Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

11


Line, surface and volume integrals


In the previous chapter we encountered continuously varying scalar and vector


fields and discussed the action of various differential operators on them. In


addition to these differential operations, the need often arises to consider the


integration of field quantities along lines, over surfaces and throughout volumes.


In general the integrand may be scalar or vector in nature, but the evaluation


of such integrals involves their reduction to one or more scalar integrals, which


are then evaluated. In the case of surface and volume integrals this requires the


evaluation of double and triple integrals (see chapter 6).


11.1 Line integrals

In this section we discusslineorpath integrals, in which some quantity related


to the field is integrated between two given points in space,AandB, along a


prescribed curveCthat joins them. In general, we may encounter line integrals


of the forms ∫


C

φdr,


C

a·dr,


C

a×dr, (11.1)

whereφis a scalar field andais a vector field. The three integrals themselves are


respectively vector, scalar and vector in nature. As we will see below, in physical


applications line integrals of the second type are by far the most common.


The formal definition of a line integral closely follows that of ordinary integrals

and can be considered as the limit of a sum. We may divide the pathCjoining


the pointsAandBintoNsmall line elements ∆rp,p=1,...,N.If(xp,yp,zp)is


any point on the line element ∆rpthen the second type of line integral in (11.1),


for example, is defined as


C

a·dr= lim
N→∞

∑N

p=1

a(xp,yp,zp)·∆rp,

where it is assumed that all|∆rp|→0asN→∞.

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