Second and higher derivatives may be obtained in the obvious way by repeated differ-
entiation. Thus, for example:
d^2 f(t)
dt^2
=
d^2 f 1
dt^2
i+
d^2 f 2
dt^2
j+
d^2 f 3
dt^2
k
Problem 11.12
Evaluate
d^2 f
dt^2
and
d^3 f
dt^3
for f=tiYe−tjYcostk
df
dt
=i−e−tj−sintk
d^2 f
dt^2
=e−t−costk
d^3 f
dt^3
=−e−tj+sintk
When we introduced ordinary differentiation we referred it to the gradient or slope of a
curve. We can do the same for differentiation of vector functions – but it is now a little more
complicated. It is perhaps best to appeal to the example considered earlier of a vector function
r(t)describing the position of a particle at timet. Thus, letr(t)be the position vector of a
moving particleP.Astvaries the particle moves along a curve in space – see Figure 11.19.
O
P
P′
Figure 11.19Definition of derivative of a vector.
Now for two points on the curver(t),r(t+h), close to each other we have:
r(t+h)−r(t)
h
=
−→
OP′−
−→
OP
h
=
−→
PP′
h
Ash→0,P′→Pand the vector
−→
PP′becomes tangential to the curve. Also the magni-
tude
−∣−→
∣PP′
∣
∣
h
is the average speed of the particle over the intervalPP′and so ash→0this
becomes the velocity of the particle. Thus:
lim
h→ 0
(
r(t+h)−r(t)
h
)
=
dr
dt