I'm writing a small program and to improve efficiency, I need to be able to find the closest latitude and longitude in my array.

Assume you have the following code:

tempDataList = [{'lat': 39.7612992 , 'lon': -86.1519681}, 
                {"lat": 39.762241, "lon": -86.158436}, 
                {"lat": 39.7622292, "lon": -86.1578917}]

tempLatList = []
tempLonList = []

for item in tempDataList:

closestLatValue = lambda myvalue: min(tempLatList, key=lambda x: abs(x - myvalue))
closestLonValue = lambda myvalue: min(tempLonList, key=lambda x: abs(x - myvalue))

print(closestLatValue(39.7622290), closestLonValue(-86.1519750))

The result I get is:

(39.7622292, -86.1519681)

What it should be is (in this example, the last object in the list)

(39.7622292, -86.1578917)

I know how to get a single value's closest cell but, I would like to make the lambda function to consider both values but I'm not entirely sure how. Help?


For a correct calculation of the distance between points on the globe, you need something like the Haversine formula. Using the Python implementation offered in this answer, you could code it like this:

from math import cos, asin, sqrt

def distance(lat1, lon1, lat2, lon2):
    p = 0.017453292519943295
    a = 0.5 - cos((lat2-lat1)*p)/2 + cos(lat1*p)*cos(lat2*p) * (1-cos((lon2-lon1)*p)) / 2
    return 12742 * asin(sqrt(a))

def closest(data, v):
    return min(data, key=lambda p: distance(v['lat'],v['lon'],p['lat'],p['lon']))

tempDataList = [{'lat': 39.7612992, 'lon': -86.1519681}, 
                {'lat': 39.762241,  'lon': -86.158436 }, 
                {'lat': 39.7622292, 'lon': -86.1578917}]

v = {'lat': 39.7622290, 'lon': -86.1519750}
print(closest(tempDataList, v))
  • Goodness gracious great balls of fire. Thats perfect. So fast too. It clocked in at 0.03 MS on an old laptop. thanks! – booky99 Dec 28 '16 at 1:21

if earth is plane,

from itertools import combinations
from math import sqrt

coords = [{'lat': 39.7612992 , 'lon': -86.1519681}, 
                {"lat": 39.762241, "lon": -86.158436}, 
                {"lat": 39.7622292, "lon": -86.1578917}]

def euclidean(l1, l2):
    return ((l1[0]**2)-(l2[0]**2)) + ((l1[1]**2)-(l2[1]**2)) 

pairs = [j for j in combinations([i.values() for i in coords], 2)]
pairs.sort(key= lambda x: euclidean(*x))
print pairs[-1]

Also u can simple do:

import mpu
def distance(point1, point2):
    return mpu.haversine_distance(point1, point2)

def closest(data, this_point):
    return min(data, key=lambda x: distance(this_point, x))
  • Why does somebody disliked this solution? Explain, please what's wrong? – Chiefir Nov 17 '18 at 19:22

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