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I have come across this in multiple sources (online and books) - Running time of square matrix multiplication is O(n^3) for matrices of size nXn. (example - matrix multiplication algorithm time complexity)

This statement would indicate that the upper bound on running time of this multiplication process is C.n^3 where C is some constant and n>n0 where n0 is some input beyond which this upper bound holds true. (http://en.wikipedia.org/wiki/Big_O_notation and What is the difference between Θ(n) and O(n)?) Problem is, i cannot seem to derive the values of constants C and n0.

My questions -

  1. Can someone provide a mathematical proof for the statement 'big Oh of square matrix multiplication is O(n^3)' ?

  2. what are the values of C and n0 ?

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For each cell (n^2), you will go through n cells in the corresponding rows and columns and multiply them together, so it's O(n^3). –  nhahtdh Nov 22 '12 at 7:00
    
so if we have 2 matrices A and B each is nXn. and their product is matrix X of size nXn. you are implying that for each value in X (there are n^2 values in X) you have to traverse a total of n elements in A and B ? or is that more like n elements in A and n elements in B, which would make this n^4 and not n^3. –  Quest Monger Nov 22 '12 at 7:09
    
n elements in A and n elements in B, yes, but it totals up to 2n, not n^2. So the final result is O(n^3). –  nhahtdh Nov 22 '12 at 7:39

1 Answer 1

up vote 2 down vote accepted
  1. There are 3 for loops within each other going from 0 to n-1 (or 1 to n) each (as can be seen in the link you provided, even though it's not completely correct), this results in O(n^3). Formalizing it into a proper proof should be easy enough.

  2. a) Running time is usually defined in terms of the most expensive operation, which is probably multiplication in this case. So inside the 3 for loops there is a single multiplication operation, thus 1.n^3, thus C = 1. An alternative is using array references (C = 3 or 4, depending on implementation (it isn't necessary to reference the output array in the inner-most loop)).

    b) n0 = 0 because this holds true from n = 1

Note that there is a rather significant difference between an upper bound (what you said, even though you may have meant asymptotic) and an asymptotic upper bound (what O(f(n)) uses). If asymptotic was not a requirement, the complexity of this algorithm can be O(n^k) for any k >= 3.

EDIT: Another choice for the most expensive operation is any arithmetic operation, then C = 2.

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thanks! and thank you for correcting my mistake, i meant an asymptotic upper bound. sorry for confusion. relevant - mathforum.org/library/drmath/view/51904.html –  Quest Monger Nov 25 '12 at 0:29
    
@QuestMonger thank you so much for the mathforum link... that was the most easy to understand answer I have yet to come across! –  Titus Aug 28 at 16:57

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