it from the Haversine formula using small angle approximations sin^2(dlon) ~ dlon^2, sin^2(dlat) ~ dlat^2 and cos(dlat) ~ 1 where dlon=lon2-lon1 and dlat=lat2-lat1. All approximations are >= the exact version, thus the approximated distance will be larger than the exact distance. – sfinkens Aug 1 '18 at 7:30
• I could argue that Haversine (if that is what you mean by 'exact') is an approximation as well since the Earth isn't a true sphere. And what order of magnitude of overshoot are we talking? A couple of inches overshoot? feet? – TreyA Aug 1 '18 at 17:05
• Of course, that is correct. The OP asked for undershooting. But for some applications overshooting is even a desired property of the approximation, e.g. for pre-selecting neighbouring points within a given distance. So the point is that it overshoots, not how much. – sfinkens Aug 2 '18 at 7:55
• Yes, but if it overshoots by only inches, technically you are correct but practically who cares? The OP is looking for speed as well. And you are free to adjust the radius of the Earth to your under/over shooting liking. – TreyA Aug 2 '18 at 15:06

One idea for speed is to transform the long/lat coordinated into 3D (x,y,z) coordinates. After preprocessing the points, use the Euclidean distance between the points as a quickly computed undershoot of the actual distance.

• But projecting a sphere into a plane introduces artifacts, and in 800 km they will be noticeable. – jjmontes Sep 5 '19 at 20:07
• @jjmontes There is no projection involved. This is a straight forward conversion from spherical coordinates to Cartesian coordinates. The points don't move in space. – Raymond Hettinger Sep 6 '19 at 1:42
• Oh I see now. Nice! and will undershoot with nice properties. – jjmontes Sep 6 '19 at 2:47

For maximal speed, you could create something like a rainbow table for coordinate distances. It sounds like you already know the area that you are working with, so it seems like pre-computing them might be feasible. Then, you could load the nearest combination and just use that.

For example, in the continental United States, the longitude is a 55 degree span and latitude is 20, which would be 1100 whole number points. The distance between all the possible combinations is a handshake problem which is answered by (n-1)(n)/2 or about 600k combinations. That seems pretty feasible to store and retrieve. If you provide more information about your requirements, I could be more specific.

If the distance between points is relatively small (meters to few km range) then one of the fast approaches could be

from math import cos, sqrt
def qick_distance(Lat1, Long1, Lat2, Long2):
x = Lat2 - Lat1
y = (Long2 - Long1) * cos((Lat2 + Lat1)*0.00872664626)
return 111.319 * sqrt(x*x + y*y)


Lat, Long are in radians, distance in km.

Deviation from Haversine distance is in the order of 1%, while the speed gain is more than ~10x.

0.00872664626 = 0.5 * pi/180,

111.319 - is the distance that corresponds to 1degree at Equator, you could replace it with your median value like here https://www.cartographyunchained.com/cgsta1/ or replace it with a simple lookup table.

def distance(lat1, lng1, lat2, lng2):
#return distance as meter if you want km distance, remove "* 1000"

dLat = (lat2-lat1) * math.pi / 180
dLng = (lng2-lng1) * math.pi / 180

lat1 = lat1 * math.pi / 180
lat2 = lat2 * math.pi / 180

val = sin(dLat/2) * sin(dLat/2) + sin(dLng/2) * sin(dLng/2) * cos(lat1) * cos(lat2)
ang = 2 * atan2(sqrt(val), sqrt(1-val))

>>> import mpu