ElmoMC SimplIQ Digital Servo Drives-Bell Getting Started User Manual

The SimplIQ for Steppers Getting Started & Tuning and Commissioning Guide

MAN-BELGS (Ver. 1.1)

84

Comparing (6) and (2), we find that the Laplace variable

s

is equivalent to the

derivative operator,

dt

d

s

⇔

and its inverse to an integrator,

∫

⇔

t

d

s

τ

1

.

The

transfer function that relates the torque of a motor to its position is roughly a
double integral (the torque is roughly proportional to acceleration), so that the

transfer function from the motor torque to its position is roughly

2

1

s

J

m

where

m

J

is the motor inertia.

Please note that the transfer function is a full description of the response of its
related system to any input, not just to sinusoids.

It is customary to describe the frequency response of a system pictorially by a
plot of the amplitude and phase of (6) versus the frequency

ω

where

ω

= j

s

, this

plot is known as its Bode plot. A Bode plot example for the function

(

)

(

)(

)

33

60

3

2000

10

2

+

+

+

⋅

s

s

s

s

is given in Figure 75.

10

0

10

1

10

2

-30

-20

-10

0

10

20

30

dB

10

0

10

1

10

2

-200

-180

-160

-140

-120

-100

deg

log(

ω)

Figure 75: Bode plot of a function

Another efficient pictorial representation of a linear system is the Nichols plot.
The Nichols plot is a plot of the amplitude of (6) versus its phase along the real
parameter,

ω

, where

ω

j

s

=

. The Nichols plot of the same transfer function is

shown in Figure 76. As will be shown in the next plot, the Nichols plot is a very
attractive description of an LTI system for feedback control design. An example

Nichols chart of the transfer function

(

)

(

)(

)

33

60

3

2000

10

2

+

+

+

⋅

s

s

s

s

is in the figure below.