Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

LINE, SURFACE AND VOLUME INTEGRALS


integral in (11.1). If a loop of wireCcarrying a currentIis placed in a magnetic


fieldBthen the forcedFon a small lengthdrof the wire is given bydF=Idr×B,


and so the total (vector) force on the loop is


F=I


C

dr×B.

11.1.3 Line integrals with respect to a scalar

In addition to those listed in (11.1), we can form other types of line integral,


which depend on a particular curveCbut for which we integrate with respect


to a scalardu, rather than the vector differentialdr. This distinction is somewhat


arbitrary, however, since we can always rewrite line integrals containing the vector


differentialdras a line integral with respect to some scalar parameter. If the path


Calong which the integral is taken is described parametrically byr(u)then


dr=

dr
du

du,

and the second type of line integral in (11.1), for example, can be written as


C

a·dr=


C


dr
du

du.

A similar procedure can be followed for the other types of line integral in (11.1).


Commonly occurring special cases of line integrals with respect to a scalar are

C

φds,


C

ads,

wheresis the arc length along the curveC. We can always representCparamet-


rically byr(u), and from section 10.3 we have


ds=


dr
du

·

dr
du

du.

The line integrals can therefore be expressed entirely in terms of the parameteru


and thence evaluated.


Evaluate the line integralI=


C(x−y)

(^2) ds,whereCis the semicircle of radiusarunning
fromA=(a,0)toB=(−a,0)and for whichy≥ 0.
The semicircular path fromAtoBcan be described in terms of the azimuthal angleφ
(measured from thex-axis) by
r(φ)=acosφi+asinφj,
whereφruns from 0 toπ. Therefore the element of arc length is given, from section 10.3,
by
ds=



dr

·


dr

dφ=a(cos^2 φ+sin^2 φ)dφ=adφ.
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