I'm trying to code a small F# linear algebra library (for applications with small matrices, so memory isn't an issue), and I was wondering which data structure had the best performance characteristics, in terms of element lookup times, since I'll need that to define matrix operations?
If "small" is 2 or 3dimensional then structs. For slightly larger "small", use a reference type with explicit components. If the number of elements is more than about 30 then use a single array and do 


I'm a little unclear what's being asked. Arrays are of course O(1), and so I expect they're the right answer. (Brian's rule of thumb: if you want something to be fast, then the answer is the same in every language  use an array of structs.) If you need something sparser, there's the .NET But of course I expect either this depends a whole lot on the specifics (density, locality/access pattern, ...) or it does not matter at all (other factors overwhelm it). At the end of day, like for every performance question: measure. 


The most efficient representation is probably going to be a mutable array (twodimensional should work pretty well). The lookup by index is O(1), so that's as efficient as it can get. Even though the array is mutable, you can still use it to develop a immutable (functional) matrix type  all you need to do is to avoid mutating the array. The compiler will not check this, but the data structure can be purely functional for the user. Something like this could be a good starting point:


