How can I derive inverse of the matrix with infinite determinant?
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Hi guys, there is a matrix A which has finite dimension and finite-valued elements.
However, because of its large size and values, the determinant of A becomes infinite on MATLAB.
load("myMatrix.mat","A")
size(A)
max(max(abs(A)))
det(A)
Therefore, it cannot compute the inverse of the matrix precisely.
B = inv(A);
isdiag(A*B)
Is there way to compute the inverse of the matrix A?
Cheers,
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Réponses (4)
Bruno Luong
le 17 Nov 2022
Modifié(e) : Bruno Luong
le 18 Nov 2022
Welcome to the world of numerical calculation. Every conclusion you made is wrong.
"det(A) = Inf Therefore, it cannot compute the inverse of the matrix precisely. ".
Wrong
A=eye(200)*1024;
det(A)
B=inv(A);
all(A*B == eye(size(A)), 'all') % A*B is exatly I, despite det(A) is Inf due to overflow
Check B is inverse of A using isdiag(A*B).
This is a bad numerically criteria as showed in the false negative answer example
A=[1 2; 3 4]
B = inv(A)
AB = A*B;
isdiag(AB) % Suppose to be TRUE
AB(2,1) % Suppose to be 0, but not exactly
3 commentaires
Bruno Luong
le 17 Nov 2022
Modifié(e) : Bruno Luong
le 17 Nov 2022
The funny thing is the inconsistency of linear algebra - mostly det - in floating point world.
The matrix is numerical singular, so the determinant should be 0, yet it is Inf.
Bruno Luong
le 17 Nov 2022
Déplacé(e) : Bruno Luong
le 17 Nov 2022
"Is there way to compute the inverse of the matrix A?"
No.
The sum of all columns of your matrix A is numerically 0, therefore your matrix is not invertible.
2 commentaires
Steven Lord
le 17 Nov 2022
The first of Cleve's Golden Rules of computation applies here. "The hardest things to compute are things that do not exist."
Bruno Luong
le 17 Nov 2022
Hmm read these two rules from Cleve I wonder this: things that do not exist are they unique?
It sounds like a non-sense question, but why it is non-sense?
If it does make sense I have no preference for the answer.
Walter Roberson
le 17 Nov 2022
Modifié(e) : Walter Roberson
le 18 Nov 2022
In theory if you have the symbolic toolbox, you could
digits(16);
sA = sym(A, 'd');
digits(32);
Ainv = inv(sA);
... But test it with a much smaller matrix first, as it might take very very long.
5 commentaires
Bruno Luong
le 18 Nov 2022
Modifié(e) : Bruno Luong
le 18 Nov 2022
OK I make change accordingly to 'd' flag in my test code, and as you can see the symbolic is no bettrer than numerical method with "\", at least in this toy example.
Even if it use minor formula, there are a lot of cancellation going on in determinant so the summation order and tree (parenthesis) matter. The symbolic probably does the sumation in the implicit order of the implementation as it progres and no care about cancellation.
I'm not sure if the symbolic solution is any better than numerical method for precision point of view, let alone the computation time that goes as factorial of the dimesion.
Walter Roberson
le 18 Nov 2022
The point about this approach was that it should avoid the intermediate inf
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