# Recurrence Relation: Solving Big O of T(n-1)

I'm solving some recurrence relation problems for Big O and so far up till this point have only encountered recurrence relations that involved this form:

``````T(n) = a*T(n/b) + f(n)
``````

For the above, it's quite easy for me to find the Big O notation. But I was recently thrown a curve ball with the following equation:

``````T(n) = T(n-1) + 2
``````

I'm not really sure how to go around solving this for Big O. I've actually tried plugging in the equation as what follows:

``````T(n) = T(n-1) + 2
T(n-1) = T(n-2)
T(n-2) = T(n-3)
``````

I'm not entirely sure if this is correct, but I'm stuck and need some help. Thanks!

Assuming T(1) = 0

``````T(n) = T(n-1) + 2
= (T(n-2) + 2) + 2
= T(n-2) + 4
= (T(n-3) + 2) + 4
= T(n-3) + 6
= T(n-k) + 2k
``````

Set k to n-1 and you have

``````T(n) = 2n - 2
``````

Hence, it's O(n)

• @AndreasJansson I do not follow your algebra on the first two steps. You claim that \$T(n-1) + 2 = (T(n-2) + 2) + 2\$ but I do not see how you come to this conclusion. Nothing in the problem hints at this so how can you make this assumption? What if \$T(2) = 10000000000000000\$ we don't know so how can you assume that it isn't?
– user1174868
Feb 21, 2015 at 18:54
• @ripDaddy69 If we plug in (n-1) into the original T(n) we get, T(n-1) = T(n-2) + 2. Right? Now if we replace T(n-1) on the first line with T(n-2)+2 we get the second line. Jan 30, 2016 at 23:55

Since the question is already answered, let me add some intuition behind how to find the complexity of the recurrence.

• Master theorem applies only to the divide and conquer type recurrences, like `T(n) = a*T(n/b) + f(n)` where `a` is the number of subproblems and each of these subproblem's size is `1/b` of the original problem. But recurrence `T(n) = T(n-1) + 2` does not technically "divide" the problem into subproblems. so master theorem does not apply here.
• If we closely look at the recurrence, it is pretty clear that it goes over `n` steps and each step takes constant time, which is `2` in this case. So the complexity would be `O(n)`.

I especially found the second intuition very helpful for most of the recurrences (may be not all). As an example, you can try the same for a similar recurrence `T(n) = T(n-1) + n`, for which the complexity is, of course, `O(n^2)`.

T(n) = 2*n = 2*(n-1)+2 = T(n-1)+2

So T(n) = 2*n which implies O(n)