Stepper motors and stepper-based linear actuators are often selected for open-loop motion control devices and equipment. These can be found in a wide range of products and systems such as laboratory equipment, medical devices, vision systems, analytical equipment, office products, aerospace, communications systems, semiconductor equipment, and light industrial equipment.
Two Basic Types of Stepper Drives
The two major types of drives for stepper motors and stepper-based linear actuators are the L/R drive and the chopper drive. Some of the criteria for choosing the drive type include:
Cost of the drive
Physical size and configuration of the drive
Available power source
Rated output current of the drive
Motion duty cycle
Total loading on the motor
Required speed range of the motor
The L/R Drive
Think of the L/R drive as a “constant voltage” drive. For continuous-duty motor operation in a room-temperature environment, you essentially match up the available power source voltage for the L/R drive to the rated coil voltage of the motor. Regarding the name L/R Drive, the L is the electrical symbol for inductance and the R is the electrical symbol for resistance. Since the stepper motor torque is proportional to ampere-turns, it is the current through the motor windings that determines the output performance at any speed including zero.
At standstill, the maximum “holding current” current through the windings is limited by the coil resistance. As the stepping rate (motor speed) increases, the coil inductance becomes a major current-limiting factor (limiting the rate of change of coil current) along with the back-emf. Back-emf is a generated voltage proportional to the speed that is produced within the motor windings during rotation, which works against the source voltage because every motor is also a generator.
The motors operated with an L/R drive will have a relatively limited performance range when compared to using a chopper drive. The source-voltage-to-motor-voltage ratio with the L/R drives is basically 1:1 whereas with chopper drives, it can be many multiples such as 2:1, 4:1, 8:1, or more (see Figure 3).
Some of the reasons for selecting an L/R drive instead of a chopper drive might be a lower cost of the drive, smaller physical size, a relatively slow motor speed range, use of a unipolar motor, or the limitations of using a battery power source. A good example of a product utilizing many of these previously listed reasons for using an L/R drive with a small stepper-based linear actuator is a handheld electronic pipette as shown in Figure 1.
Typically, L/R driver performance curves published by stepper motor and stepper-based linear actuator manufacturers were developed with the full rated motor voltage available at the motor’s lead wires at zero steps per second. If there are any voltage drops through the drive circuitry, then the DC power supply voltage would be set slightly higher to compensate for the total voltage loss in the drive.
The Chopper Drive
Think of this type as a “constant current” drive. For continuous-duty motor operation in a room-temperature environment, you set the output RMS (Root Mean Square) current of the chopper drive to the rated RMS coil current of the motor. Regarding the name chopper drive, this technique for maintaining the proper motor phase current levels throughout a usable speed range is to rapidly turn on and off (i.e., chopping) a relatively high source voltage via a proportional duty cycle while circuitry monitors the current levels in the motor windings. Chopper drives can be separate standalone units or integrated with the motor. For an example of a compact standalone chopper drive, see Figure 2.
If the application has a fairly short duty cycle (i.e., the full powered ON or Run times relative to the OFF or lower-current zero motion Hold times) in a moderate-temperature environment, then a higher magnitude of run current can be used to increase the motion performance of the motor; however, care must be taken when using this higher-than-rated run current. The current levels and ON times versus hold or OFF times, as well as the ambient temperature and any motor cooling methods (conduction, convection, etc.,) will determine the internal coil temperatures. It is recommended to consult the motor manufacturer if significantly high phase currents are necessary.
The additional circuitry within chopper drives senses the magnitude of the phase currents and to control the voltage chopping, may increase their price (compared to an L/R drive) but it can help to maintain a high level of motor torque or force throughout a relatively wider speed range. The power supply voltage to a chopper drive is typically much higher than the rated voltage of the motor. As discussed in the L/R drive section, the source-voltage-to-motor voltage ratio for a chopper drive is usually significantly higher than 1:1 and is typically 8:1 or even higher; therefore, the relative performance range can be greatly improved (see Figure 3).
The inductance of relatively low-voltage stepper motors and actuators is significantly less than their mechanically equivalent motors of higher rated coil voltages. For very good motor performance over a wider speed range, a low-voltage motor operated with a chopper drive at a relatively high source voltage is selected. The relatively low inductance and lower back-emf characteristics of a low-voltage motor in conjunction with a high source voltage chopper drive can provide excellent performance results. The major requirement with these low-voltage motor configurations is that the drive has to be capable of providing higher levels of phase current.
As a cautionary note, some chopper drive manufacturers advertise their product’s output phase current levels as a peak value; using larger values is typically a marketing tactic. The continuous-duty phase currents for stepper motors and stepper-based linear actuators are typically rated as RMS values (RMS = Peak × 0.707)
Configurations and Features
There can be other configurations and features for stepper drives:
- Bipolar Drives. For operating 4- or 8-lead bipolar stepper motors and stepper-based linear actuators.
