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det
determinant of a square matrix
Syntax
d = det(X) [e,m] = det(X)
Arguments
- X
- square matrix of real or complex numbers, polynomials, or rationals. Sparse-encoded matrices accepted.
- d
- Scalar of the
X
's type: the determinant ofX
. IfX
is sparse-encoded,d
is dense. - m
- real or complex number: the determinant base 10 mantissa, with
abs(m) ∈ [1,10)
. Not supported forX
polynomial or rational. - e
- integer: the determinant base 10 exponent, such that
d = m * 10e
. Not supported forX
polynomial or rational.
Description
d = det(X) yields the determinant of the matrix
X
.
For a polynomial or rational matrix, d=det(X)
uses determ(..)
whose algorithm is based on the FFT.
d=detr(X)
can be alternatively used, based on the Leverrier algorithm.
Both methods yield equivalent results. For rational matrices, turning off simp_mode(%f)
might be required to get identical results.
[e, m] = det(X) can be used only for a matrix of numbers.
This syntax allows to overcome computation's underflow or overflow, when abs(d)
is smaller than
number_properties("tiny")
≈ 2.23 10-308 or
bigger than number_properties("huge")
≈ 1.80 10308.
For denses matrices, det(..)
is based on the Lapack routines
DGETRF for real matrices and ZGETRF for the complex case.
For sparse matrices, the determinant is obtained from LU factorization thanks to the umfpack library.
Examples
A = rand(3,3)*5; det(A) [e, m] = det(A) // Matrix of complex numbers: // A = grand(3,3,"uin",0,10) + grand(3,3,"uin",0,10)*%i A = [3+%i, 9+%i*3, 9+%i ; 8+%i*8, 4+%i*3, 7+%i*7 ; 4, 6+%i*2, 6+%i*9] det(A) [e, m] = det(A) abs(m) // in [1, 10)
--> A = rand(3,3)*5; --> det(A) ans = -10.805163 --> [e, m] = det(A) e = 1. m = -1.0805163 --> // Matrix of complex numbers: --> A = [3+%i, 9+%i*3, 9+%i ; 8+%i*8, 4+%i*3, 7+%i*7 ; 4, 6+%i*2, 6+%i*9] A = 3. + i 9. + 3.i 9. + i 8. + 8.i 4. + 3.i 7. + 7.i 4. + 0.i 6. + 2.i 6. + 9.i --> det(A) ans = 745. - 225.i --> [e, m] = det(A) e = 2. m = 7.45 - 2.25i --> abs(m) // in [1, 10) ans = 7.7823518
Very big or small determinants: underflow and overflow handling:
// Very big determinant: n = 1000; A = rand(n, n); det(A) [e, m] = det(A) // Very small determinant (of a sparse-encoded matrix): A = (triu(sprand(n,n,1)) + diag(rand(1,n)))/1.5; det(A) prod(diag(A)) [e, m] = det(A) A = A/2; det(A) [e, m] = det(A)
--> // Very big determinant: --> A = rand(n, n); --> det(A) ans = -Inf --> [e, m] = det(A) // -3.1199e743 e = 743. m = -3.1198687 --> // Very small determinant (of a sparse-encoded matrix): --> n = 1000; --> A = (triu(sprand(n,n,1)) + diag(rand(1,n)))/1.5; --> det(A) ans = 5.21D-236 --> prod(diag(A)) ans = 5.21D-236 --> [e, m] = det(A) e = -236. m = 5.2119757 --> A = A/2; --> det(A) ans = 0. --> [e, m] = det(A) e = -537. m = 4.8641473
Determinant of a polynomial matrix:
s = %s; det([s, 1+s ; 2-s, s^2]) w = ssrand(2,2,4); roots(det(systmat(w))),trzeros(w) //zeros of linear system
--> det([s, 1+s ; 2-s, s^2]) ans = -2 -s +s² +s³ --> w = ssrand(2,2,4); --> roots(det(systmat(w))),trzeros(w) ans = -3.1907522 + 0.i 2.3596502 + 0.i ans = 2.3596502 + 0.i -3.1907522 + 0.i
See also
History
Version | Description |
6.1.1 | [e,m]=det(X) syntax extended to sparse matrices. |
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