Assuming that you perform vector operations `M`

elements at a time (I think NEON is 128 bits wide, so that would be `M=4`

32-bit elements), you can unroll the difference equation by a factor of `M`

pretty easily for the simple single-pole filter. Assume that you have already calculated all outputs up to `y[n]`

. Then, you can calculate the next four as follows:

```
y[n+1] = (1-a)*y[n] + a*x[n+1]
y[n+2] = (1-a)*y[n+1] + a*x[n+2] = (1-a)*((1-a)*y[n] + a*x[n+1]) + a*x[n+2]
= (1-a)^2*y[n] + a*(1-a)*x[n+1] + a*x[n+2]
...
```

In general, you can write `y[n+k]`

as:

```
y[n+k] = (1-a)^2*y[n] + sum_{i=1}^k a*(1-a)^{k-i}*x[n+i]
```

I know the above is difficult to read (maybe we can migrate this question over to Signal Processing and I can re-typeset in LaTeX). But, given an initial condition `y[n]`

(which is assumed to be the last output calculated on the previous
vectorized iteration), you can calculate the next `M`

outputs in parallel, as the rest of the unrolled filter has an FIR-like structure.

There are some caveats to this approach: if `M`

becomes large, then you end up multiplying a bunch of numbers together in order to get the effective FIR coefficients for the unrolled filters. Depending upon your number format and the value of `a`

, this could have numerical precision implications. Also, you don't get an `M`

-fold speedup with this approach: you end up calculating `y[n+k]`

with what amounts to a `k`

-tap FIR filter. Although you're calculating `M`

outputs in parallel, the fact that you have to do `k`

multiply-accumulate operations instead of the simple first-order recursive implementation diminishes some of the benefit to vectorization.