I believe you can perform the access in O(log(N)) time, given O(N log(N)) preprocessing time and O(N log(N)) extra space. Here's how.
You can augment a red-black tree to support a
select(i) operation which retrieves the element at rank
i in O(log(N)) time. For example, see this PDF or the appropriate chapter of Introduction to Algorithms.
You can implement a red-black tree (even one augmented to support
select(i)) in a functional manner, such that the insert operation returns a new tree which shares all but O(log(N)) nodes with the old tree. See for example Purely Functional Data Structures by Chris Okasaki.
We will build an array
T of purely functional augmented red-black trees, such that the tree
T[j] stores the indexes
0 ... j-1 of the first
j elements of
A sorted largest to smallest.
Base case: At
T create an augmented red-black tree with just one node, whose data is the number 0, which is the index of the 0th largest element in the first 1 elements of your array
Inductive step: For each
j from 1 to
T[j] create an augmented red-black tree by purely functionally inserting a new node with index
j into the tree
T[j-1]. This creates at most O(log(j)) new nodes; the remaining nodes are shared with
T[j-1]. This takes O(log(j)) time.
The total time to construct the array
T is O(N log(N)) and the total space used is also O(N log(N)).
T[j-1] is created, you can access the
ith largest element of the first
j elements of
A by performing
T[j-1].select(i). This takes O(log(j)) time. Note that you can create
T[j-1] lazily the first time it is needed. If
A is very large and
j is always relatively small, this will save a lot of time and space.