# it is possible determinant of matrix(256*256) be infinite

i have (256*1) vectors of feature come from (16*16) of gray images. number of vectors is 550 when i compute Sample covariance of this vectors and compute covariance matrix determinant answer is inf

it is possible determinant of finite matrix with finite range (0:255) value be infinite or i mistake some where?

in fact i want classification with bayesian estimation , my distribution is gaussian and when i compute determinant be inf and ultimate Answer(likelihood) is zero .

some part of my code:

Mean =  mean(dataSet,2);
MeanMatrix = Mean*ones(1,NoC);
Xc = double(dataSet)-MeanMatrix; % transform data to the origine
Sigma = (1/NoC) *Xc*Xc'; % calculate sample covariance matrix
Parameters(i).M = Mean';
Parameters(i).C = Sigma;

likelihoods(i) = (1/(2*pi*sqrt(det(params(i).C)))) * (exp(-0.5 * (double(X)-params(i).M)' * inv(params(i).C) * (double(X)-params(i).M)));


variable i show my classes; variable X show my feature vector;

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Maybe you have overshot the floating point range? 256**256 is pretty big a number, and there are 256! of those. –  Jan Dvorak Jan 28 '14 at 14:27

Can the determinant of such matrix be infinite? No it cannot.

Can it evaluate as infinite? Yes definitely.

Here is an example of a matrix with a finite amount of elements, that are not too big, yet the determinant will rarely evaluate as a finite number:

det(rand(255)*255)

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Here is another: det(5*eye(500)) –  Matt J Jan 28 '14 at 15:29
perhaps matlab because the value is big and large estimate with inf is not? –  ali kiani Jan 28 '14 at 18:11
@alikiani Indeed, too large values will be evaluated as Inf. You should compare your expected result (and any intermediate results) with realmax to see whether they are too large. –  Dennis Jaheruddin Jan 29 '14 at 8:46

In your case, probably what is happening is that you have too few datapoints to produce a full-rank covariance matrix.

For instance, if you have N examples, each with dimension d, and N<d, then your d x d covariance matrix will not be full rank and will have a determinant of zero.

In this case, a matrix inverse (precision matrix) does not exist. However, attempting to compute the determinant of the inverse (by taking 1/|X'*X|=1/0 -> \infty) will produce an infinite value.

One way to get around this problem is to set the covariance to X'*X+eps*eye(d), where eps is a small value. This technique corresponds to placing a weak prior distribution on elements of X.

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no it is not possible. it may be singular but taking elements a large value has will have a determinant value.

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