# Calculating Inverse Filter

Does anyone has an idea how to calculate the Inverse of a 2-D filter?

Let's say I have a 3x3 filter:
0 1 0
1 1 1
0 1 0
I want to find it's inverse. It's easy to do using DFT. But let's say I want to do it by convolution. Now, that's the problem, Matlab symbolic isn't my specialty. Assuming there's a 3X3 Inverse Filter it means convolution of the two will result in:
0 0 0
0 1 0
0 0 0
The problem is to create the right set of equations for that and solving it. Doing it with symbols is easy to think yet I couldn't do it.

Any ideas? Thanks.

P.S. I'm not sure there an Inverse Filter for this one as it has zeros in its DTFT.

Moreover, someone should allow Latex in this forum the way MathOverflow has.

-

Let h[n] be the finite impulse response of a 1D filter. What does that imply about its inverse filter? The inverse cannot possibly be FIR.

Proof: Let H(omega) G(omega) = 1 for all omega, where H is the DTFT of h[n], and G is the DTFT of g[n]. If h[n] is FIR, then g[n] must be IIR.

Of course, there are ways to approximate the inverse IIR filter with an FIR filter. A basic method is adaptive filtering, e.g., Least Mean Squares (LMS) algorithm. Or just truncate the IIR filter. You still need to worry about stability, though.

For practical purposes, there probably is no desirable solution to your specific question. Especially if, for example, this is in image processing and you are trying to inverse an FIR blur filter with FIR sharpening filter. The final image will not look that good, period, unless your sharpening filter is really, really large.

EDIT: Let y[n] = b0 x[n-0] + b1 x[n-1] + ... + bN x[n-N]. Let this equation characterize the forward system, where y is the output and x is the input. By definition, the impulse response is the output when the input is an impulse: h[n] = b0 d[n-0] + b1 d[n-1] + ... + bN d[n-N]. This impulse response has finite length N+1.

Now, consider the inverse system where x is the output and y is the input. Then the impulse response is described by the recurrence equation d[n] = b0 h[n] + b1 h[n-1] + ... + bN h[n-N]. Equivalently, b0 h[n] = d[n] - b1 h[n-1] - ... - bN h[n-N].

Without loss of generality, assume that b0 and bN are both nonzero. For any m, if h[m] is nonzero, then h[m+N] is also nonzero. Because this system has feedback, its impulse response is infinitely long. QED.

Causality does not matter. The inverse of a delay is an advance, and vice versa. Neither a delay or an advance alter the finiteness of an impulse response. Shift an infinite impulse response left or right; it is still infinite.

EDIT 2: For clarification, this proof is not related to my original "proof". One was in frequency domain, the other in time domain.

-
Wouldn't the Delta function contradict your proof? Take h[n] to be the Delta, its Inverse would be a Delta. Both are FIR. What make you say that if H(omega)*G(Omega)=1 it means G must be IIR? Thanks. –  Drazick Jan 18 '10 at 8:03
Yes, I know. That is the only trivial, pathological case. Delayed impulses; same thing. –  Steve Tjoa Jan 18 '10 at 14:37
Could you elaborate how do you conclude that the inverse of FIR is IIR. How come dividing by it makes it IIR? By the way, If I get it right, this statement is holding for casual filters only? In Image Processing you have the whole image, which means it doesn't hold for that case. Thanks. –  Drazick Jan 19 '10 at 22:03
Sure. See edit. –  Steve Tjoa Jan 19 '10 at 23:40

In practice, one useful solution is Wiener deconvolution http://en.wikipedia.org/wiki/Wiener_deconvolution which basically, in Fourier space, divides by the spectrum of the given filter. Zeros are handled by adding a fudge term: instead of 1/H(w), use H(w)/( abs(H(w))^2 + c) where H(w) is the discrete Fourier transform of the filter h(x) (add a 2nd dimension as you like) and "w" is supposed to be omega. The constant is chosen based on the noise level of the signal or image.

-
What I meant is something like "Equalizer" for Digital Communications systems. You calculate the coefficients needed for a discrete delta. The problem is actually something technical in Matlab. How do I use it along with its symbolic capabilities to compute this Matrix of coefficients. It's as easy as solving Linear Equation for 1D filter. It seems harder for 2D. Thanks. –  Drazick Feb 2 '10 at 9:37

For a separable filter (i.e., one in which you can pull out a horizontal and vertical filter which can be applied in any order and give the same result as the composite 2-D filter), you could attempt to calculate the inverse of each on individually.

The inverse of a filter H(w) is G(w)=1/H(w), so one way to do it is to take the impulse response (the h[n] time-domain coeffs) and inverse-DFT them. It's not always easy to get an analytic expression for such a filter, so you could either compute it numerically (approximating to the desired precision) or do adaptive inverse filtering, as Steve suggested. See Widrow and Stearn's Adaptive Signal Processing for more info on this latter method.

-