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This is the approach John Carmack uses to calculate the determinant of a 4x4 matrix. From my investigations i have determined that it starts out like the laplace expansion theorem but then goes on to calculate 3x3 determinants which doesn't seem to agree with any papers i've read.

	// 2x2 sub-determinants
	float det2_01_01 = mat[0][0] * mat[1][1] - mat[0][1] * mat[1][0];
	float det2_01_02 = mat[0][0] * mat[1][2] - mat[0][2] * mat[1][0];
	float det2_01_03 = mat[0][0] * mat[1][3] - mat[0][3] * mat[1][0];
	float det2_01_12 = mat[0][1] * mat[1][2] - mat[0][2] * mat[1][1];
	float det2_01_13 = mat[0][1] * mat[1][3] - mat[0][3] * mat[1][1];
	float det2_01_23 = mat[0][2] * mat[1][3] - mat[0][3] * mat[1][2];

	// 3x3 sub-determinants
	float det3_201_012 = mat[2][0] * det2_01_12 - mat[2][1] * det2_01_02 + mat[2][2] * det2_01_01;
	float det3_201_013 = mat[2][0] * det2_01_13 - mat[2][1] * det2_01_03 + mat[2][3] * det2_01_01;
	float det3_201_023 = mat[2][0] * det2_01_23 - mat[2][2] * det2_01_03 + mat[2][3] * det2_01_02;
	float det3_201_123 = mat[2][1] * det2_01_23 - mat[2][2] * det2_01_13 + mat[2][3] * det2_01_12;

	return ( - det3_201_123 * mat[3][0] + det3_201_023 * mat[3][1] - det3_201_013 * mat[3][2] + det3_201_012 * mat[3][3] );

Could someone explain to me how this approach works or point me to a good write up which uses the same approach?

If it matters this matrix is row major.

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up vote 5 down vote accepted

It seems to be the method that involves using minors. The mathematical aspect can be found on wikipedia at

Basically you reduce the matrix to something smaller and easier to compute, and sum those results up (it involves some (-1) factors which should be described on the page i linked to).

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yep - that's it.. Simple unrolled laplace expansion. – Nils Pipenbrinck Aug 14 '09 at 8:36
If you want more info, you should also search for "cofactor expansion" – Martijn Aug 24 '09 at 12:17
and probably prone to roundoff errors. Pivoting usually uses some logic to avoid substracting potentially close numbers by selecting (for instance) the largest number as pivot. – Alexandre C. Jul 2 '10 at 10:29

He uses the standard formula where you can compute, in pseudocode,

det(M) = sum(M[0, i] * det(M.minor[0, i]) * (-1)^i)

Here minor[0, i] is a matrix you obtain by crossing out 0-th row and i-th column from your original matrix and (-1)*i stands for i-th power of -1.

The same (up to an overall sign) formula will work if you take a different row or if you make a loop over a column. If you think about how det is defined, it's pretty self-explanatory. Note how for 2-matrix this becomes:

det(M) = M[0, 0] * M[1, 1] * (+1) + M[0, 1] * M[1, 0] * (-1)

or, by row 1 rather then 0,

-det(M) = M[1, 0] * M[0, 1] * (+1) + M[1, 1] * M[0, 0] * (-1)

– you should recognize the standard formula for determinant of 2x2 matrix.

Similarly, for a 3-matrix composed as N = [[a, b, c], [d, e, f], [g, h, i]] this leads to the formula

det(N) = a * det([[e, f], [h, i]]) - b * det([[d, f], [g, i]]) + c * det([[d, e], [g, h]])

which of course becomes the textbook formula

a*e*i + b*f*g +  c*d*h - c*e*g - a*f*h - b*d*i

once you expand each of 2x2 determinants.

Now if you take a 4-matrix X, you will see that to compute det(X) you need to compute determinants of 4 minors, each minor being a 3x3 matrix; but you can also expand them further so you'll have the determinants of 6 2x2 matrices with some coefficients. You should really try it yourself similarly to what is above for 3x3 matrices.

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Yep I understand it as far as the 2x2 matrix determinants are concerned but i can't see where the 3x3's are needed? – Adam Naylor Aug 14 '09 at 15:55
To answer your narrow question, the formula I quoted says: (1) compute det for some 3x3 matrices; (2) add them with coefficients. – ilya n. Aug 14 '09 at 18:55
The method is to reduce an NxN determinant calculation to the calculation of N-1xN-1 determinants, and continue until you're down to 2x2. Therefore, the 4x4 reduces to some 3x3s, which reduce to more 2x2s. – David Thornley Aug 14 '09 at 18:58

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