# What's the run time of: T(n) = 2T(n-1) + 3T(n-2)+ 1

How do you solve this? I understand that it is similar to the Fibonacci sequence that has an exponential running time. However this recurrence relation has more branches. What are the asymptotic bounds of T(n) = 2T(n-1) + 3T(n-2)+ 1?

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If you know the starting terms, you can write it out by hand. T(0) = ? T(1)= ?. From that you can get the rest of the terms –  Jason Feb 20 '13 at 21:57
The number of branches in t(n) = F(t(n-1),t(n-2)) is the same for any F, so if you have the solution for the Fibonacci sequence, ... –  Joni Feb 20 '13 at 22:15

Usually, you will need to make some assumptions on T(0) and T(1), because there will be exponentially many of them and their values may determine the functional form of T(n). However in this case it doesn't seem to matter.

Then, recurrence relations of this form can be solved by finding their characteristic polynomials. I found this article: http://www.wikihow.com/Solve-Recurrence-Relations

I obtained the characteristic polynomial with roots 3 and 1, so that guesses the form `T(n) = c_1*3^n + c_2`. In particular, `T(n) = 1/2*3^n - 1/4` satisfies the recurrence relation, and we can verify this.

``````1/2*3^n - 1/4 = 2*T(n-1) + 3*T(n-2) + 1
= 2*(1/2*3^(n-1) - 1/4) + 3*(1/2*3^(n-2) - 1/4) + 1
= 3^(n-1) - 1/2 + 1/2*3^(n-1) - 3/4 + 1
= 3/2*3^(n-1) - 1/4
= 1/2*3^n - 1/4
``````

Hence it would give that `T(n) = Theta(3^n)`. However, this may not be the only function that satisfies the recurrence and other possibilities will also depend on what you defined the values `T(0)` and `T(1)`, but they should all be `O(3^n)`.

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This does not actually answer the question. –  user85109 Feb 20 '13 at 23:49
Why doesn't it solve the question? I give you a function that satisfies the recurrence relation and proved as such. –  Andrew Mao Feb 21 '13 at 1:07
Because the question had ABSOLUTELY NOTHING to do with an analytical solution. –  user85109 Feb 21 '13 at 3:24
You are being really disrespectful. I don't think you understood the question at all, and now you are trolling two people that tried to answer it. `T(n)` is the running time for an algorithm on a particular input of size `n`, and the recurrence relation defines its structure with recursion. We are trying to solve for `T(n)` using this recurrence relation. What do you think the question is about? Perhaps you should answer it if you think you're such a hotshot. –  Andrew Mao Feb 21 '13 at 4:16
A fibonacci type recurrence relation (when applied recursively) will have exponentially many recursive calls. This is the comment about exponential run time. Your answer fails to touch on the branching aspect. –  user85109 Feb 21 '13 at 13:40

This is a linear recurrence. There are several methods for solving it. One is this

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And this answer too is NOT relevant to answering the question. The problem is NOT how to solve a linear recurrence relation using analytical methods. –  user85109 Feb 21 '13 at 3:29
Did you ever stop to think that if two people answer the same question similarly and they both disagree with your intepretation, then your intepretation of the question might be wrong? How about we stop with the downvote trolling and power tripping? –  Andrew Mao Feb 21 '13 at 4:25
Thanks for helping me. –  Anne Apr 5 '13 at 12:38