You don't give the exact function you use, but it sounds like it's something like:

```
z = a * sin(b * x) * sin(b * y)
```

I'll walk through the process, so you should be able to apply the recipe even if your function looks slightly differently. Also, if your wave is not relative to the xy-plane, you can still use the same calculation, and then apply the necessary transformation matrix to the resulting normal.

What we have here is a parametric surface, where the 3 coordinates of a point of the plane are calculated from two parameters. In this case, the parameters are `x`

and `y`

, and the vector describing each point is:

```
[ x ]
v(x, y) = [ y ]
[ a * sin(b * x) * sin(b * y) ]
```

The process described here works for any parametric surface, including common geometric shapes. For example for a torus, the two parameters would be two angles. The mathematical tools needed for calculating are basic analysis (derivatives) and some vector geometry (cross product).

As the first step, we calculate the gradient vector for each of the two parameters. These gradient vectors consist of the partial derivatives of each vector component with the corresponding parameter. In the example, the results are:

```
[ 1 ]
dv(x, y)/dx = [ 0 ]
[ a * b * cos(b * x) * sin(b * y) ]
[ 0 ]
dv(x, y)/dy = [ 1 ]
[ a * b * sin(b * x) * cos(b * y) ]
```

The normal vector is calculated as the cross product of these two gradient vectors:

```
[ - a * b * cos(b * x) * sin(b * y) ]
vn = [ - a * b * sin(b * x) * cos(b * y) ]
[ 1 ]
```

Then you normalize this vector, and `vn / |vn|`

is your normal vector.