Basic Engineering Mathematics, Fifth Edition

(Amelia) #1

320 Basic Engineering Mathematics


Now try the following Practice Exercise

PracticeExercise 134 Differentiation of
sine and cosine functions (answers on
page 354)


  1. Differentiatewithrespect tox:(a)y=4sin3x
    (b)y=2cos6x.

  2. Givenf(θ )=2sin3θ−5cos2θ,findf′(θ ).

  3. Find the gradient of the curvey=2cos


1
2

xat

x=

π
2


  1. Determine the gradient of the curve


y=3sin2xatx=

π
3


  1. An alternating current is given by
    i=5sin100tamperes, wheretis the time
    in seconds. Determine the rate of change of
    current


(
i.e.

di
dt

)
whent= 0 .01 seconds.


  1. v=50sin40tvolts represents an alternating
    voltage,v,wheretis the time in seconds. At
    a time of 20× 10 −^3 seconds, find the rate of
    change of voltage


(
i.e.

dv
dt

)


  1. If f(t)=3sin( 4 t+ 0. 12 )−2cos( 3 t− 0. 72 ),
    determinef′(t).


34.7 Differentiation ofeaxand lnax

A graph ofy=exis shown in Figure 34.7(a). The gra-
dient of the curve at any point is given by

dy
dx

and is
continually changing. By drawing tangents to the curve
at many points on the curve and measuring the gradient
ofthetangents,valuesof

dy
dx

forcorrespondingvaluesof
xmay be obtained. These values are shown graphically
in Figure 34.7(b).
The graph of

dy
dx

againstxis identical to the original
graph ofy=ex. It follows that

ify=ex,then

dy
dx

=ex

It may also be shown that

ify=eax,then

dy
dx

=aeax

3

y 5 ex

1 2 x

5

10

15

20

y

23022 21
(a)

3

dy
dx^5 e

x

dy
dx

1 2 x

5

10

15

20

y

23022 21
(b)

Figure 34.7

Therefore,

ify= 2 e^6 x,then

dy
dx

=( 2 )( 6 e^6 x)= 12 e^6 x

A graph ofy=lnxis shown in Figure 34.8(a). The gra-
dient of the curve at any point is given by

dy
dx

and is
continually changing. By drawing tangents to the curve
at many points on the curve and measuring the gradient
of the tangents, values of

dy
dx

for corresponding values
ofxmay be obtained. These values are shown graphi-
cally in Figure 34.8(b).
The graph of

dy
dx

againstxis the graph of

dy
dx

=

1
x
It follows that

ify=lnx,then

dy
dx

=

1
x
It may also be shown that

ify=lnax,then

dy
dx

=

1
x
(Note that, in the latter expression, the constantadoes
not appear in the

dy
dx

term.) Thus,

ify=ln4x,then

dy
dx

=

1
x
Free download pdf