# Algorithm that schedule the right number of tasks to maximize reward: tough or basic?

In the ith week, you have the choice of:

• doing nothing
• doing an basic task with a reward bi
• doing an tough task with a reward ti

If you choose to do a tough task, you must have 'done nothing' in the previous week [i-1]

What tasks must we choose we do to maximize reward? We can assume bi and ti are > 0.

My attempt

A greedy solution that I designed is to compare t_2 and b_1+b_2, it t_2 is higher, do nothing and on the next week do a tough task; if not, do basic tasks. Keep on doing this procedure until the end. Unfortunately, this does not obtain the optimal solution.

Does anyone have some sort of idea of an algorithm that obtains the optimal solution?

I suggest to use the Dynamic Programming technique to tackle this problem as it is more straight-forward and intuitive. The setup of the DP is as follow:

Let `P[i]` denotes the optimal reward from week 1 till week i, then we have the following recurrence relation:

`P[i] = max{ P[i-2] + ti, P[i-1] + bi }` for `i ≥ 2`.

And the base cases are `P[0] = 0, P[1] = b1` (assume you can only do basic task in week 1).

### Update

Proof of optimality. Observe that the optimal solution `P[i]` must consists of either `bi` or `ti` (the contrapositive statement can be proved easily).

In the case `P[i]` uses `bi`, the best possible solution is `P[i] = P[i - 1] + bi` (because by definition `P[i - 1]` is the optimal solution). On the other hand, if `P[i]` uses `ti`, then the best possible solution is `P[i] = P[i - 2] + ti`.

• Doing nothing will not give you an optimal solution. If you have a solution `Q[i]` that does nothing in week i, `Q[i] + bi` will always be a better solution. Commented Nov 17, 2014 at 3:38
• Yes, the optimal solution of that case is given by P[i - 2] + ti Commented Nov 17, 2014 at 3:48