Step, Stepper, Stepping Motor Fundamentals

User Manual: Step, Stepper, Stepping Motor Fundamentals

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Stepper Motor Basics

Stepper Motor Basics
Note: For this discussion, stepper, stepping and step motor(s) are used interchangeably.
A stepper motor is a digital device. Digital information is processed by the stepper motor to accomplish
an end result, in this case, controlled motion. One may assume that a stepper motor will dependably
follow digital instructions, just as a computer is expected. This is the distinguishing feature of a stepper
motor.
The stepper motor is an electrical motor that is driven by digital pulses rather than a continuously
applied voltage. Inherent in this concept is open‐loop control, wherein a train of pulses translates into so
many shaft revolutions, with each revolution requiring a given number of pulses. Each pulse equals one
rotary increment, or step (hence named, stepper, stepping, or step motor), which is only a portion of
one complete rotation. Therefore, counting pulses can be applied in the stepper motor to achieve a
desired amount of shaft rotation. The count automatically represents how much movement has been
achieved, without the need for feedback information, as would be the case in servo systems, and other
technologies. Although not required, most stepper motors can accommodate an encoder when desired.

Applications for Stepper Motor
Although the stepper motor has been overshadowed in the past by servo systems for motion control, it
has emerged as the preferred technology in more and more areas. The major factor in this trend
towards the stepper motor is the prevalence of digital control, the emergence of the microprocessor,
improved designed, i.e. high‐torque models, and the lower cost. Today, stepper motor applications are
all around us: they are used in printers (paper feed, print wheel), disk drives, clocks and watches, as well
as used in factory automation and machinery.
Anaheim Automation’s cost‐effective stepper motor product line is the wise choice for both OEM and
user accounts. Anaheim Automation's customers for the stepper motor product line is diverse: industrial
companies operating or designing automated machinery or processes that involve food, cosmetics or
medical packaging, labeling or tamper‐evident requirements, cut‐to‐length applications, assembly,
conveyor, material handling, robotics, special filming and projection effects, medical diagnostics, camera
tracking, inspection and security devices, aircraft controls, pump flow control, metal fabrication (CNC
machinery), and equipment upgrades. A stepper motor is most often found in motion systems that
require position control.
Anaheim Automation, Inc. also offers a stepper motor product line that integrates a matched stepper
motor, driver and controller in one unit. This design concept makes selection easy, thus reducing errors
and wiring time. With friendly customer service and professional application assistance, Anaheim
Automation often surpasses the customer's expectations for fulfilling specific stepper motor and driver
requirements, as well as other motion control needs.
IMPORTANT NOTE: Technical assistance regarding the stepper motor product line is available at no
charge. This assistance is offered to help the customer in choosing Anaheim Automation products for a
specific application. However, any selection, quotation, or application suggestion for a stepper motor, or
any other product, offered from Anaheim Automation’s staff, its' representatives or distributors, are
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only to assist the customer. In all cases, determination of fitness of the stepper motor in a specific
system application is solely the customers' responsibility. While every effort is made to offer solid advice
regarding the stepper motor in a specific application, and to produce technical data and illustrations
accurately, such advice and documents are for reference only, and subject to change without notice.
Anaheim Automation is in no event responsible or liable for indirect or consequential damages resulting
from the use or application of the stepper motor. Improper use of a stepper motor in an application can
result in personal injury or death, property damage, and/or economic loss.

