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There is one locality given, that is represented by a matrix and every entry indicates the number of cars in that area. Our task is to place a petrol pump at one entry in the matrix, so that the block we choose that gives the minimum travel cost.

I found a solution that takes O(n^4) time in which we compute the whole process for every entry.

Can you tell me any other good approach for this question?

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How is the cost defined? – fgb Aug 25 '12 at 15:38
move one path is equal to one unit cost – devsda Aug 25 '12 at 16:06
Do you mean that the cost from the block x to the location of the pump is the number of the cars in x multiplied by the manhattan distance from x to the pump? – Haile Aug 25 '12 at 17:17
exactly the same – devsda Aug 25 '12 at 19:52
Is this a homework problem? ... if so, you've just got three bright people to do your homework for you... – Assad Ebrahim Aug 25 '12 at 19:58
up vote 4 down vote accepted

I'll expand Rupert's answer with a practical example (i.e. how to compute what he calls the median row and column).

As he said, you can find the optimal row and the optimal column for the pump separaterly. How?

Let us consider the following instance of the problem:

3 2 7
1 8 9 
7 2 2
  • First, we find the optimal row for the pump

We start adding all the rows of the matrix

3 2 7 -> 12
1 8 9 -> 18
7 2 2 -> 11

now if we place the pump in the first row, the total vertical cost is

11*2 + 18*1 + 12*0 = 30

since the 11 cars in row 3 have to travel for 2 vertical units, the 18 cars in row 2 have to travel for 1 vertical unit, and the cars in row 1 do not have to travel in vertical. We have to compute the total vertical travel cost for all the rows.

pump in 1st row -> cost 30 = 11*2 + 18*1 + 12*0
pump in 2nd row -> cost 23 = 11*1 + 18*0 + 12*1
pump in 3rd row -> cost 42 = 11*0 + 18*1 + 12*2

so the optimal row for the pump is the 2nd.

We computed this in O(n^2), since we did O(n^2) sums when the summed all the n cars in the n rows, and we did O(n^2) sums and multiplication when we computed the total vertical cost for each possible row for the pump.

  • Now we find the optimal column for the pump

We sum the cars in each column:

3  2  7
1  8  9 
7  2  2
11 12 18


pump in 1st col -> cost 48 = 11*0 + 12*1 + 18*2
pump in 2nd col -> cost 29 = 11*1 + 12*0 + 18*1
pump in 3rd col -> cost 34 = 11*2 + 12*1 + 18*0

so the optimal column for the pump is the 2nd.

In O(n^2) steps, we found that we have to place the pump in [2][2].

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Thanks, that's probably much less obscure to read than my original! :-) – Rupert Swarbrick Aug 25 '12 at 19:37

If I've understood your question correctly, so your cost function is as Haile describes in his/her comment, there's an easy solution since you can reduce to a one-dimensional problem.

Note that in the Manhattan metric, the distance in columns that the cars must traverse is just summed with the distance in rows, so we can minimise them separately.

So we've reduced the problem to one dimension. To work out what was going on, I had to switch this to a continuous problem. So suppose that I have a density function, p(x), (let's say it's continuous with compact support, so that the maths works). Then the cost function is given by

\int p(x) |x-x0|

Splitting this into two halves to get rid of the mod sign and differentiating (this is where you need to assume p(x) is well behaved), you get

\int_-\infty^x_0 p(x) - \int_{x_0}^\infty p(x)

Now, the optimal position for x0 is going to be the one that makes this derivative zero. But notice that this is the median of the distribution.

For the discrete setting, which was the original question, the same arguments work. Basically you can take a discrete derivative, which is E(k+1)-E(k). If you write a[n] for the number of cars at position n, then the cost function splits up as

E(k) = \sum_{n<k} a_n(k-n) + \sum_{n>k} a_n(n-k)

Assuming I haven't made a stupid mistake, the discrete derivative comes out as

E(k+1)-E(k) = \sum_{n<k+1} a_n - \sum_{n>k+1} a_n

so the solution will be at the median again (rounded either way if you end up at a half-integer). To see why this is true, note that if k is a large negative number, this derivative is definitely negative (so increasing k by 1 will decrease the cost). Now, as k increases, the derivative slowly increases. At some point, it will become positive for the first time. This happens as soon as k+1 is larger than the median. After that, it will stay positive, so the correct k to choose is the largest k less than or equal to the median.

The original question was in two dimensions, so you need to run this twice, once for each axis.

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I think so: Suppose we are in a 1d situation with cars spaced on the real line. Then the total distance travelled is the sum over cars of the distance between pump and that car. I'm pretty certain that this sum is minimised at the mean position of the cars. – Rupert Swarbrick Aug 25 '12 at 18:38
(Er, that comment was in response to one that seems to have gotten deleted: it's meant to justify why taking the mean is the correct thing to do on each axis) – Rupert Swarbrick Aug 25 '12 at 18:40
sorry for deleting my comment, i wanted to double-check. anyway, imagine that there are just two populated blocks, one with 9 and the other with 10 cars - the optimal location is always in the cell with the 10 cars, although the mean location may vary – staafl Aug 25 '12 at 18:40
the more i think about it, the more it seems as though brute-forcing is the only way (every solution i come up with seems to be equivalent). still, O(n^2) per side of matrix isn't bad. @RupertSwarbrick, kudos for catching the invariant. – staafl Aug 25 '12 at 19:00
@Haile, to find the optimal column, you need to sum the rows into an n element vector and scalar multiply it by each of the n vectors of the form (0..n-1),(1,0,1..n-2),(2,1,0..n-3), finding the least product => O(n^2) – staafl Aug 25 '12 at 19:07

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