# Time complexity of two algorithms running together?

Imagine T1(n) and T2(n) are running times of P1 and P2 programs, and

T1(n) ∈ O(f(n))

T2(n) ∈ O(g(n))

What is the amount of T1(n)+T2(n), when P1 is running along side P2?

The Answer is `O(max{f(n), g(n)})` but why?

When we think about Big-O notation, we generally think about what the algorithm does as the size of the input `n` gets really big. A lot of times, we can fall back on some sort of intuition with math. Consider two functions, one that is `O(n^2)` and one that is `O(n)`. As `n` gets really large, both algorithms increases without bound. The difference is, the `O(n^2)` algorithm grows much, MUCH faster than `O(n)`. So much, in fact, that if you combine the algorithms into something that would be `O(n^2+n)`, the factor of `n` by itself is so small that it can be ignored, and the algorithm is still in the class `O(n^2)`.

That's why when you add together two algorithms, the combined running time is in `O(max{f(n), g(n)})`. There's always one that 'dominates' the runtime, making the affect of the other negligible.

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)`