I'll sketch a correct, poly-time algorithm. Undoubtedly there are data-structural improvements to be made, but I believe that a better understanding of this problem in particular will be required to search very large datasets (or, perhaps, an ad-hoc upper bound on the dimensions of the box containing the polygon).

The main loop consists of guessing the lowest point p in the largest convex polygon (breaking ties in favor of the leftmost point) and then computing the largest convex polygon that can be with p and points q such that (q.y > p.y) || (q.y == p.y && q.x > p.x).

The dynamic program relies on the same geometric facts as Graham's scan. Assume without loss of generality that p = (0, 0) and sort the points q in order of the counterclockwise angle they make with the x-axis (compare two points by considering the sign of their dot product). Let the points in sorted order be q_{1}, …, q_{n}. Let q_{0} = p. For each 0 ≤ i < j ≤ n, we're going to compute the largest convex polygon on points q_{0}, a subset of q_{1}, …, q_{i - 1}, q_{i}, and q_{j}.

The base cases where i = 0 are easy, since the only “polygon” is the zero-area segment q_{0}q_{j}. Inductively, to compute the (i, j) entry, we're going to try, for all 0 ≤ k ≤ i, extending the (k, i) polygon with (i, j). When can we do this? In the first place, the triangle q_{0}q_{i}q_{j} must not contain other points. The other condition is that the angle q_{k}q_{i}q_{j} had better not be a right turn (once again, check the sign of the appropriate dot product).

At the end, return the largest polygon found. Why does this work? It's not hard to prove that convex polygons have the optimal substructure required by the dynamic program and that the program considers exactly those polygons satisfying Graham's characterization of convexity.