# For each element A[i] of array A, find the closest j such that A[j] > A[i]

Given : An array `A[1..n]` of real numbers.

Goal : An array `D[1..n]` such that

``````D[i] = min{ distance(i,j) : A[j] > A[i] }
``````

or some default value (like 0) when there is no higher-valued element. I would really like to use Euclidean distance here.

Example :

``````A = [-1.35, 3.03, 0.73, -0.06, 0.71, -0.21, -0.12, 1.49, 1.41, 1.42]
D = [1, 0, 1, 1, 2, 1, 1, 6, 1, 2]
``````

Is there any way to beat the obvious O(`n`^2) solution? The only progress I've made so far is that `D[i] = 1` whenever `A[i]` is not a local maxima. I've been thinking a lot and have come up with NOTHING. I hope to eventually extend this to 2D (so `A` and `D` are matrices).

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Your notation is nice and concise, but it might be more useful (and you might get more answers) if you explained things in English. –  noah Mar 31 '10 at 20:08
Needs `homework` tag ? –  Paul R Mar 31 '10 at 21:08
noah: Thanks!! I tried writing the title with less notation, but when I presented it to the two guys who sit next to me, they didn't like it. The best I could come up with was "At each element of an array, find the nearest array element of higher value." Paul R: This is actually a small part of a bigger project I'm working on which is not homework. But you're right, it does look like homework. –  SamH Mar 31 '10 at 21:32

• Seems like dynamic programming could be helpful here, if you can figure out a way to solve for each element based on the solution for its neighbors (augmenting the answers with information like the `j` for each `A[i]` instead of just the distance maybe).