PBL 3770A
In order to minimize electromagnetic
interference, it is recommended to route
MA and MB leads in parallel on the
printed circuit board directly to the
terminal connector. The motor wires
should be twisted in pairs, each phase
separately, when installing the motor
system.
V
C
C
(+5
V)
V
M
M
STEPPER
MOTOR
1
1
6
3,
14
1
V
V
V
8
7
9
Phase
R
C
C
M
M
Phas
M
B
A
e
I
I
1
1
I
PBL 3770A
I
A
M
0
0
1
5
A
A
T
2
GN
D
C
E
1
0
1
6
4, 5
12, 13
56
k
1
k
Unused inputs
820
pF
820
pF
0.5
Unused inputs should be connected to
proper voltage levels in order to obtain
the highest possible noise immunity.
V
(+5
V)
V
C
C
M
M
1
1
6
3,
14
Ramping
1
V
V
V
8
7
9
Phase
M
Phas
R
C
C
M
M
B
B
e
I
I
A stepper motor is a synchronous motor
and does not change its speed due to
load variations. This means that the
torque of the motor must be large
enough to match the combined inertia of
the motor and load for all operation
modes. At speed changes, the requires
torque increases by the square, and the
required power by the cube of the speed
change. Ramping, i.e., controlled
1
B
0
1
I
PBL 3770A
I
M
1
5
0
A
B
T
GN
D
C
E
1
0
1
6
4, 5
12, 13
2
Diodes are
UF 4001 or
56
k
1
k
820
pF
BYV27
t
820
pF
0.5
100
ns
r
r
Figure 8. Typical stepper motor driver application with PBL 3770A.
acceleration or deceleration must then
be considered to avoid motor pull-out.
VF (V)
VSat (V)
1.8
1.8
VCC , VMM
1.6
1.4
1.2
1.0
1.6
1.4
1.2
T = 25°C
j
The supply voltages, VCC and VMM, can
be turned on or off in any order. Normal
dv/dt values are assumed.
Before a driver circuit board is
removed from its system, all supply
voltages must be turned off to avoid
destructive transients being generated
by the motor.
T = 125
°C
j
T = 25°C
1.0
j
.8
.6
.8
.6
T = 125°C
j
.4
.2
.4
.2
0
0
0
Switching frequency
.40
.80
IM (A)
1.2
1.6
0
.40
.80
IM (A)
1.2
1.6
The motor inductance, together with the
pulse time, toff, determines the switching
frequency of the current regulator. The
choice of motor may then require other
values on the RT, CT components than
those recommended in figure 6, to
obtain a switching frequency above the
audible range. Switching frequencies
above 40 kHz are not recommended
because the current regulation can be
affected.
Figure 9. Typical source saturation vs.
output current.
Figure 11. Typical lower diode voltage
drop vs. recirculating current.
Interference
VSat (V)
As the circuit operates with switched-
mode current regulation, interference-
generation problems can arise in some
applications. A good measure is then to
decouple the circuit with a 0.1 µF
ceramic capacitor, located near the
package across the power line VMM and
ground.
Also make sure that the VRef input is
sufficiently decoupled. An electrolytic
capacitor should be used in the +5 V rail,
close to the circuit.
The ground leads between RS, CC and
circuit GND should be kept as short as
possible. This applies also to the leads
connecting RS and RC to pin 16 and pin
10 respectively.
1.8
1.6
1.4
1.2
T = 125°C
j
1.0
Analog control
.8
.6
As the current levels can be continu-
ously controlled by modulating the VR
input, limited microstepping can be
achieved.
.4
.2
0
T = 25°C
j
0
.40
.80
1.2
1.6
IM (A)
Figure 10. Typical sink saturation vs.
output current.
7
ERICSSON [ ERICSSON ]
