HP (Hewlett-Packard) 50g ユーザーズマニュアル

Page 16-10

Press 

J @ODETY to get the string “

Linear w/ cst coeff

” for the ODE type in 

this case.

The Laplace transform of a function f(t) produces a function F(s) in the image 
domain that can be utilized to find the solution of a linear differential equation 
involving f(t) through algebraic methods.   The steps involved in this application 
are three:

1. Use of the Laplace transform converts the linear ODE involving f(t) into an 

algebraic equation.

2. The unknown F(s) is solved for in the image domain through algebraic 

manipulation.

3. An inverse Laplace transform is used to convert the image function found in 

step 2 into the solution to the differential equation f(t).

The Laplace transform for function f(t) is the function F(s) defined as

The image variable s can be, and it generally is, a complex number.

Many practical applications of Laplace transforms involve an original function 
f(t) where t represents time, e.g., control systems in electric or hydraulic circuits.  
In most cases one is interested in the system response after time t>0, thus, the 
definition of the Laplace transform, given above, involves an integration for 
values of t larger than zero.   
The inverse Laplace transform maps the function F(s) onto the original function 
f(t) in the time domain, i.e., L 

-1

{F(s)} = f(t).

The convolution integral or convolution product of two functions f(t) and g(t), 
where g is shifted in time, is defined as 

0

{ ( )}

( )

( )

.

L

∞

−

=

=

⋅

∫

st

f t

F s

f t e dt

.

)

(

)

(

)

)(

*

(

0

∫

⋅

−

⋅

=

t

du

u

t

g

u

f

t

g

f