Types of Stepper Motors
There are three basic types of stepper motor. These stepper motor types vary by construction and in
how they function. Each stepper motor type offers a solution to an application in a different way. The
three basic types of stepper motor include the Variable Reluctance, Permanent Magnet, and Hybrid.
Variable Reluctance (VR) Stepper Motor
The Variable Reluctance stepper motor is known for having a soft iron multiple rotor and a wound stator
construction. The Variable Reluctance stepper motor generally operates in step angles from 5 to 15
degrees at relatively high step rates. They also possess no detent torque. See Figure 5 of our Technical
Information for Step Motor Systems for more details. Anaheim Automation does not carry any VR
stepper motors.
Permanent Magnet (PM) Stepper Motor
The Permanent Magnet stepper motor differs from the Variable Reluctance stepper motor by having
permanent magnet rotors with no teeth. These rotors are magnetized perpendicular to the axis. When
the four phases are energized in sequence, the rotor rotates as it is attracted to the magnetic poles. See
Figure 6 of our Technical Information for Step Motor Systems for more details. The Permanent Magnet
stepper motor generally has step angles of 45 to 90 degrees and tends to step at relatively low rates, but
produce high torque and excellent damping characteristics. See the TSM series for Anaheim
Automation’s Permanent Magnet Stepper Motor Product lines.
Hybrid Stepper Motor
The Hybrid stepper motor combines qualities from the permanent magnet and variable reluctance
stepper motors. The Hybrid stepper motor has some of the desirable features of each. This type of
stepper motor has a high detent torque, excellent holding and dynamic torque, and they can operate in
high stepping speeds. Step angles of 0.9 to 5.0 degrees are normally seen in the Hybrid stepper motor.
Bi‐filar windings are generally supplied to this stepper motor, so that a single power supply can be used
to power the stepper motor. The rotor will rotate in increments of 1.8 degrees if the phases are
energized one at a time in the order they are indicated at. This stepper motor can be driven in two
phases at a time to yield more torque. The Hybrid stepper motor can also be driven by one then two
then one phase to produce half‐steps of 0.9 degree increments. See Anaheim Automation’s Hybrid
Stepper Motor Product lines: Standard 23D, 34D, 42D, 23W, 34W and 42W, for round‐bodied, square‐
flanged stepper motors, and the High‐Torque 08Y, 11Y, 14Y, 15Y, 17Y, 23Y, 34Y, 42Y, 23V, 34V, 34N,
42N, 34K, 42K, and IP65‐Rated series motors for square‐bodied, square‐flanged stepper motors.
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Stepper Motor Modes
There are three excitation modes that are commonly used with the stepper motor. These stepper motor
modes are the full‐step, half‐step‐ and microstep.
Stepper Motor ‐ Full‐Step
In full‐step operation, the stepper motor steps through the normal step angle, e.g. 200 step/revolution
motors take 1.8 steps, while in half‐step operation 0.9 steps are taken. There are two kinds of full‐step
modes. Single phase full‐step excitation is where the stepper motor is operated with only one phase
energized at a time. This mode should only be used in applications where torque and speed
performance are not important, wherein the motor is operated at a fixed speed and load conditions are
well defined. Typically stepper motors are used in full‐step mode as replacements in existing motion
systems, and not used in new developments. Problems with resonance can prohibit operation at some
speeds. This type of mode requires the least amount of power from the drive power supply of any of the
excitation modes. Dual phase full‐step excitation is where the stepper motor is operated with two
phases energized at a time. This mode provides good torque and speed performance with a minimum of
resonance problems. Note: Dual excitation, provides about 30 to 40 percent more torque than single
excitation, but does require twice the power from the drive power supply. Many of Anaheim
Automation’s microstep drivers can be set at Full‐Step mode if needed.
Stepper Motor ‐ Half‐Step
Stepper motor half‐step excitation is alternate single and dual phase operation resulting in steps one
half the normal step size. Therefore, this mode provides twice the resolution. While the motor torque
output varies on alternate steps, this is more than offset by the need to step through only half the angle.
This mode had become the predominately used mode by Anaheim Automation beginning in the 1970’s,
because it offers almost complete freedom from resonance problems. The stepper motor can be
operated over a wide range of speeds and used to drive almost any load commonly encountered.
Although half‐step drivers are still a popular and affordable choice, many newer microstep drivers are a
cost‐effective alternative. Anaheim Automation’s BLD75 series is a very popular driver and is suitable for
a wide range of stepper motors.
Stepper Motor ‐ Microstep
In the stepper motor microstep mode, a stepper motor's natural step angle can be divided into much
smaller angles. For example, a standard 1.8 degree motor has 200 steps/revolution. If the motor is
microstepped with a 'divide‐by‐10', then each microstep moves the motor 0.18 degrees, which is 2,000
steps/revolution. The microsteps are produced by proportioning the current in the two windings
according to sine and cosine functions. This mode is only used where smoother motion or more
resolution is required. Typically, microstep modes range from divide‐by‐10 to divide‐by‐256 (51,200
steps/rev for a 1.8 degree motor). Some microstep drivers have a fixed divisor, while the more
expensive microstep drivers provide for selectable divisors. For cost‐effective microstep drivers, see
Anaheim Automation’s MBC and MLP Series. Note: In general, the larger the microstep divisor provided,
the more costly the stepper motor driver. Should you prefer, Anaheim Automation also manufactures a
series of Integrated Stepper Motor/Driver, meaning the stepper motor and driver are in one unit. This
design approach takes the guesswork out of motor and driver compatibility. See the 17MD, 23MD and
34MD Series for more information.
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Stepper Motor Feedback
The stepper motor is typically controlled by a driver and indexer/controller. The amount, speed, and
direction of rotation of a stepper motor is determined by the specific configuration of digital control
devices. The main types of stepper motor control devices are: stepper motor drivers and stepper motor
controllers, which include indexers and pulse generators. The stepper motor driver accepts the clock
pulses and direction signals and translates these signals into appropriate phase currents for the stepper
motor. The stepper motor indexer creates the clock pulses and the direction signals for the stepper
motor. The computer or PLC (Programmable Logic Controller) sends out commands to the indexer or
controller.

