HP 48gII User Manual

Page 16-17

Another important result, known as the second shift theorem for a shift to the
right, is that L

-1

{e

–as

⋅F(s)}=f(t-a)⋅H(t-a), with F(s) = L{f(t)}.

In the calculator the Heaviside step function H(t) is simply referred to as ‘1’.
To check the transform in the calculator use:

1 ` LAP. The result is ‘1/X’,

i.e., L{1} = 1/s. Similarly, ‘U0’

` LAP , produces the result ‘U0/X’, i.e.,

L{U

0

} = U

0

/s.

You can obtain Dirac’s delta function in the calculator by using:

1` ILAP

The result is

‘Delta(X)’.

This result is simply symbolic, i.e., you cannot find a numerical value for, say
‘

Delta(5)

’.

This result can be defined the Laplace transform for Dirac’s delta function,
because from L

-1

{1.0}=

δ(t), it follows that L{δ(t)} = 1.0

Also, using the shift theorem for a shift to the right, L{f(t-a)}=e

–as

⋅L{f(t)} =

e

–as

⋅F(s), we can write L{δ(t-k)}=e

–ks

⋅L{δ(t)} = e

–ks

⋅1.0 = e

–ks

.

Applications of Laplace transform in the solution of linear ODEs

At the beginning of the section on Laplace transforms we indicated that you
could use these transforms to convert a linear ODE in the time domain into an
algebraic equation in the image domain. The resulting equation is then
solved for a function F(s) through algebraic methods, and the solution to the
ODE is found by using the inverse Laplace transform on F(s).

The theorems on derivatives of a function, i.e.,

L{df/dt} = s

⋅F(s) - f

o

,

L{d

2

f/dt

2

} = s

2

⋅F(s) - s⋅f

o

– (df/dt)

o

,

and, in general,

L{d

n

f/dt

n

} = s

n

⋅F(s) – s

n-1

⋅f

o

−…– s⋅f

(n-2)

o

– f

(n-1)

o

,

are particularly useful in transforming an ODE into an algebraic equation.