3

Here is a peak detection routine which works as I want it. However, I want to make it more flexible.

def peak2(x,y,dp,dv):

# Define two arrays: one for the peaks and one
# for the valleys

  peaks=[]
  valleys=[]

# Create two arrays, one for x, and one for y, where each
# element of the new array # consists of three adjacent
# elements of the old array.

  xt=zip(x,x[1:],x[2:])
  yt=zip(y,y[1:],y[2:])

# Walk through these arrays, checking to see if the middle
# value of the three old elements exceeds its neighbors by
# d or more.

  idx=1
  for i,j in zip(xt,yt):
    if(j[1]-j[0]>dp and j[1]-j[2]>dp):
      peaks.append((x[idx],y[idx]))
    elif (j[0]-j[1]>dv and j[2]-j[1]>dv):
      valleys.append((x[idx],y[idx]))
    idx+=1

  return array(peaks),array(valleys)

As you can see, it detects a peak by comparing a value with its right and left neighbor. And if the center value is greater than both its immediate neighbors by a certain threshold, then it is considered a peak. Similar logic for finding a valley.

I want to expand it so that it compares the center value with n neighbors on each side. I will pass a parameter to the function (call it w), and if w=3, then I do something like this:

xt=zip(x,x[1:],x[2:])
yt=zip(y,y[1:],y[2:])

which is what is currently in the routine. But if w=5, then I want this:

xt=zip(x,x[1:],x[2:],x[3:],x[4:])
yt=zip(y,y[1:],y[2:],y[3:],y[4:])

And if w=n, where n is odd, then I want this:

xt=zip(x,x[1:],x[2:],...,x[n:])
yt=zip(y,y[1:],y[2:],...,y[n:])

So how can I build these arrays where each element contains n elements of other arrays?

2 Answers 2

2

You can use range with slice to build a list of the arguments and then pass them using unpacking (with *) to zip:

xt = zip(*[x[slice(i, None)] for i in xrange(n)]) # use range in Python 3
yt = zip(*[y[slice(i, None)] for i in xrange(n)])

In the case you may be having more than two dimensions, it may be better to build the list of slices once and then use it with map and list.__getitem__ to create the new list slices:

slices = [slice(i, None) for i in xrange(n)]
xt = zip(*map(x.__getitem__, slices)
yt = zip(*map(y.__getitem__, slices)
zt = zip(*map(z.__getitem__, slices)

On another note, since the sizes of your list arguments are not constant and zip stops when the shortest sublist is exhausted (the last slice in this case), you may consider using itertools.izip_longest.

1

If you need to do the shift operation on an iterator instead of a list, you can use itertools.tee() to create n shifted iterators like:

Code:

import itertools as it

def shift(an_iter, n):
    iters = it.tee(an_iter, n)
    for i in range(n):
        for _ in range(i):
            # remove the first i elements
            next(iters[i])
    return zip(*iters)

Test Code:

for i in shift('abcdefghij', 5):
    print(i)

Results:

('a', 'b', 'c', 'd', 'e')
('b', 'c', 'd', 'e', 'f')
('c', 'd', 'e', 'f', 'g')
('d', 'e', 'f', 'g', 'h')
('e', 'f', 'g', 'h', 'i')
('f', 'g', 'h', 'i', 'j')

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