Customizing a Stepper Motor
Anaheim Automation offers a variety of options to customize the stepper motor. The list of available
customizations includes, but is not limited to: shaft modifications, mechanical brake or encoder
additions, shaft flat or seal for an IP65 rating, mounting dimension changes, and customization for
specific speed, torque, and voltage characteristics. Please contact Anaheim Automation for your custom
stepper motor requirements. There may be a Non‐Recurring Engineering (NRE) charge, and/or a
minimum purchase for customizations and modifications. Note: Do not attempt to modify a stepper
motor on your own. Changes to a stepper motor once it is shipped can affect its performance and will
void its warranty.

Stepper Motor Environmental Considerations
The following environmental and safety considerations must be observed during all phases of operation,
service and repair of a stepper motor system. Failure to comply with these precautions violates safety
standards of design, manufacture and intended use of the stepper motor, driver and controiller. Please
note that even a well‐built stepper motor products operated and installed improperly, can be hazardous.
Precaution must be observed by the user with respect to the load and operating environment. The
customer is ultimately responsible for the proper selection, installation, and operation of the stepper
motor system.
The atmosphere in which a stepper motor is used must be conducive to good general practices of
electrical/electronic equipment. Do not operate the stepper motor in the presence of flammable gases,
dust, oil, vapor or moisture. For outdoor use, the stepper motor, driver and controller must be
protected from the elements by an adequate cover, while still providing adequate air flow and cooling.
Moisture may cause an electrical shock hazard and/or induce system breakdown. Due consideration
should be given to the avoidance of liquids and vapors of any kind. Contact the factory should your
application require specific IP ratings. It is wise to install the stepper motor, driver and controller in an
environment which is free from condensation, dust, electrical noise, vibration and shock.
Additionally, it is preferable to work with the stepper motor/driver /controller system in a non‐static
protective environment. Exposed circuitry should always be properly guarded and/or enclosed to
prevent unauthorized human contact with live circuitry. No work should be performed while power is
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applied. Don’t plug in or unplug the connectors when power is ON. Wait for at least 5 minutes before
doing inspection work on the stepper motor system after turning power OFF, because even after the
power is turned off, there will still be some electrical energy remaining in the capacitors of the internal
circuit of the stepper motor driver.
Plan the installation of the stepper motor, driver and/or controller in a system design that is free from
debris, such as metal debris from cutting, drilling, tapping, and welding, or any other foreign material
that could come in contact with circuitry. Failure to prevent debris from entering the stepper motor
system can result in damage and/or shock.
Stepper Motor Wiring
The following information is intended as a general guideline for wiring of the Anaheim Automation
stepper motor product line. Be aware that when you route power and signal wiring on a machine or
system, radiated noise from the nearby relays, transformers, and other electronic devices can be
introduced into the stepper motor and encoder signals, input/output communications, and other
sensitive low voltage signals. This can cause system faults and communication errors.
WARNING – Dangerous voltages capable of causing injury or death may be present in the stepper motor
system. Use extreme caution when handling, wiring, testing, and adjusting during installation, set‐up,
tuning, and operation. Don’t make extreme adjustments or changes to the stepper motor system
parameters, which can cause mechanical vibration and result in failure and/or loss. Once the stepper
motor is wired, do not run the stepper driver by switching On/Off the power supply directly. Frequent
power On/Off switching will cause fast aging of the internal components, which will reduce the lifetime
of stepper motor system.
Strictly comply with the following rules:
•

