Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

10.1 DIFFERENTIATION OF VECTORS


a(u)

a(u+∆u)

∆a=a(u+∆u)−a(u)

Figure 10.1 A small change in a vectora(u) resulting from a small change
inu.

assuming that the limit exists, in which casea(u) is said to be differentiable at


that point. Note thatda/duis also a vector, which is not, in general, parallel to


a(u). In Cartesian coordinates, the derivative of the vectora(u)=axi+ayj+azk


is given by


da
du

=

dax
du

i+

day
du

j+

daz
du

k.

Perhaps the simplest application of the above is to finding the velocity and

acceleration of a particle in classical mechanics. If the time-dependent position


vector of the particle with respect to the origin in Cartesian coordinates is given


byr(t)=x(t)i+y(t)j+z(t)kthen the velocity of the particle is given by the vector


v(t)=

dr
dt

=

dx
dt

i+

dy
dt

j+

dz
dt

k.

The direction of the velocity vector is along the tangent to the pathr(t)atthe


instantaneous position of the particle, and its magnitude|v(t)|is equal to the


speed of the particle. The acceleration of the particle is given in a similar manner


by


a(t)=

dv
dt

=

d^2 x
dt^2

i+

d^2 y
dt^2

j+

d^2 z
dt^2

k.

The position vector of a particle at timetin Cartesian coordinates is given byr(t)=
2 t^2 i+(3t−2)j+(3t^2 −1)k. Find the speed of the particle att=1and the component of
its acceleration in the directions=i+2j+k.

The velocity and acceleration of the particle are given by


v(t)=

dr
dt

=4ti+3j+6tk,

a(t)=

dv
dt

=4i+6k.
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