The MC33926 motor driver carrier can supply up to almost 3 A
continuous current to a single brushed DC motor at 5 ? 28 V, and
it can tolerate peak currents up to 5 A for a few seconds, making
this a great general-purpose motor driver for medium-sized DC motors.
The MC33926 supports ultrasonic (up to 20 kHz) pulse width
modulation (PWM) of the motor output voltage, which eliminates the
audible switching sounds caused by PWM speed control, and a current
feedback circuit outputs an analog voltage on the FB pin that is
proportional to the output current. Since this board is a carrier for
the Freescale Semiconductor MC33926 H-bridge, we recommend careful
reading of the href="http://www.pololu.com/file/download/MC33926.pdf?file_id=0J233">MC33926
datasheet

The default states of many of the MC33926 logic input pins requires that many external connections be made to use this motor driver. To reduce the number of necessary external connections, the board has five default-overriding jumpers. All of the default-overriding jumpers are tied to VDD, except the D1 jumper, which is tied to GND. All VDD jumper pads are circles; the ground jumper pad is square.

In a typical application, five I/O lines are used to connect the motor driver to a microcontroller: the two input lines, IN1 and IN2, for direction control, one of the disable lines, D1 or D2, for PWM speed control, the status flag, SF, for monitoring motor driver errors, and the current sense output, FB, for monitoring motor current draw (connected to an analog-to-digital converter input). The control lines can be reduced to two pins if PWM signals are applied directly to the two input pins with both disable pins held inactive. A two-pin interface can also be achieved using one of the disable lines for PWM speed control and the INV input for direction control with IN1 and IN2 held at different values (i.e. one set HIGH and the other set LOW). In each of these cases, the other unused lines must be set to enable proper operation. For example, if D2 is used for the PWM input (as is typically the case), D1 must be held low to prevent it from disabling the motor driver. The circuit board provides convenient jumper points for overriding the motor driver defaults without having to connect extra wires to the module.

The current sense and status flag connections are optional, though monitoring of the status flag can allow detection of latched fault conditions. The status flag is an open-drain output, so multiple units can have their status flag pins wired together for applications where I/O pins are scarce and determining which motor driver is experiencing a fault condition is not necessary.

Note that the default state of the enable pin, EN, is LOW, which holds the chip in a low-current sleep mode. You will need to hold this pin high (either with an external connection or via the default-overriding jumper next to the pin) to allow the chip to run.

The MC33926 has under-voltage, over-current, and over-temperature protection. Some protection events are indicated by the status flag pin (SF), which is an active-low pin allowing the SF pin from multiple boards to connected to a single input. If the chip detects an over-current or over-termperature event, the SF is latched LOW and OUT1 and OUT2 are set to high-impedance. To unlatch the status flag pin toggle the D1, D2 , EN or VIN lines. The carrier board has a reverse-protection MOSFET for added protection to the motor driver chip.

The MC33926 motor driver used on the carrier board has a maximum current rating of 5 A continuous. However, the chip by itself will overheat at lower currents. For example, in our tests at room temperature with no forced air flow, the chip was able to deliver 5 A for 5 s and 4 A for 18 s before the chip˙s thermal protection started reducing the current. A continuous current of 3 A was right at the over-temperature threshold; in some tests the thermal protection kicked in after a minute, and in other tests the chip delivered 3 A for over five minutes without triggering thermal protection. The actual current you can deliver will depend on how well you can keep the motor driver cool. The carrier˙s printed circuit board is designed to draw heat out of the motor driver chip, but performance can be improved by adding a heat sink. Our tests were conducted at 100% duty cycle; PWMing the motor will introduce additional heating proportional to the frequency.