# how to calculate running median efficiently

I borrowed some code trying to implement a function to calculate the running median for a ton of data. The current one is too slow for me (The tricky part is that I need to exclude all zeros from the running box). Below is the code:

``````from itertools import islice
from collections import deque
from bisect import bisect_left,insort

def median(s):
sp = [nz for nz in s if nz!=0]
print sp
Mnow = len(sp)
if Mnow == 0:
return 0
else:
return np.median(sp)

def RunningMedian(seq, M):
seq = iter(seq)
s = []

# Set up list s (to be sorted) and load deque with first window of seq
s = [item for item in islice(seq,M)]
d = deque(s)

# Sort it in increasing order and extract the median ("center" of the sorted window)
s.sort()
medians = [median(s)]
for item in seq:
old = d.popleft()          # pop oldest from left
d.append(item)             # push newest in from right
del s[bisect_left(s, old)] # locate insertion point and then remove old
insort(s, item)            # insert newest such that new sort is not required
medians.append(median(s))
return medians
``````

It works well, the only drawback is that it is too slow. Any one could help me to improve the code to be more efficient?

After I explored all the possibilities, the following simple code can calculate comparably efficiently:

``````def RunningMedian(x,N):
idx = np.arange(N) + np.arange(len(x)-N+1)[:,None]
b = [row[row>0] for row in x[idx]]
return np.array(map(np.median,b))
#return np.array([np.median(c) for c in b])  # This also works
``````
• Possible duplicate of Rolling median algorithm in C Commented Jun 7, 2016 at 5:57
• You can attract more answers if you move this question to Code Review Stack Exchange. Commented Jun 7, 2016 at 6:44
• Didn't Running or sliding median, mean and standard deviation work for you or was it too slow for your needs? Commented Jun 7, 2016 at 6:55
• Take a look at this. It's a lot of code, and being written in Python may not be all that fast. But the implementation is about as fast as it gets, and it uses the same approach that pandas does for its rolling median calculations, but written in Cython for speed. Commented Jun 7, 2016 at 12:34
• why not using pandas.rolling_* methods ? Commented Jun 7, 2016 at 20:39

You can use two heaps to maintain the lower and higher halves of the data sample as you process it. The algorithm goes like this: for each value, put it to an appropriate heap and 'rebalance' the heaps so that their size is not different by more than 1. Then, to get the median, just pull out the first element from the bigger heap, or take an average of the first elements of the two heaps if they are of equal size. This solution has `O(n log(n))` time complexity.

``````from heapq import heappush, heappop

class RunningMedian:
def __init__(self):
self.lowers, self.highers = [], []

if not self.highers or number > self.highers[0]:
heappush(self.highers, number)
else:
heappush(self.lowers, -number)  # for lowers we need a max heap
self.rebalance()

def rebalance(self):
if len(self.lowers) - len(self.highers) > 1:
heappush(self.highers, -heappop(self.lowers))
elif len(self.highers) - len(self.lowers) > 1:
heappush(self.lowers, -heappop(self.highers))

def get_median(self):
if len(self.lowers) == len(self.highers):
return (-self.lowers[0] + self.highers[0])/2
elif len(self.lowers) > len(self.highers):
return -self.lowers[0]
else:
return self.highers[0]
``````

Demo:

``````>>> running_median = RunningMedian()
>>> for n in (12, 4, 5, 3, 8, 7):
...     print(running_median.get_median())
...
12
8.0
5
4.5
5
6.0
``````
• What is running about this? The heap grows without bounds. Normally you have a window over the samples to compute the running median. Therefore you need both to order the samples in the window and to be able to pop samples in the order that they have been introduced. An efficient algorithm should reuse the ordering when adding/removing elements - which your implementation does - while still keeping window size - which your implementation does not. Commented Sep 23, 2020 at 9:20
• Looks like this is computing the running mean, not the median. Commented Jan 21, 2022 at 23:12

One approach is below:

``````def RunningMedian(x,N):
idx = np.arange(N) + np.arange(len(x)-N+1)[:,None]
b = [row[row>0] for row in x[idx]]
return np.array(map(np.median,b))
#return np.array([np.median(c) for c in b])  # This also works
``````

I found a much faster one (tens of thousand times faster), copied as below:

``````from collections import deque
from bisect import insort, bisect_left
from itertools import islice
def running_median_insort(seq, window_size):
"""Contributed by Peter Otten"""
seq = iter(seq)
d = deque()
s = []
result = []
for item in islice(seq, window_size):
d.append(item)
insort(s, item)
result.append(s[len(d)//2])
m = window_size // 2
for item in seq:
old = d.popleft()
d.append(item)
del s[bisect_left(s, old)]
insort(s, item)
result.append(s[m])
return result
``````

Take a look at the link: running_median

• "A much faster one" gives incorrect median when the length of the window is even. Correct one is to take mean between a pair of center elements. Commented Aug 7, 2019 at 13:13
• You may check some simple case like step function with window size 3 - both functions give incorrect results on boundary of the step function. And both doesn't preserve phase. Commented Aug 7, 2019 at 13:24

There's a nice comparison of some speeds of different methods here. But, in general, the scipy.ndimage.median_filter seems to be a simple and efficient method. To include the exclusion of zeros one could do:

``````from scipy.ndimage import median_filter

def RunningMedian(x, N):
return median_filter(x[x != 0], N)
``````

I faced this problem but not as a programmer. I wanted dedicated hardware to do a moving median of a sequence, with a fairly large moving window.

I did it with the two heaps as suggested above, but I also noticed that all the data movement and comparisons within a heap can be done in parallel. So the time required to insert a datum into either heap or to move a datum from either heap was O(1), a constant.