I believe I can do this is O(n log n).
First, sort the
B array, applying the same permutation to the
A array (and remembering the permutation). This is the O(n log n) part. Since we sum over all i, applying the same permutation to the A and B arrays does not change the minimum.
With a sorted
B array, the rest of the algorithm is actually O(n).
For each k, define an array Ck[i] = |B[i] - B[k]|
(Note: We will not actually construct Ck... We will just use it as a concept for easier reasoning.)
Observe that the quantity we are trying to minimize (over k) is the sum of A[i] * Ck[i]. Let's go ahead and give that a name:
Define: Sk = Σ A[i] * Ck[i]
Now, for any particular k, what does Ck look like?
Well, Ck[k] = 0, obviously.
More interestingly, since the B array is sorted, we can get rid of the absolute value signs:
- Ck[i] = B[k] - B[i], for 0 <= i < k
- Ck[i] = 0, for i = k
- Ck[i] = B[i] - B[k], for k < i < n
Let's define two more things.
Definition: Tk = Σ A[i] for 0 <= i < k
Definition: Uk = Σ A[i] for k < i < n
(That is, Tk is the sum of the first k-1 elements of A. Uk is the sum of all but the first k elements of A.)
The key observation: Given Sk, Tk, and Uk, we can compute Sk+1, Tk+1, and Uk+1 in constant time. How?
T and U are easy.
The question is, how do we get from Sk to Sk+1?
Consider what happens to Ck when we go to Ck+1. We simply add B[k+1]-B[k] to every element of C from 0 to k, and we subtract the same amount from every element of C from k+1 to n (prove this). That means we just need to add Tk * (B[k+1] - B[k]) and subtract Uk * (B[k+1] - B[k]) to get from Sk to Sk+1.
Algebraically... The first k terms of Sk are just the sum from 0 to k-1 of A[i] * (B[k] - B[i]).
The first k terms of Sk+1 are the sum from 0 to k-1 of A[i] * (B[k+1] - B[i])
The difference between these is the sum, from 0 to k-1, of (A[i] * (B[k+1] - B[i]) - (A[i] * (B[k] - B[i])). Factor out the A[i] terms and cancel the B[i] terms to get the sum from 0 to k-1 of A[i] * (B[k+1] - B[k]), which is just Tk * (B[k+1] - B[k]).
Similarly for the last n-k-1 terms of Sk.
Since we can compute S0, T0, and U0 in linear time, and we can go from Sk to Sk+1 in constant time, we can calculate all of the Sk in linear time. So do that, remember the smallest, and you are done.
Use the inverse of the sort permutation to get the
k for the original arrays.