Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Suppose I have a long and irregular digital signal made up of smaller but irregular signals occurring at various times (and overlapping each other). We will call these shorter signals the "pieces" that make up the larger signal. By "irregular" I mean that it is not a specific frequency or pattern.

Given the long signal I need to find the optimal arrangement of pieces that produce (as closely as possible) the larger signal. I know what the pieces look like but I don't know how many of them exist in the full signal (or how many times any one piece exists in the full signal). What software algorithm would you use to do this optimization? What do I search for on the web to get help on solving this problem?

share|improve this question
Could you give a few examples. Don't really get the idea.sorry. –  smk Feb 9 '13 at 5:17
You will probably get more responses on the Signal Processing stack exchange: dsp.stackexchange.com –  Alex W Feb 9 '13 at 5:19
This sounds closely related to independent components analysis. –  Dougal Feb 9 '13 at 5:20
If you are given the long signal..you can analyze that to see what us the 1st piece,2nd piece etc correct? –  smk Feb 9 '13 at 5:20
Maybe Variable Resolution Analysis? –  Joseph Quinsey Feb 9 '13 at 5:22

1 Answer 1

up vote 1 down vote accepted

Here's a stab at it.

This is actually the easier of the deconvolution problems. It is easier in that you may be able to have a unique answer. The harder problem is that you also don't know what the pieces look like. That case is called blind deconvolution. It is a harder problem and is usually iterative and statistical (ML or MAP), and the solution may not be right.

Luckily, your case is easier, but still not so easy because you have multiple pieces :p

I think that it may be commonly called mixture deconvolution?

So let f[t] for t=1,...N be your long signal. Let h1[t]...hn[t] for t=0,1,2,...M be your short signals. Obviously here, N>>M.

So your hypothesis is that:

(1) f[t] = h1[t+a1[1]]+h1[t+a1[2]] + ...
       +h2[t+a2[1]]+h2[t+a2[2]] + ...
       +hn[t+an[1]]+h2[t+an[2]] + ...

Observe that each row of that equation is actually hj * uj where uj is the sum of shifted Kronecker delta. The * here is convolution.

So now what?

Let Hj be the (maybe transposed depending on how you look at it) Toeplitz matrix generated by hj, then the equation above becomes:

 (2) F = H1 U1 + H2 U2 + ... Hn Un

subject to the constraint that uj[k] must be either 0 or 1.  

where F is the vector [f[0],...F[N]] and Uj is the vector [uj[0],...uj[N]].

So you can rewrite this as:

 (3) F = H * U 

where H = [H1 ... Hn] (horizontal concatenation) and U = [U1; ... ;Un] (vertical concatenation).

H is an Nx(nN) matrix. U is an nN vector.

Ok, so the solution space is finite. It is 2^(nN) in size. So you can try all possible combinations to see which one gives you the lowest ||F - H*U||, but that will take too long.

What you can do is solve equation (3) using pseudo-inverse, multi-linear regression (which uses least square, which comes out to pseudo-inverse), or something like this

Is it possible to solve a non-square under/over constrained matrix using Accelerate/LAPACK?

Then move that solution around within the null space of H to get a solution subject to the constraint that uj[k] must be either 0 or 1.

Alternatively, you can use something like Nelder-Mead or Levenberg-Marquardt to find the minimum of:

  ||F - H U|| + lambda g(U)

where g is a regularization function defined as:

   g(U) = ||U - U*||

where U*[j] = 0 if |U[j]|<|U[j]-1|, else 1

Ok, so I have no idea if this will converge. If not, you have to come up with your own regularizer. It's kinda dumb to use a generalized nonlinear optimizer when you have a set of linear equations.

In reality, you're going to have noise and what not, so it actually may not be a bad idea to use something like MAP and apply the small pieces as prior.

share|improve this answer
Thanks for the great effort on the response! I've got a few questions. You lost me a little bit with h1[t+a1[1]]. It seems that a1 refers to an array of (negative) offsets into f? Then if t + a1[1] is out of range in h1 it becomes a no-op/zero? Is including the t inside the h1 indexer necessary? I was a little confused when you reused t as the indexer on the pieces. –  Brannon Feb 9 '13 at 16:37
@Brannon, hj[t+aj[k]] is just a shifted version of hj in time. since that's how the f is generated (by your description)... sums of shifted versions of the small pieces. in the next step, i take aj out as a pulse train and represent it as hj*uj where uj is a train of kronecker deltas (presumably sparse, but not necessarily). this step is needed to turn your problem in the the more canonical deconvolution...aj[k] is a parameter, so you can constrain it to not be out of range. –  thang Feb 9 '13 at 19:43
@Brannon, also t is necessary because otherwise it wouldn't be a shifted version of hj. –  thang Feb 9 '13 at 19:50

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.