HP 50g Graphing Calculator User Manual

Page 16-15

Dirac’s delta function and Heaviside’s step function

In the analysis of control systems it is customary to utilize a type of functions that
represent certain physical occurrences such as the sudden activation of a switch
(Heaviside’s step function, H(t)) or a sudden, instantaneous, peak in an input to
the system (Dirac’s delta function,

δ(t)). These belong to a class of functions

known as generalized or symbolic functions [e.g., see Friedman, B., 1956,
Principles and Techniques of Applied Mathematics, Dover Publications Inc.,
New York (1990 reprint) ].

The formal definition of Dirac’s delta function,

δ(x), is δ(x) = 0, for x ≠0, and

Also, if f(x) is a continuous function, then

An interpretation for the integral above, paraphrased from Friedman (1990), is
that the

δ-function “picks out” the value of the function f(x) at x = x

0

. Dirac’s

delta function is typically represented by an upward arrow at the point x = x0,
indicating that the function has a non-zero value only at that particular value of
x

0

.

Heaviside’s step function, H(x), is defined as

Also, for a continuous function f(x),

Dirac’s delta function and Heaviside’s step function are related by dH/dx =

δ(x). The two functions are illustrated in the figure below.

)].

(

[

lim

)

(

lim

0

s

F

s

t

f

f

s

t

⋅

=

=

→

∞

→

∞

∫

∞

−∞

=

.

0

.

1

)

( dx

x

δ

∫

∞

−∞

=

−

).

(

)

(

)

(

0

0

x

f

dx

x

x

x

f

δ

⎩

⎨

⎧

<

>

=

0

,

0

0

,

1

)

(

x

x

x

H

∫

∫

∞

−∞

∞

=

−

0

.

)

(

)

(

)

(

0

x

dx

x

f

dx

x

x

H

x

f