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 C_{k}[i] = |B[i] - B[k]|

(Note: We will not actually construct C_{k}... 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] * C_{k}[i]. Let's go ahead and give that a name:

Define: S_{k} = Σ A[i] * C_{k}[i]

Now, for any particular k, what does C_{k} look like?

Well, C_{k}[k] = 0, obviously.

More interestingly, since the B array is sorted, we can get rid of the absolute value signs:

- C
_{k}[i] = B[k] - B[i], for 0 <= i < k
- C
_{k}[i] = 0, for i = k
- C
_{k}[i] = B[i] - B[k], for k < i < n

Let's define two more things.

Definition: T_{k} = Σ A[i] for 0 <= i < k

Definition: U_{k} = Σ A[i] for k < i < n

(That is, T_{k} is the sum of the first k-1 elements of A. U_{k} is the sum of all but the first k elements of A.)

The key observation: Given S_{k}, T_{k}, and U_{k}, we can compute S_{k+1}, T_{k+1}, and U_{k+1} in constant time. How?

T and U are easy.

The question is, how do we get from S_{k} to S_{k+1}?

Consider what happens to C_{k} when we go to C_{k+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 T_{k} * (B[k+1] - B[k]) and subtract U_{k} * (B[k+1] - B[k]) to get from S_{k} to S_{k+1}.

Algebraically... The first k terms of S_{k} are just the sum from 0 to k-1 of A[i] * (B[k] - B[i]).

The first k terms of S_{k+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 T_{k} * (B[k+1] - B[k]).

Similarly for the last n-k-1 terms of S_{k}.

Since we can compute S_{0}, T_{0}, and U_{0} in linear time, and we can go from S_{k} to S_{k+1} in constant time, we can calculate all of the S_{k} 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.