I would like to write a dynamic programming algorithm that solves the following problem; for that, I would like to define the proper recurrence relation. This is the statement of the problem: Consider a straight road with a length of K miles on which we seek to place phone antennas. Available sites are characterized by the integers x1, x2,. . . , xn where xi represents the position in miles, of an antennas along the road (0 ≤ xi ≤ K). In addition, an antenna placed at position xi generates a revenue of r (0 ≤ i ≤ n). The distance between two successive antennas cannot be less than or equal to 5 kilometers. How and where should you place your antennas to maximize your revenue.

Here's the recurrence relation that I wrote: variable parameters are: k: the length of the road xi: the position of the antenna xi-x (i +1)> 5

This is to maximize the number of antennas to be placed. Thus, let N be the number of antennas to be placed. Then N depends on k and xi. First, if the first antenna is placed at position xi, then there is k kilometer on which it is possible to place antennas. The antenna will be placed next to the position 5 + xi, then it will remain k-5-kilometers xi on which it is possible to place antennas. If I decide not to plant the antenna of the position xi, so I can plant them in position 5 + xi.

Hence my following recurrence relation: N (k, i) = max (Nxi, k) + N5 + xi, N (xi, in) & & N (xi, in)

Is is correct? Thanks.

This is my algorithm (I want an algorithm in ** O(n)**):

```
Algorithm Antenna(\emph{int K, int xi, int profit)
{
int K: road lenght
int xi: position of antenna i
While{j < k}
{
xi = j
if{xi < k}
{
return idealPosition
}
j = j+5
return profit
}
}
```

About the profit, the more you have antenna, the more you have profit.