Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

26.21 ABSOLUTE DERIVATIVES ALONG CURVES


this is the analogue of the expression in Cartesian coordinates discussed in


section 26.8.


26.21 Absolute derivatives along curves

In section 26.19 we discussed how to differentiate a general tensor with respect


to the coordinates and introduced the covariant derivative. In this section we


consider the slightly different problem of calculating the derivative of a tensor


along a curver(t) that is parameterised by some variablet.


Let us begin by considering the derivative of a vectorvalong the curve. If we

introduce an arbitrary coordinate systemuiwith basis vectorsei,i=1, 2 ,3, then


we may writev=vieiand so obtain


dv
dt

=

dvi
dt

ei+vi

dei
dt

=

dvi
dt

ei+vi

∂ei
∂uk

duk
dt

;

here the chain rule has been used to rewrite the last term on the right-hand side.


Using (26.75) to write the derivatives of the basis vectors in terms of Christoffel


symbols, we obtain


dv
dt

=

dvi
dt

ei+Γjikvi

duk
dt

ej.

Interchanging the dummy indicesiandjin the last term, we may factor out the


basis vector and find


dv
dt

=

(
dvi
dt

+Γijkvj

duk
dt

)
ei.

The term in parentheses is called theabsolute(orintrinsic) derivative of the


componentsvialong the curver(t)and is usually denoted by


δvi
δt


dvi
dt

+Γijkvj

duk
dt

=vi;k

duk
dt

.

With this notation, we may write


dv
dt

=

δvi
δt

ei=vi;k

duk
dt

ei. (26.99)

Using the same method, the absolute derivative of the covariant components

viof a vector is given by


δvi
δt

≡vi;k

duk
dt

.

Similarly, the absolute derivatives of the contravariant, mixed and covariant

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