Follow the Wiring Diagram with each stepper motor

•

Route high‐voltage power cables separately from low‐voltage power cables.

•

Segregate input power wiring and stepper motor power cables from control wiring and motor
feedback cables as they leave the stepper motor driver. Maintain this separation throughout
the wire run.

•

Use shielded cable for power wiring and provide a grounded 360 degree clamp termination to
the enclosure wall. Allow room on the sub‐panel for wire bends.

•

Make all cable routes as short as possible.

NOTE: Factory made cables are recommended for use in our stepper motor and driver systems. These
cables are purchased separately, and are designed to minimize EMI. These cables are recommended
over customer‐built cables to optimize system performance and to provide additional safety for the
stepper motor system and the user.
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WARNING – To avoid the possibility of electrical shock, perform all mounting and wiring of the stepper
motor and driver system prior to applying power. Once power is applied, connection terminals may have
voltage present.
Stepper Motor Mounting
The following information is intended as a general guideline for the installation and mounting of the
stepper motor system. WARNING – Dangerous voltages capable of causing injury or death may be
present in the stepper motor system. Use extreme caution when handling, testing, and adjusting during
installation, set‐up, and operation. It is very important that the wiring of the stepper motor and driver
be taken into consideration upon installation and mounting.
Subpanels installed inside the enclosure for mounting stepper motor system components, must be a
flat, rigid surface that will be free from shock, vibration, moisture, oil, vapors, or dust. Remember that
the stepper motor and driver will produce heat during work; therefore, heat dissipation should be
considered in designing the system layout. Size the enclosure so as not to exceed the maximum ambient
temperature rating. It is recommended that the stepper motor driver and controller be mounted in
position as to provide adequate airflow. The stepper motor should be mounted in a stable fashion,
secured tightly, to minimize vibration. NOTE: There should be a minimum of 3 inches between the
stepper motor driver and any other devices mounted in the system/electric panel or cabinet. If using
relays in your motion system, take care to protect the relays and the stepper driver and controller, and
always run these wires separately. When using a DC relay, put a diode across the coil, and when using an
AC relay, be sure to use a MOV.
NOTE: In order to comply with UL and CE requirements, the stepper motor system must be grounded in
a grounded conducive enclosure offering protection as defined in standard EN 60529 (IEC 529) to IP55
such that they are not accessible to the operator or unskilled person. As with any moving part in a
system, the stepper motor should be kept out of the reach of the operator. A NEMA 4X enclosure
exceeds those requirements providing protection to IP66. To improve the bond between the power rail
and the subpanel, construct your subpanel out of a zinc‐plated (paint‐free) steel. Additionally, it is
strongly recommended that the stepper motor driver and/or controller be protected against electrical
noise interferences. Noise from signal wires can cause mechanical vibration and malfunctions.

