Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Well the problem is quite easy to solve naively in O(n3) time. The problem is something like:

There are N unique points on a number line. You want to cover every single point on the number line with some set of intervals. You can place an interval anywhere, and it costs B + MX to create an interval, where B is the initial cost of creating an interval, and X is half the length of the interval, and M is the cost per length of interval. You want to find the minimum cost to cover every single interval.

Sample data:

Points = {0, 7, 100}
B = 20
M = 5

So the optimal solution would be 57.50 because you can build an interval [0,7] at cost 20 + 3.5×5 and build an interval at [100,100] at cost 100 + 0×5, which adds up to 57.50.

I have an O(n3) solution, where the DP is minimum cost to cover points from [left, right]. So the answer would be in DP[1][N]. For every pair (i,j) I just iterate over k = {i...j-1} and compute DP[i][k] + DP[k + 1][j].

However, this solution is O(n3) (kind of like matrix multiplication I think) so it's too slow on N > 2000. Any way to optimize this?

share|improve this question

1 Answer 1

up vote 2 down vote accepted

Here's a quadratic solution:

  1. Sort all the points by coordinate. Call the points p.

  2. We'll keep an array A such that A[k] is the minimum cost to cover the first k points. Set A[0] to zero and all other elements to infinity.

  3. For each k from 0 to n-1 and for each l from k+1 to n, set A[l] = min(A[l], A[k] + B + M*(p[l-1] - p[k])/2);

You should be able to convince yourself that, at the end, A[n] is the minimum cost to cover all n points. (We considered all possible minimal covering intervals and we did so from "left to right" in a certain sense.)

You can speed this up so that it runs in O(n log n) time; replace step 3 with the following:

Set A[1] = B. For each k from 2 to n, set A[k] = A[k-1] + min(M/2 * (p[k-1] - p[k-2]), B).

The idea here is that we either extend the previous interval to cover the next point or we end the previous interval at p[k-2] and begin a new one at p[k-1]. And the only thing we need to know to make that decision is the distance between the two points.

Notice also that, when computing A[k], I only needed the value of A[k-1]. In particular, you don't need to store the whole array A; only its most recent element.

share|improve this answer
    
very nice observation. –  Forza Dec 15 '12 at 6:12
    
Also can you explain how you arrived at O(n log n) on the complexity for the second solution? Shouldn't it be O(n)? –  Forza Dec 15 '12 at 6:19
    
You still need to sort the input. That takes more than linear time. –  tmyklebu Dec 15 '12 at 19:28

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.