Eigenvalue vs Eigentime - What's the difference?

As nouns the difference between eigenvalue and eigentime

is that eigenvalue is (linear algebra) a scalar,

\lambda\!

, such that there exists a vector

x

(the corresponding eigenvector) for which the image of

x

under a given linear operator

\rm a\!

is equal to the image of

x

under multiplication by

\lambda

; ie

{\rm a} x = \lambda x\!

while eigentime is (physics) a time whose value is that of a corresponding eigenvalue.

(en noun)

(linear algebra) A scalar,

\lambda\!

, such that there exists a vector

x

(the corresponding eigenvector) for which the image of

x

under a given linear operator

\rm A\!

is equal to the image of

x

under multiplication by

\lambda

; i.e.

{\rm A} x = \lambda x\!

''The eigenvalues

\lambda\!

of a square transformation matrix

\rm M\!

may be found by solving

\det({\rm M} - \lambda {\rm I}) = 0\!

When unqualified, as in the above example, eigenvalue conventionally refers to a right eigenvalue, characterised by

{\rm M} x = \lambda x\!

for some right eigenvector

x\!

. Left eigenvalues, charactarised by

y {\rm M} = y \lambda\!

also exist with associated left eigenvectors

y\!

. For commutative operators, the left eigenvalues and right eigenvalues will be the same, and are referred to as eigenvalues with no qualifier.

* characteristic root * characteristic value * eigenroot * latent value * proper value