- Unipolar Drives. For operating 6- or 8-lead unipolar steppers and actuators (typically L/R type drives).
- Non-programmable Drives. Require digital “Pulse” and “Direction” inputs from a controller (and some include an “Output Enable” digital input). The controller outputs a single pulse to the drive for each motor step and outputs a stream of pulses to the drive for the motor to ‘index’ a precise amount. The quantity of pulses to the drive determines the amount of rotational or linear movement and the frequency of the pulse train determines the rotational or linear speed of the stepper motor or linear actuator, respectively.
- Programmable Drives. These drives incorporate a microprocessor and can execute various motion control programs in addition to immediately executable motor commands. These drives can have the motor index virtually any amount in either direction and at various speeds in real time or under user-specified program control. Most programmable drives have some general-purpose (GP) digital inputs/outputs (I/O) for talking with or controlling other equipment (and thus providing coordinated system motion control), and also have some conditional functions based upon the GP inputs, the relative motor position, and/or encoder feedback data.
- Half-Step Mode in Addition to Standard Full-Step Mode. In the half-step mode, the drive can electronically divide each full step of a stepper motor in half; for example, a stepper motor with a 15° full-step rotation can operate at a 7.5° step angle with the drive in the half-step mode. A 1.8° stepper motor can be run with 0.9° half-step increments, and so forth. Similarly, the linear resolution of a stepper-based linear actuator can be divided in half using the half-step mode.
- Micro-Stepping Modes. Micro-stepping drives can electronically divide each full step of a stepper motor or actuator into finer discrete step angles than half-stepping. Typical division factors are 1/4, 1/8, 1/16, 1/32, etc., and/or 1/5, 1/10, 1/25, 1/50, etc. The four major benefits of micro-stepping the motor are increased rotary or linear resolution, smoother operation, reduced audible dynamic noise, and a reduction of dynamic resonance. The tradeoff for these benefits is a reduction in motor step accuracy and repeatability, especially under loaded conditions.
- Encoder Input. There are many applications that may require a method of speed verification and/or positional verification such as certain medical devices, gas or liquid flow regulation, communications equipment, or microelectronics. To close the loop of a stepper-based system, an integrated motor-mounted or a load-attached rotary or linear encoder can essentially ‘tell’ this type of drive if the motor is successfully achieving the commanded step rates and/or has achieved the true commanded position for every move. An encoder can also recover the significant loss of motor step accuracy when using fine micro-stepping modes as described above.
Acceleration/Deceleration Ramping. To help get a relatively greater load moving and/or achieve higher motor step rates (possibly without having to change to a physically larger motor), the use of accel/decel ramping can often be implemented with many stepper drives. As shown in typical published (non-ramped) speed versus torque, or speed versus force performance curves for stepper motors or step-per-based actuators, the slower the motor speed the higher the output torque or output force, respectively. See Figure 4 for an example of a linear actuator non-ramped performance curve.
To benefit from lower speed, higher force levels, the rotary or linear move profiles can include an initial start from standstill at a relatively low base speed and then immediately begin ramping up to the desired high velocity and then reverse this technique if a deceleration ramp is also required. Just as we have to accelerate heavy motor vehicles up to speed from a dead stop, stepper motors and actuators can usually get relatively large loads moving with the use of ramping. To continue with this analogy, it requires extra power (i.e. engine mechanical horsepower for a conventional vehicle or electrical power for a motor) to get moving up to speed and then, depending upon the type of loading, it may take significantly less power to maintain motion at a constant velocity. Figure 5 is an example of a possible performance benefit with ramping.
A Phase Current ‘Boost’ Feature. Some chopper drives offer an option to set a boosted phase current (higher magnitude than continuous rated current) during part of, or possibly all of, any acceleration and/or deceleration ramp. Typically, the active time of boosted current levels is of limited duration during a ramp to prevent overheating the motor windings. This boosted current during an acceleration ramp can increase the internal torque of the motor, allowing the motor to get a relatively larger load moving from the rest position. Similarly, a boosted current during a deceleration ramp can help to stop a relatively larger moving load.
Conclusion
In summary, there may be many factors to consider when designing a motion control device or system using stepper motors or stepper-based linear actuators. One of the critical components is the stepper drive, and its selection is best determined by various factors such as the type, physical size, voltage and current ratings, available step modes, controllability and programmability, ramping and/or current boosting options, as well as cost and delivery lead time.
Depending upon the loading and duty cycle, significantly improved performance from, or the increase in energy efficiency of a stepper motor or stepper-based actuator can often be achieved by the proper selection of the drive type (along with any optional features of the drive) and the power source.
This article was contributed by Haydon Kerk Pittman, Harleysville, PA. For more information, visit here .