# Finding islands of zeros in a sequence

Imagine you have a very long sequence. What is the most efficient way of finding the intervals where the sequence is all zeros (or more precisely the sequence drops to near-zero values `abs(X)<eps`):

For simplicity, lets assume the following sequence:

``````sig = [1 1 0 0 0 0 1 1 1 1 1 0 1 0 0 0 1 1 1 1 1 1 1 1 0 0 1 1 1 0];
``````

I'm trying to get the following information:

``````startIndex   EndIndex    Duration
3            6           4
12           12          1
14           16          3
25           26          2
30           30          1
``````

then using this information, we find the intervals with duration >= to some specified value (say `3`), and returning the indices of the values in all these intervals combined:

``````indices = [3 4 5 6 14 15 16];
``````

That last part is related to a previous question:

MATLAB: vectorized array creation from a list of start/end indices

This is what I have so far:

``````sig = [1 1 0 0 0 0 1 1 1 1 1 0 1 0 0 0 1 1 1 1 1 1 1 1 0 0 1 1 1 0];
len = length(sig);
thresh = 3;

%# align the signal with itself successively shifted by one
%# v will thus contain 1 in the starting locations of the zero interval
v = true(1,len-thresh+1);
for i=1:thresh
v = v & ( sig(i:len-thresh+i) == 0 );
end

%# extend the 1's till the end of the intervals
for i=1:thresh-1
v(find(v)+1) = true;
end

%# get the final indices
v = find(v);
``````

I'm looking to vectorize/optimize the code, but I'm open to other solutions. I have to stress that space and time efficiencies are very important, since I'm processing a large number of long bio-signals.

-
I like your usage of the word islands. – ChaosPandion Jul 18 '10 at 2:07
@ChaosPandion: searching islands of zeros in a sea of ones.. arrr :) – merv Jul 18 '10 at 22:03

These are the steps I would take to solve your problem in a vectorized way, starting with a given vector `sig`:

• First, threshold the vector to get a vector `tsig` of zeros and ones (zeroes where the absolute value of the signal drops close enough to zero, ones elsewhere):

``````tsig = (abs(sig) >= eps);  %# Using eps as the threshold
``````
• Next, find the starting indices, ending indices, and duration of each string of zeroes using the functions DIFF and FIND:

``````dsig = diff([1 tsig 1]);
startIndex = find(dsig < 0);
endIndex = find(dsig > 0)-1;
duration = endIndex-startIndex+1;
``````
• Then, find the strings of zeroes with a duration greater than or equal to some value (such as 3, from your example):

``````stringIndex = (duration >= 3);
startIndex = startIndex(stringIndex);
endIndex = endIndex(stringIndex);
``````
• Finally, use the method from my answer to the linked question to generate your final set of indices:

``````indices = zeros(1,max(endIndex)+1);
indices(startIndex) = 1;
indices(endIndex+1) = indices(endIndex+1)-1;
indices = find(cumsum(indices));
``````
-
Was going to suggest this, more or less exactly. – rlbond Jul 18 '10 at 5:21
how come I didnt think of using DIFF myself?? thanks – merv Jul 18 '10 at 22:01

You can solve this as a string search task, by finding strings of zeros of length `thresh` (STRFIND function is very fast)

``````startIndex = strfind(sig, zeros(1,thresh));
``````

Note that longer substrings will get marked in multiple locations but will eventually be joined once we add in-between locations from intervals start at `startIndex` to end at `start+thresh-1`.

``````indices = unique( bsxfun(@plus, startIndex', 0:thresh-1) )';
``````

Note that you can always swap this last step with the CUMSUM/FIND solution by @gnovice from the linked question.

-
thats definitely the shortest vectorized solution, I wonder how It compares to the other two methods: `diff/find` by @gnovice and `conv` by @emailhy – merv Jul 18 '10 at 22:02

Here it is in numpy (also answered here)

``````def nonzero_intervals(vec):
'''
Find islands of non-zeros in the vector vec
'''
if len(vec)==0:
return []
elif not isinstance(vec, np.ndarray):
vec = np.array(vec)

edges, = np.nonzero(np.diff((vec==0)*1))
edge_vec = [edges+1]
if vec[0] != 0:
edge_vec.insert(0, [0])
if vec[-1] != 0:
edge_vec.append([len(vec)])
edges = np.concatenate(edge_vec)
return zip(edges[::2], edges[1::2])
``````

E.g:

``````a=[1, 2, 0, 0, 0, 3, 4, 0]
intervals = nonzero_intervals(a)
assert intervals == [(0, 2), (5, 7)]
``````
-
why `numpy` answer? the question is tagged matlab? – Shai Dec 25 '14 at 7:02
Because I found this question when searching for how to do it in numpy. The question is really about how to do it in vectorized code. – Peter Dec 26 '14 at 16:44
``````function indice=sigvec(sig,thresh)
%extend sig head and tail to avoid 0 head and 0 tail

exsig=[1,sig,1];
%convolution sig with extend sig
cvexsig=conv(exsig,ones(1,thresh));
tempsig=double(cvexsig==0);

indice=find(conv(tempsig,ones(1,thresh)))-thresh;
``````
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+1 This is a decent solution in case `thresh` is small enough, however it gets slower with larger values – merv Jul 18 '10 at 22:02

I think the most MATLAB/"vectorized" way of doing it is by computing a convolution of your signal with a filter like [-1 1]. You should look at the documentation of the function conv. Then on the output of conv use find to get the relevant indexes.

-

As gnovice showed, we'll do a threshold test to make "near zero" really zero:

``````logcl = abs(sig(:)) >= zero_tolerance;
``````

Then find regions where the cumulative sum isn't increasing:

``````cs = cumsum(logcl);
islands = cs(1+thresh:end) == cs(1:end-thresh);
``````
``````v = zeros(1,max(endInd)+1);   %# An array of zeroes
v(startInd) = 1;              %# Place 1 at the starts of the intervals
v(endInd+1) = v(endInd+1)-1;  %# Add -1 one index after the ends of the intervals
indices = find(cumsum(v));  %# Perform a cumulative sum and find the nonzero entries
``````

We note that our `islands` vector already has ones in the `startInd` locations, and for our purposes `endInd` always comes `thresh` spots later (longer runs have runs of ones in `islands`)

``````endcap = zeros(thresh,1);
indices = find(cumsum([islands ; endcap] - [endcap ; islands]))
``````

# Test

``````sig = [1 1 0 0 0 0 1 1 1 1 1 0 1 0 0 0 1 1 1 1 1 1 1 1 0 0 1 1 1 0];
logcl = abs(sig(:)) >= .1;
cs = cumsum(logcl);
islands = cs(1+thresh:end) == cs(1:end-thresh);
endcap = zeros(thresh,1);
indices = find(cumsum([islands ; endcap] - [endcap ; islands]))
``````
``````indices =

2
3
4
5
13
14
15
``````
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