Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

10.1 DIFFERENTIATION OF VECTORS


in terms ofiandj. From figure 10.2, we see that


ˆeρ=cosφi+sinφj,

eˆφ=−sinφi+cosφj.

Sinceiandjare constant vectors, we find that the derivatives of the basis vectors


ˆeρandˆeφwith respect totare given by


dˆeρ
dt

=−sinφ


dt

i+cosφ


dt

j=φ ̇eˆφ, (10.2)

dˆeφ
dt

=−cosφ


dt

i−sinφ


dt

j=−φ ̇eˆρ, (10.3)

where the overdot is the conventional notation for differentiation with respect to


time.


The position vector of a particle in plane polar coordinates isr(t)=ρ(t)eˆρ.Findexpres-
sions for the velocity and acceleration of the particle in these coordinates.

Using result (10.4) below, the velocity of the particle is given by


v(t)= ̇r(t)=ρ ̇eˆρ+ρ ̇eˆρ= ̇ρeˆρ+ρφ ̇eˆφ,

where we have used (10.2). In a similar way its acceleration is given by


a(t)=

d
dt

( ̇ρeˆρ+ρφ ̇ˆeφ)

= ̈ρeˆρ+ρ ̇e ̇ˆρ+ρ ̇φ ̇eˆφ+ρ ̈φˆeφ+ ̇ρφ ̇ˆeφ
= ̈ρeˆρ+ ̇ρ(φ ̇ˆeφ)+ρ ̇φ(− ̇φeˆρ)+ρφ ̈ˆeφ+ ̇ρφ ̇ˆeφ
=( ̈ρ−ρφ ̇^2 )ˆeρ+(ρ ̈φ+2ρ ̇ ̇φ)ˆeφ.

Here we have used (10.2) and (10.3).


10.1.1 Differentiation of composite vector expressions

In composite vector expressions each of the vectors or scalars involved may be


a function of some scalar variableu, as we have seen. The derivatives of such


expressions are easily found using the definition (10.1) and the rules of ordinary


differential calculus. They may be summarised by the following, in which we


assume thataandbare differentiable vector functions of a scalaruand thatφ


is a differentiable scalar function ofu:


d
du

(φa)=φ

da
du

+


du

a, (10.4)

d
du

(a·b)=a·

db
du

+

da
du

·b, (10.5)

d
du

(a×b)=a×

db
du

+

da
du

×b. (10.6)
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