The Answer is O(max{f(n), g(n)})

This is only correct if the programms run independently of each other. Anyhow, let's assume, this is the case.

In order to answer the *why*, we need to take a closer look at what the *BIG-O-notation* represents. Contrary to the way you stated it, it **does not represent time** but an **upperbound on the complexity**.

So while running both programms might take more time, the upperbound on the complexity won't increase.

Lets considder an example: P_1 calculates the the product of all pairs of n numbers in a vector, it is implemented using nested loops, and therefore has a complexity of `O(n*n)`

. P_2 just prints the numbers in a single loop and therefore has a complexity of `O(n)`

.

Now if we run both programms at the same time, the nested loops of P_1 are the most *'complex'* part, leaving the combination with a complexity of `O(n*n)`