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Karatsuba Algorithm involves the recursion relation T(n) = 3T(n/2) + n.

By the recursion tree method, we can approximate the big O of T to be O(nlog23)

However, by the substitution method I am having trouble verifying the approximate result I found by the recursion tree method

I'll simply use lg 3 to mean log23.

Substitution method:

Hypothesis -> T(n) <= cnlg 3 where c is a positive constant
Proof -> T(n) <= 3c(n/2)lg 3 + n
                  =  cnlg 3 + n

But step 2 of the proof shows that I cannot prove my hypothesis because of n term.

I modified step 2 of proof

T(n) <= cnlg 3 + nlg 3
      = (c+1)nlg 3

And later realized I had made a mistake because the hypothesis is not proven.

T(n) <= cnlg 3 has to be proven, not T(n) <= (c+1)nlg 3

But the answer is T(n) is O(nlg 3)

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1 Answer 1

When using the substitution method, you sometimes have to strengthen the inductive hypothesis and guess a more complex form of the expression that upper-bounds the recurrence.

Try making a guess of the form T(n) ≤ c0 nlg 3 - c1n. Now that you are subtracting some term of the form c1 n, you can probably make the recurrence work out by using some of the linear term to offset the n term added in later.

For example:

T(n) ≤ 3T(n / 2) + n

≤ 3(c0(n/2)lg 3 - c1(n/2)) + n

= 3(c0(n/2)lg 3) - 3c1n/2 + n

Now, choose c1 so that -3c1n/2 + n = -c1n. This solves to

-3c1n/2 + n = -c1n

-3c1/2 + 1 = -c1

-3c1 + 2 = -2c1

2 = c1

This choice of c1 will then let you cancel out the +n term successfully, letting the induction work successfully.

Hope this helps!

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Thanks.It helped –  tcp Nov 2 '13 at 17:48

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