Find nearest value in numpy array
import numpy as np
def find_nearest(array, value):
array = np.asarray(array)
idx = (np.abs(array - value)).argmin()
return array[idx]
array = np.random.random(10)
print(array)
# [ 0.21069679 0.61290182 0.63425412 0.84635244 0.91599191 0.00213826
# 0.17104965 0.56874386 0.57319379 0.28719469]
value = 0.5
print(find_nearest(array, value))
# 0.568743859261
IF your array is sorted and is very large, this is a much faster solution:
def find_nearest(array,value):
idx = np.searchsorted(array, value, side="left")
if idx > 0 and (idx == len(array) or math.fabs(value - array[idx-1]) < math.fabs(value - array[idx])):
return array[idx-1]
else:
return array[idx]
This scales to very large arrays. You can easily modify the above to sort in the method if you can't assume that the array is already sorted. It’s overkill for small arrays, but once they get large this is much faster.
With slight modification, the answer above works with arrays of arbitrary dimension (1d, 2d, 3d, ...):
def find_nearest(a, a0):
"Element in nd array `a` closest to the scalar value `a0`"
idx = np.abs(a - a0).argmin()
return a.flat[idx]
Or, written as a single line:
a.flat[np.abs(a - a0).argmin()]
Summary of answer: If one has a sorted array then the bisection code (given below) performs the fastest. ~100-1000 times faster for large arrays, and ~2-100 times faster for small arrays. It does not require numpy either.
If you have an unsorted array then if array is large, one should consider first using an O(n logn) sort and then bisection, and if array is small then method 2 seems the fastest.
First you should clarify what you mean by nearest value. Often one wants the interval in an abscissa, e.g. array=[0,0.7,2.1], value=1.95, answer would be idx=1. This is the case that I suspect you need (otherwise the following can be modified very easily with a followup conditional statement once you find the interval). I will note that the optimal way to perform this is with bisection (which I will provide first - note it does not require numpy at all and is faster than using numpy functions because they perform redundant operations). Then I will provide a timing comparison against the others presented here by other users.
Bisection:
def bisection(array,value):
'''Given an ``array`` , and given a ``value`` , returns an index j such that ``value`` is between array[j]
and array[j+1]. ``array`` must be monotonic increasing. j=-1 or j=len(array) is returned
to indicate that ``value`` is out of range below and above respectively.'''
n = len(array)
if (value < array[0]):
return -1
elif (value > array[n-1]):
return n
jl = 0# Initialize lower
ju = n-1# and upper limits.
while (ju-jl > 1):# If we are not yet done,
jm=(ju+jl) >> 1# compute a midpoint with a bitshift
if (value >= array[jm]):
jl=jm# and replace either the lower limit
else:
ju=jm# or the upper limit, as appropriate.
# Repeat until the test condition is satisfied.
if (value == array[0]):# edge cases at bottom
return 0
elif (value == array[n-1]):# and top
return n-1
else:
return jl
Now I'll define the code from the other answers, they each return an index:
import math
import numpy as np
def find_nearest1(array,value):
idx,val = min(enumerate(array), key=lambda x: abs(x[1]-value))
return idx
def find_nearest2(array, values):
indices = np.abs(np.subtract.outer(array, values)).argmin(0)
return indices
def find_nearest3(array, values):
values = np.atleast_1d(values)
indices = np.abs(np.int64(np.subtract.outer(array, values))).argmin(0)
out = array[indices]
return indices
def find_nearest4(array,value):
idx = (np.abs(array-value)).argmin()
return idx
def find_nearest5(array, value):
idx_sorted = np.argsort(array)
sorted_array = np.array(array[idx_sorted])
idx = np.searchsorted(sorted_array, value, side="left")
if idx >= len(array):
idx_nearest = idx_sorted[len(array)-1]
elif idx == 0:
idx_nearest = idx_sorted[0]
else:
if abs(value - sorted_array[idx-1]) < abs(value - sorted_array[idx]):
idx_nearest = idx_sorted[idx-1]
else:
idx_nearest = idx_sorted[idx]
return idx_nearest
def find_nearest6(array,value):
xi = np.argmin(np.abs(np.ceil(array[None].T - value)),axis=0)
return xi
Now I'll time the codes: Note methods 1,2,4,5 don't correctly give the interval. Methods 1,2,4 round to nearest point in array (e.g. >=1.5 -> 2), and method 5 always rounds up (e.g. 1.45 -> 2). Only methods 3, and 6, and of course bisection give the interval properly.
array = np.arange(100000)
val = array[50000]+0.55
print( bisection(array,val))
%timeit bisection(array,val)
print( find_nearest1(array,val))
%timeit find_nearest1(array,val)
print( find_nearest2(array,val))
%timeit find_nearest2(array,val)
print( find_nearest3(array,val))
%timeit find_nearest3(array,val)
print( find_nearest4(array,val))
%timeit find_nearest4(array,val)
print( find_nearest5(array,val))
%timeit find_nearest5(array,val)
print( find_nearest6(array,val))
%timeit find_nearest6(array,val)
(50000, 50000)
100000 loops, best of 3: 4.4 µs per loop
50001
1 loop, best of 3: 180 ms per loop
50001
1000 loops, best of 3: 267 µs per loop
[50000]
1000 loops, best of 3: 390 µs per loop
50001
1000 loops, best of 3: 259 µs per loop
50001
1000 loops, best of 3: 1.21 ms per loop
[50000]
1000 loops, best of 3: 746 µs per loop
For a large array bisection gives 4us compared to next best 180us and longest 1.21ms (~100 - 1000 times faster). For smaller arrays it's ~2-100 times faster.