Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

26.23 EXERCISES


Writing out the covariant derivative, we obtain
(
dti
ds


+Γijktj

duk
ds

)
ei= 0.

But, sincetj=duj/ds, it follows that the equation satisfied by a geodesic is


d^2 ui
ds^2

+Γijk

duj
ds

duk
ds

=0. (26.101)

Find the equations satisfied by a geodesic (straight line) in cylindrical polar coordinates.

From (26.83), the only non-zero Christoffel symbols are Γ^122 =−ρand Γ^212 =Γ^221 =1/ρ.
Thus the required geodesic equations are


d^2 u^1
ds^2

+Γ^122


du^2
ds

du^2
ds

=0 ⇒


d^2 ρ
ds^2

−ρ

(



ds

) 2


=0,


d^2 u^2
ds^2

+2Γ^212


du^1
ds

du^2
ds

=0 ⇒


d^2 φ
ds^2

+


2


ρ


ds


ds

=0,


d^2 u^3
ds^2

=0 ⇒


d^2 z
ds^2

=0.


26.23 Exercises

26.1 Use the basic definition of a Cartesian tensor to show the following.


(a) That for any general, but fixed,φ,
(u 1 ,u 2 )=(x 1 cosφ−x 2 sinφ, x 1 sinφ+x 2 cosφ)
are the components of a first-order tensor in two dimensions.
(b) That
(
x^22 x 1 x 2
x 1 x 2 x^21

)


is not a tensor of order 2. To establish that a single element does not
transform correctly is sufficient.

26.2 The components of two vectors,AandB, and a second-order tensor,T, are given
in one coordinate system by


A=




1


0


0



, B=




0


1


0



, T=




2



√^30


340


002



.


In a second coordinate system, obtained from the first by rotation, the components
ofAandBare

A′=


1


2





3


0


1



, B′=^1


2




− 1


√^0


3



.


Find the components ofTin this new coordinate system and hence evaluate,
with a minimum of calculation,
TijTji,TkiTjkTij,TikTmnTniTkm.
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