A4973_16 Datasheet, PDF(6/11 Page) Allegro MicroSystems

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A4973_16 Datasheet, PDF (6/11 Pages) Allegro MicroSystems – Full-Bridge PWM Motor Driver

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A4973

Full-Bridge PWM Motor Driver

The operation of the circuit is as follows: when the PWM latch is

reset by the current comparator, the voltage on the RC terminal

will begin to decay from approximately 0.60VCC. When the

voltage on the RC terminal reaches approximately 0.22VCC, the

PWM latch is set, thereby enabling the driver(s).

RC Blanking. In addition to determining the fixed off-time of

the PWM control circuit, the CT component sets the comparator

blanking time. This function blanks the output of the comparator

when the outputs are switched by the internal current-control

circuitry (or by the PHASE, BRAKE, or ENABLE inputs).

The comparator output is blanked to prevent false over-current

detections due to reverse recovery currents of the clamp diodes,

and/or switching transients related to distributed capacitance in

the load.

During internal PWM operation, at the end of the tOFF time, the

comparatorâs output is blanked and CT begins to be charged

from approximately 0.22VCC by an internal current source of

approximately 1 mA. The comparator output remains blanked

until the voltage on CT reaches approximately 0.60VCC.

When a transition of the PHASE input occurs, CT is discharged

to near ground during the crossover delay time (the crossover

delay time is present to prevent simultaneous conduction of

the source and sink drivers). After the crossover delay, CT is

charged by an internal current source of approximately 1 mA.

The comparator output remains blanked until the voltage on CT

reaches approximately 0.60VCC.

When the device is disabled, via the ENABLE input, CT is

discharged to near ground. When the device is re-enabled, CT is

charged by an internal current source of approximately 1 mA.

The comparator output remains blanked until the voltage on CT

reaches approximately 0.60VCC.

For 3.3 V operation, the minimum recommended value

for CT is 680 pF Â± 5 %. For 5.0 V operation, the minimum

recommended value for CT is 470 pF Â± 5%. These values

ensure that the blanking time is sufficient to avoid false trips

of the comparator under normal operating conditions. For

optimal regulation of the load current, the above values for CT

are recommended and the value of RT can be sized to determine

tOFF. For more information regarding load current regulation, see

below.

LOAD CURRENT REGULATION

WITH INTERNAL PWM

CURRENT-CONTROL CIRCUITRY

When the device is operating in slow current-decay mode,

there is a limit to the lowest level that the PWM current-

control circuitry can regulate load current. The limitation is the

minimum duty cycle, which is a function of the user-selected

value of tOFF and the minimum on-time pulse tON(min) max that

occurs each time the PWM latch is reset. If the motor is not

rotating (as in the case of a stepper motor in hold/detent mode, a

brush dc motor when stalled, or at startup), the worst case value

of current regulation can be approximated by:

IAVE

{

[

VBB

Ã RDS) ]

1.05 Ã

Ã tON(min)max } â [1.05 (I Ã RDS

(tON(min)max + tOFF) Ã RLOAD

VF)

tOFF

]

where tOFF = RT x CT, RLOAD is the series resistance of the load,

VBB is the motor supply voltage and t ON(min)max is specified in

the Electrical Characteristics table. When the motor is rotating,

the back EMF generated will influence the above relationship.

For brush dc motor applications, the current regulation is

improved. For stepper motor applications, when the motor is

rotating, the effect is more complex. A discussion of this subject

is included in the section on stepper motors below.

The following procedure can be used to evaluate the worst-case

slow current-decay internal PWM load current regulation in the

system:

1. Set VREF to 0 volts. With the load connected and the PWM

current control operating in slow current-decay mode, use an

oscilloscope to measure the time the output is low (sink on) for

the output that is chopping. This is the typical minimum on time

(tON(min) typ) for the device.

2. The CT then should be increased until the measured value

of tON(min) is equal to tON(min) max as specified in the electrical

characteristics table.

3. When the new value of CT has been set, the value of RT should

be decreased so the value for tOFF = RT x CT (with the artificially

increased value of CT) is equal to the nominal design value.

4. The worst-case load-current regulation then can be measured

in the system under operating conditions.

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

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