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I am working on an algorithm which calculates the determinant of any n*n matrix, here is my code:

 Laplace[matrix_List] := Module[{a = matrix, newmatrix, result = 0},
     If [Length[a] == 1, result = Total[Total[a]],
         For [i = 1, i <= Length[a], i++,
              newmatrix = Drop[a, {i}, {1}];
              result = result + (-1)^(i + 1) *
                       Total[Total[Take[a, {i}, {1}]]]*
                       Laplace[newmatrix]; 
         ]
     ]; result]

It works recursively, it works for a 2*2 matrix(I have checked with Det[]), but it doesn't work for any matrix of higher degree than 2!

I would like to solve this solution myself - I want to implement this myself, rather than simply using Det - but I would appreciate it if someone could explain what is wrong with the recursion here?

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Localize 'i'. Else it messes up because it changes in recursive calls. Also it does not bode well for a matrix such as {{i, j}, {k, l}}. Could also try this variant: Laplace[mat : {{a_}} /; MatrixQ[mat]] := a Laplace[mat_?MatrixQ] /; Length[mat] == Length[mat[[1]]] := Laplace[mat] = Sum[(-1)^j*mat[[j, 1]]*Laplace[Drop[mat, {j}, {1}]], {j, Length[mat]}] –  Daniel Lichtblau Jan 28 '12 at 21:19
    
Take a look at this answer : stackoverflow.com/questions/8507654/… –  Artes Jan 29 '12 at 13:00
    
Why not use Det[]? –  Jack Maney Jun 12 '12 at 20:40
    
@Jack there's a deleted answer on which the OP comments that they are deliberately trying to implement the determinant themselves, rather than use Det. I'll update the question to include. –  AakashM Jun 12 '12 at 21:53
    
@John: You may wish to use something other than Laplace for your function name. That's the name of a built in symbol. Standard practice is to typically use lower case names. –  Mike Bantegui Jun 12 '12 at 22:01
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1 Answer

You should not calculate the determinant in a recursive way, it takes a lot of time. The simplest method is to take the first column and see if there is an element different from 0. If there isn't then the determinant is equal to 0. Otherwise take that element and for every line in the matrix different from that of the chosen element substract the line of the chosen element multiplied with the symetric of the first element of the current line. That substraction should leave you with a line which has 0 as its first element. Then you can eliminate the first column and the line of the chosen element and multiply the n-1 order determinant with (-1)^(line_index+column_index)*chosen_element.

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