I'm trying to evaluate the complexity of some basic image filtering algorithms. I was wondering if you could verify this theory;

For a basic pixel by pixel filter like Inverse the number of operations grows linearly with the size of the input (In pixels) and

Let S = Length of the side of the image Let M = # pixels input

Inverse is of order O(M) or O(S^2).

A convolution filter on the other hand has a parameter R which determines the size of the neighborhood to convolve in establishing the next pixel value for each filter.

Let R = Radius of convolution filter

Convolution is of order O(M*((R+R*2)^2) = O(M*(4R^2) = O(MR^2)

Or should I let N = the size of the convolution filter (Neighbourhood) in pixels?

O(M*(N)) = O(MN)

Ultimately a convolution filter is linearly dependent on the product of the number of pixels and the number of pixels in the neighbourhood.

If you have any links to a paper where this has been documented it would be greatly appreciated.

Kind regards,

Gavin