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] + t`_{i}, P[i-1] + b_{i} }

for `i ≥ 2`

.

And the base cases are `P[0] = 0, P[1] = b`_{1}

(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 `b`_{i}

or `t`_{i}

(the contrapositive statement can be proved easily).

In the case `P[i]`

uses `b`_{i}

, the best possible solution is `P[i] = P[i - 1] + b`_{i}

(because by definition `P[i - 1]`

is the *optimal* solution). On the other hand, if `P[i]`

uses `t`_{i}

, then the best possible solution is `P[i] = P[i - 2] + t`_{i}

.