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The statement goes this way(this scenario occurs while choosing which all matrix pair to be parenthesized for optimal matrix multiplication)

p(n)=Summation of P(k)P(k-n) is omega(2^n) for k=1 to n-1 and for n>=2.

p(n) is number of combinations of alternate parenthesis.

say p(3)=A1(A2*A3) or (A1*A2)A3 or (A1*A2*A3)

k:split value

n=no of matrices

I solved this equation using recursion.

lets say I have four matrices A1,A2,A3,A4.

lets say k=2 and we have n=4.

p(4)=p(1)p(3)+p(2)p(2)

solving recursively for p(3) and p(2) we get:

p(4)=p(1)p(3)+p(2)p(2)+p(1)p(1)p(2)+p(1)p(2)p(1)+p(1)p(1)p(1)p(1).

what it implies is we can parenthesis A1A2A3A4 in following ways

p(4)=A1(A2A3A4) or (A1A2)(A3A4) or (A1)(A2)(A3A4) or (A1)(A2A3)(A4) or (A1)(A2)(A3)(A4)

My question is:

for n=3 p(n)=3 and for n=4 p(n)=5

then how come p(n)=summation of p(k)p(n-k) is omega(2^n)???

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please do care downvoting –  Gaurav Patil Mar 21 '13 at 15:22
    
Why dont you do it for more number of ns, say n=10, n=1000, n=1000000 ? You will probably see why the complexity makes sense. –  ElKamina Mar 21 '13 at 15:30

1 Answer 1

p(n) is catalan number = (2n choose n)/(n+1) and that is Theta(4^n/n sqrt(n)) (using Stirling's formula) and so is Omega(2^n).

You cannot determined whether a function is Omega(2^n) by examining just two values!

Since the bound you are seeking is so weak as compared to the actual theta value, there is probably a simpler proof.

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