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Hey im having trouble calculating the complexity of Laplace Expansion using my code:

def determinant_laplace(self, i=0):
    assert self.dim()[0] == self.dim()[1]
    if self.dim() == (1,1):
        return self[0,0]
    else:
        det = 0
        for col in range(self.dim()[1]):
            det += ((-1)**(col+i) *self[i,col]* self.minor(i,col).determinant_laplace())
        return det

to better undestand this here is how a minor is calculated (in my code):

def minor(self, i, j):
    t = self.dim()[0] # rows
    k = self.dim()[1] # columns
    assert isinstance(i, int) and isinstance(j, int) \
    and i < t and j < k
    newMat = Matrix(t-1,k-1) # new matrix will be with 1 less col and row
    for row in range(t):
        for col in range(k):
            if row < i and col < j:
                newMat[row,col] = self[row,col]
            elif row < i and col > j:
                newMat[row,col-1] = self[row,col]

            elif row > i and col < j:
                newMat[row-1,col] = self[row,col]

            elif row > i and col > j:
                newMat[row-1,col-1] = self[row,col]
    return newMat

as you can see, the complexity of creating a minor in nxn matrix is O(n^2).

so i'm torn by the overall complexity is it O(n!) or O((n+1)!) or O((n+2)!) ?

Why it's O(n!) : Wikipedia says so, but I guess their implementation is different and maybe they neglect some calculating regarding the minor.

Why it's O((n+1))! : The recursion sequence is n(n^2 + next(recursion_minor)..) = O(n*n!) = O((n+1)!)

Why it's O((n+2)!) : calculating a minor is O(n^2) and we calculate n! of those so we get O(n^2)*O(n!)=O(n+2)!

Personnaly I lean towards the Bold statement.

Thanks for your help.

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2 Answers 2

up vote 2 down vote accepted

Let f(n) be the time it takes for determinant_laplace to complete given any square matrix of size n by n.

There are n minors to be computed.

For each minor it takes

  • O((n-1)**2) = O(n**2) time to create the minor
  • plus f(n-1) time to compute the determinant_laplace of the minor

So a recurrence inequality satisfied by f is:

f(n) <= n(C*n**2 + f(n-1))

for some C and for all n bigger than some constant M. I do not know what C and M are, but we can take them to be known, constant values.


Consider the hypothesis H(n):

f(n) <= D * n * n!

for some constant D>0 which is independent of n.


Base cases: For n = 1, ..., M, we can find some constant D so huge such that

H(1), ..., H(M) are true, and D>C.

Preliminary observation: Note that n**3/n! < 1 for n >= 6, and we can assume without loss of generality that M>6.


Induction step: Take some n > M and assume H(n-1).

f(n) <= n(C*n**2 + f(n-1))          # by our recurrence inequality
     <= C*n**3 + n*D*(n-1)*(n-1)!   # by H(n-1)
      = C*n**3 + D*(n-1)*n!
     <= C*n! + D*(n-1)*n!           # since n**3 / n! < 1 and n > M > 6
      = (C+D*(n-1))*n! 
     <= D*n*n!                      # since D > C

So H(n) is true. Therefore f(n) is in O(n*n!).

Note however, that this is a loose upper bound. Essentially the same induction proof can be used to show that f(n) is in O(n**(1/p)*n!) for any p = 1, 2, 3, ....

share|improve this answer
    
Wait, I am not convinced of this. Why is O(n!) = O((n+1)!) = O((n+2)!) ? when n goes to infinity this is completely different... by your claim it is also correct that: O(n) = O(n*(n+1)) which is obviously false. Can you prove that this is correct by definition? –  Matthew D May 20 '13 at 18:56
    
Oops, you are right. They are not the same! –  unutbu May 20 '13 at 19:04
    
This proof is kinda 'risky'. If I assume O(f(n))=O((n+1)!) I would say O(f(n+1))=O((n+1)*(n^2+f(n))=O((n+1)*(n+1)!)=O((n+2)!). the induction is kind of 'broken' there are no base cases. Can you explain this a bit more or explain why my statement above is incorrect? –  Matthew D May 21 '13 at 6:09
    
Yes, I've been too sloppy. When I write out all the details, I get f in O(n*n!), not O(n!). –  unutbu May 21 '13 at 10:34

I think that O(n+2)! is the right answer. as you mentioned the complexity to generate the minor ij for Matrix in size n x n is O(n^2) which derive from the slicing (o(k) in python) in your code. At the end of the Recursion you will get n! minors(in size 1 x 1). So we got here:

O(n^2) * O(n!) = O(n!(n+1)(n+2)) = O(n+2)!
share|improve this answer
    
But isn't it also true that it doesnt take O(n^2) for every minor but it sequently decreases because the minors are getting smaller? –  Matthew D May 20 '13 at 20:12

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