Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

TENSORS


where the elementsLijare given by


L=



cosθ sinθ 0
−sinθ cosθ 0
001


.

Thus (26.68) and (26.70) agree with our earlier definition in the special case of a


rigid rotation of Cartesian axes.


Following on from (26.68) and (26.70), we proceed in a similar way to de-

fine general tensors of higher rank. For example, the contravariant, mixed and


covariant components, respectively, of a second-order tensor must transform as


follows:


contravariant components, T′

ij
=

∂u′i
∂uk

∂u′j
∂ul

Tkl;

mixed components, T′

i
j=

∂u′i
∂uk

∂ul
∂u′j

Tkl;

covariant components, T′ij=

∂uk
∂u′i

∂ul
∂u′j

Tkl.

It is important to remember that these quantities form the components of the

sametensorTbut refer to different tensor bases made up from the basis vectors


of the different coordinate systems. For example, in terms of the contravariant


components we may write


T=Tijei⊗ej=T′

ij
e′i⊗e′j.

We can clearly go on to define tensors of higher order, with arbitrary numbers

of covariant (subscript) and contravariant (superscript) indices, by demanding


that their components transform as follows:


T′ij···klm···n=

∂u′i
∂ua

∂u′j
∂ub

···

∂u′k
∂uc

∂ud
∂u′l

∂ue
∂u′m

···

∂uf
∂u′n

Tab···cde···f. (26.71)

Using the revised summation convention described in section 26.14, the algebra

of general tensors is completely analogous to that of the Cartesian tensors


discussed earlier. For example, as with Cartesian coordinates, the Kronecker


delta is a tensor provided it is written as the mixed tensorδjisince


δ′

i
j=

∂u′i
∂uk

∂ul
∂u′j

δkl=

∂u′i
∂uk

∂uk
∂u′j

=

∂u′i
∂u′j

=δji,

where we have used the chain rule to justify the third equality. This also shows


thatδij is isotropic. As discussed at the end of section 26.15, theδjican be


considered as the mixed components of the metric tensorg.

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