How to solve for the impulse response using a differential equation?

Given a differential equation: `y[n] - 0.9y[n-1] + 0.81y[n-2] = x[n] - x[n-2]`

a. Find the impulse response for `h[n], n=0,1,2` using recursion.

b. Find the impulse response using MATLAB command filter.

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What have you tried? Is this homework? –  andand May 19 '12 at 13:52

I understand that this is homework, so I will try to give you guidelines without actually giving away the answer completely:

Using recursion

This is actually quite simple, because the differential equation contains the body of the recursive function almost entirely: y[n] = 0.9y[n-1] - 0.81y[n-2] + x[n] - x[n-2]

The parts in bold are actually the recursive calls! What you need to do is to build a function (let's call it `func`) that receives `x` and `n`, and calculates `y[n]`:

``````function y = func(x, n)
if (n < 0)
%# Handling for edge case n<0
return 0
else if (n == 0)
%# Handling for edge case n=0
return x(0)
else
%# The recursive loop
return 0.9 * func(x, n-1) - 0.81 * func(x, n-2) + x(n) - x(n-2)
end
``````

Note that it's pseudo-code, so you still have to check the edge cases and deal with the indexation (indices in MATLAB start with 1 and not 0!).

Using filters

The response of a digital filter is actually the y[n] that you're looking for. As you probably know from lesson, the coefficients of that filter would be the coefficients specified in the differential equation. MATLAB has a built-in function `filter` that emulates just that, so if you write:

``````B = [1, 0, 1];        %# Coefficients for x
A = [1, 0.9, -0.81];  %# Coefficients for y
y = filter(B, A, x);
``````

You'd get an output vector which holds all the values of y[n].

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not sure your `A` or `B` is correct, but if this homework, I suggest you leave it as is. –  Rasman May 20 '12 at 14:08
If you're worried about the signs of the elemenst, maybe you're right... I haven't put much thought into it, I wanted to leave something for the OP to solve :-). –  Eitan T May 20 '12 at 14:10