# Algorithm to find the determinant of a matrix

I have to write an algorithm to find the determinant of a matrix, which is done with the recursive function:

where `A_ij` is the matrix, which appears when you remove the `i`th row and the `j`th column for `A`. When `A` has dimension `n x n`, then the dimension for `A_ij` is `(n-1) x (n-1)`. I'm not allowed to use `Minor[]` or `Det[]`.

How do I write this algorithm?

This is the code I have so far:

``````det1[Mi_ /; Dimensions[Mi][[1]] == Dimensions[Mi][[2]]] :=
Module[{det1},
det1 = Sum[
If[det1 == 1, Break[], (-1)^(1 + j) *Mi[[1, j]]*det1[Drop[Mi, {1}, {j}]]],
{j, 1, Length[Mi]}];
Return[det1 // MatrixForm, Module]
]
``````
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Is this homework by any chance? – Szabolcs Dec 14 '11 at 16:08
What have you tried? – Sjoerd C. de Vries Dec 14 '11 at 16:11
What do you have so far? Where are you getting stuck? – Brett Champion Dec 14 '11 at 16:11
Sorry, i forgot.. Here is my code, until now, but doesn't work: det1[Mi_ /; Dimensions[Mi][[1]] == Dimensions[Mi][[2]]] := Module[{det1}, det1 = Sum[ If[det1 == 1, Break[], (-1)^(1 + j) *Mi[[1, j]]*det1[Drop[Mi, {1}, {j}]]], {j, 1, Length[Mi]}]; Return[det1 // MatrixForm, Module]] – user1098185 Dec 14 '11 at 16:32
@user1098185 Please add the code to the main question. You can use the edit link. – Szabolcs Dec 14 '11 at 16:36

1. `MatrixForm` is used for formatting (display), but a MatrixForm-wrapped matrix can't be used in calculations. You simply need to remove it.

2. Think about your stopping condition for the recursion: the determinant of a 1*1 matrix is just the single element of the matrix. Rewrite the sum and `If` based on this. If the matrix is of size 1, return its element (it's impossible to `Break[]` out of a recursion).

3. Don't use a local variable with the same name as your function: this masks the global function and makes it impossible to call recursively.

4. Finally, this doesn't break the function, but an explicit `Return` is not necessary. The last value of a `CompoundExpression` is simply returned.

To summarize, `det[m_] := If[Length[m] == 1, m[[1,1]], (Laplace expansion here)]`. An alternative is to use pattern matching to identify size-1 matrices:

``````Clear[det]
det[{{x_}}] := x
det[m_] := (Laplace expansion)
``````
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How does Laplace's formula involve in this? im confused, sorry – user1098185 Dec 14 '11 at 17:20
I mean the same formula you posted: en.wikipedia.org/wiki/Laplace_expansion – Szabolcs Dec 14 '11 at 17:22

``````Clear[det];
det[{{x_}}] := x;
det[a_ /; MatrixQ[a] && SameQ @@ Dimensions[a]] :=
Sum[(-1)^(1 + i) a[[1, i]] det[Drop[a, {1}, {i}]], {i, 1, Length[a]}];
det::gofish = "Unable to handle this type of input: ``";
det[a___] := (Message[det::gofish, HoldForm[det][a]]; \$Failed)
``````

E.g., this:

``````In[]:=

m = {{a, b, c}, {c, d, e}, {f, g, h}};
Det[m] === Expand[det[m]]
``````

gives:

``````Out[]=

True
``````
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Thank you, it was a big help – user1098185 Dec 15 '11 at 18:35