A lot of informaiton is missing for the vectorization of this loop. Just have a look at the line

```
out_angle = out_angle - sigma*lut(j);
```

After vectorization you would like to have an expression similar to

```
out_angle(j) = out_angle(j-1) - sigma*lut(j);
```

You immediately see that the current `out_angle`

depends on the previously computed value. This also means that `out_angle`

can only be computed sequentially **except** if you can
come up with an explicit representation of `out_angle`

.

```
out_angle(j) = out_angle(j-1) - sigma*lut(j)
= out_angle(j-2) - sigma*lut(j-1) - sigma*lut(j)
= out_angle(j-3) - sigma*lut(j-2) - sigma*lut(j-1) - sigma*lut(j)
= ...
= out_angle(0) - sum_{k = 0}^j (sigma*lut(k))
```

The thing gets more complicated as `sigma`

also depends on `j`

, i.e. actually you have
`sigma(j)`

and thus

```
out_angle(j) = out_angle(0) - sum_{k = 0}^j (sigma(k)*lut(k))
```

Unfortunately you also have only an implicit expression for `sigma`

which you have to
resolve in the same manner. You can probably think a bit about the structure behind `sigma`

. This is a variable, which is 1, where `y`

is negative and -1 where `y`

is positive
or zero, i.e. it is something like

```
sigma = -mySign(y)
```

where `mySign`

acts like the `sign`

function but gives 1 for a zero argument.

If you can find an explicit representation for `sigma`

, you can insert it into the explicit representation of `out_angle`

above. After that you can (most likely) vectorize the code.

`m`

and/or`n`

are very large, or that the`20`

is an example value which is really much larger for your problem? Because if that isn't so, a vectorization of this tiny loop makes little sense, and will in all probability be slower than the loop (see this for example) – Rody Oldenhuis Aug 9 '12 at 7:08