Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

10


Vector calculus


In chapter 7 we discussed the algebra of vectors, and in chapter 8 we considered


how to transform one vector into another using a linear operator. In this chapter


and the next we discuss the calculus of vectors, i.e. the differentiation and


integration both of vectors describing particular bodies, such as the velocity of


a particle, and of vector fields, in which a vector is defined as a function of the


coordinates throughout some volume (one-, two- or three-dimensional). Since the


aim of this chapter is to develop methods for handling multi-dimensional physical


situations, we will assume throughout that the functions with which we have to


deal have sufficiently amenable mathematical properties, in particular that they


are continuous and differentiable.


10.1 Differentiation of vectors

Letusconsideravectorathat is a function of a scalar variableu.Bythis


we mean that with each value ofuwe associate a vectora(u). For example, in


Cartesian coordinatesa(u)=ax(u)i+ay(u)j+az(u)k,whereax(u),ay(u)andaz(u)


are scalar functions ofuand are the components of the vectora(u)inthex-,y-


andz- directions respectively. We note that ifa(u) is continuous at some point


u=u 0 then this implies that each of the Cartesian componentsax(u),ay(u)and


az(u) is also continuous there.


Let us consider the derivative of the vector functiona(u)withrespecttou.

The derivative of a vector function is defined in a similar manner to the ordinary


derivative of a scalar functionf(x) given in chapter 2. The small change in


the vectora(u) resulting from a small change ∆uin the value ofuis given by


∆a=a(u+∆u)−a(u) (see figure 10.1). The derivative ofa(u) with respect touis


defined to be


da
du

= lim
∆u→ 0

a(u+∆u)−a(u)
∆u

, (10.1)
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