An non-optimal answer is the following:
Generate all the possible k-plets of points (they are N × N-1 × … × N-k+1, so this is O(Nk) and can be done via recursion).
Filter this list down by eliminating all k-plets which are not enclosed in a a×b rectangle: this is a O(k Nk) at worst.
Find the k-plet which has the maximum weight: this is a O(k Nk-1) at worst.
Thus, this algorithm is O(k Nk).
Improving the algorithm
Step 2 can be integrated in step 1 by stopping the branch recursion when a set of points is already too large. This does not change the need to scan the element at least once, but it can reduce the number significantly: think of cases where there are no solutions because all points are separated more than the size of the rectangle, that can be found in O(N2).
Also, the permutation generator in step 1 can be made to return the points in order by x or y coordinate, by pre-sorting the point array correspondingly. This is useful because it lets us discard a bunch of more possibilities up front. Suppose the array is sorted by y coordinate, so the k-plets returned will be ordered by y coordinate. Now, supposing we are discarding a branch because it contains a point whose y coordinate is outside the max rectangle, we can also discard all the next sibling branches because their y coordinate will be more than of equal to the current one which is already out of bounds.
This adds O(n log n) for the sort, but the improvement can be quite significant in many cases -- again, when there are many outliers. The coordinate should be chosen corresponding to the minimum rectangle side, divided by the corresponding side of the 2D field -- by which I mean the maximum coordinate minus the minimum coordinate of all points.
Finally, if all the points lie within an a×b rectangle, then the algorithm performs as O(k Nk) anyways. If this is a concrete possibility, it should be checked, an easy O(N) loop, and if so then it's enough to return the points with the top N weights, which is also O(N).