Stepper Motors

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As the name implies, stepper motors are different from run-of-the-mill DC motors, in that you make them move by sending them phased pulses of current, making the motor move in "steps." In order to do this, you need to send pulse trains of varying polarity to multiple windings, the speed of the motor being determined by the frequency of the pulses, and the direction of motor motion being determined by the phasing between the pulses being applied to the various windings. As a result, you get more-precise control over motor motion (vs. DC motors), but at the cost of some control circuitry complexity and less power for size.

A number of types of stepper motors are available. As some are more common than others, I'll briefly discuss the ones you'll be most likely to run across, and most likely to be used in BEAMbots.

Contents

Permanent magnet stepper motors

The most common type of stepper motor you'll run across is the permanent magnet (PM) stepper. As you might suspect from the name, PM steppers have a permanent magnet in them -- in the form of a rotor magnetized in alternate polarity "stripes" parallel to the rotor shaft.

Image:stepper_pm.gif

The step size (angular resolution) of a given motor is entirely a function of the angular "width" of these magnetized stripes -- 30 degrees is common, although steps down to 7.5 degrees are not unheard of in even very inexpensive motors.

Given this construction, you'll most often run into two different wiring configurations -- unipolar and bipolar. I'll start with the bipolar configuration since it's a bit simpler.

Bipolar stepper motor

Image:Bipolar stepper motor layout.gif

Bipolar stepper motors generally have four leads, in two pairs, each pair powering one coil. These motors are common and cheap -- as an example, the stepper motor that drives a floppy drive read / write head is a bipolar stepper motor. To rotate the motor, we simply supply the two coils with phase-shifted pulse trains. If you have no data on a given bipolar motor, you can identify which leads correspond to the windings of the motor with an ohmeter -- just check for continuity between the leads at the end of each winding.

Unipolar stepper motor

Image:stepper_unipolar.gif

Unipolar stepper motors generally have six leads, in two triplets, each triplet powering one coil with a center tap . On occasion, you'll find a unipolar stepper with only five leads -- here the two "common" leads (center taps) have been tied together internally. Note that a unipolar motor's rotor is identical to a bipolar motor's rotor. Often unipolar motors are controlled by using the center taps as a common point (cathode or anode), and then just switching drive voltage from one end of the given coil to the other (to reverse coil polarity). This avoids the need for an H-bridge or similar motor driver. You can also drive unipolar stepper motors in a bipolar fashion (i.e. by just ignoring the center taps). If you have no data on a given unipolar motor, you will need to work a bit to find which leads correspond to each winding. Using an ohmeter, look for pairs of leads with equal resistance between them -- the common of each triplet will have equal resistance to two other leads, and high (essentially infinite) resistance to all the leads in the other triplet.

Variable Reluctance Motors

Image:Stepper_variable_reluctance.gif

Many hard disk drives have motors with four terminals. One of these is a common terminal, and the other three each connect to a different winding (this can be confirmed with an Ohm meter). In order to drive this type of motor, power must be applied to each of the three windings in sequence. Variable reluctance motors with 4 and 5 windings also exist.

Controlling a stepper motor

Two control sequences for single stepping a unipolar or bipolar stepper motor are shown below (here positive voltages are denoted by red bars, and negative / ground by blue):

Image:stepper_pattern_1.gif

This first sequence only powers one winding at a time, so it provides lower torque at lower input power.

Image:stepper_pattern_2.gif

The second sequence powers two windings at a time and produces a torque about 40% greater than for the previous sequence while using twice as much power. From a circuitry perspective, though, producing this sequence is fairly simple (since the duty cycle is 50%, a master / slave bicore pair can be used, with some down-stream drivers, and potentially reversing logic).

The following articles contain circuits for driving stepper motors:


Also See:

External References


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