Understanding Engineering Mathematics

(やまだぃちぅ) #1

method of solution – we do not have to find the general solution first and then apply the
initial conditions afterwards.


Exercises on 17.4



  1. Evaluate the Laplace transforms of


(i) 3t^2 +cos 2t (ii) 2t+t^3 + 4 tet


  1. Solve the following initial value problem by using the Laplace transform


y′+ 2 y= 3 y( 0 )= 0

Answers



  1. (i)


6
s^3

+

s
s^2 + 4

(ii)

2
s^2

+

6
s^4

+

4
(s− 1 )^2

2.^32 ( 1 −e−^2 t)


17.5 The inverse Laplace transform


Iff(s) ̃ is some function of the Laplace transform variables, then that functionf(t)whose
Laplace transform isf(s) ̃ is called theinverse Laplace transformoff(s) ̃ and is denoted:


f(t)=L−^1 [f(s) ̃ ]

Crudely, we may think ofL−^1 as ‘undoing’ the Laplace transform operation.
Table 17.1 gives a number of important inverse transforms, simply by reading it from
right to left.


Problem 17.7
Find the inverse transforms of 3=s^2 ,1=.s− 4 /,4=.s^2 Y 9 /,.s^2 − 9 /=.s^2 Y
9 /^2 ,.s− 1 /=[.s− 1 /^2 Y1], from Table 17.1. Check your results by taking
their transform.

Many more inverse transforms may be obtained by algebraic and mathematical manipula-
tion on the transform to put it into a suitable form for inversion by already known inverses.
Like the Laplace transform itself, the inverse Laplace transform is a linear operator, and
this alone accounts for a large number of inverses. Also completing the square (66

) can
be useful as for example in


L−^1

[
s− 1
s^2 − 2 s+ 2

]
=L−^1

[
s− 1
(s− 1 )^2 + 1

]

=e−tcost

Exercise on 17.5


Find the inverse Laplace transform in each case and check by taking the Laplace transform
of your results.

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