Common Causes for Stepper Motor and/or Stepper Driver Failure
Note: Always read the specification sheet/user’s guide that accompanies each product
Problem: Intermittent or erratic stepper motor or stepper driver function.
Solution: This is the most common cause of failure and one of the most difficult to detect. Start by
checking to insure that all connections are tight between the stepper motor and the stepper driver and
controllers. Evidence of discoloration at the terminals/connections, may indicate a loose connection.
When replacing a stepper motor, stepper driver or Driver Pack, or controller in a motion control system,
be sure to inspect all terminal blocks and connectors. Check cabling/wiring for accuracy. Stress stepper
motor wiring and connections for worse conditions and check with an ohmmeter. Whenever possible,
use Anaheim Automation’s shielded cables for stepper motor wiring.
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Stepper Motor Basics
Problem: Stepper motor wires were disconnected while the driver was powered up.
Solution: Avoid performing any service to the stepper motor, driver or controller while the power is on,
especially in regard to the motor connections. This precaution is imperative for both the driver, as well
as the technician/installer.
Problem: Poor system performance.
Solution: Check to see if the wire/cables are too long. Keep wire/cable to the stepper motor under 25
feet in length. For applications where the wiring from the stepper motor to the stepper driver exceeds
25 feet, please contact the factory for instructions, as it is likely that transient voltage protection devices
will be required. Another possibility is that the stepper motor lead wires are of a gauge that is too small.
Do not match your cable wires to the gauge size the stepper motor lead wires. This is a common mistake,
so Anaheim Automation suggests using its shielded cable for such wiring (purchased separately).
Additionally, check the age of your stepper motor, as with time and use, stepper motors lose some of
their magnetism which affects performance. Typically one can expect 10,000 operating hours for
stepper motors (approximately 4.8 years, running one eight‐hour shift per work day). Also, make certain
that your stepper motor and driver combination is a good match for your application. Contact the
factory, should you have any concerns.
Problem: The stepper motor has a shorted winding or a short to the motor case.
Solution: It is likely that you have a defective stepper motor. Do not attempt to repair motors. Opening
the stepper motor case may de‐magnetize the motor, causing poor performance. Opening of the
stepper motor case will also void your warranty. The motor windings can be tested with an ohmmeter.
As a rule of thumb, if the stepper motor is a frame size of NEMA 08, 11, 14, 15, 17, 23, or 34 and the
warranty period has expired, it is not cost‐effective to return these stepper motors for repair. Contact
the factory if you suspect a defective stepper motor that is still under warranty, or if it is a NEMA 42 or a
K‐series motor.
Problem: The stepper motor driver or Driver Pack is over‐heating.
Solution: Ventilation and cooling accommodations are essential – failure to provide adequate airflow
will affect the stepper motor driver’s performance and will shorten the life of the driver. Keep driver
temperatures below 60 degrees Celsius. To maintain good airflow, use fans, heat sink material, and base
plates, so not to exceed the maximum temperature rating of the stepper motors, drivers or controllers.
Be mindful of temperatures inside cabinets and enclosures where stepper drivers may be mounted.
Note: Painted surfaces do not make good heat sink material for stepper motor drivers and controllers.
Also, be certain that the environment is free from dust and debris that can clog a fan‐cooled system.
Problem: Environmental factors are less than ideal.
Solution: Environmental factors, such as welding, chemical vapors, moisture, humidity, dust, metal
debris, etc., can damage both the electronics and the stepper motor. Protect drivers, controllers and
stepper motors from environments that are corrosive, contain voltage spikes, or prevent good
ventilation. Anaheim Automation offers products in several line voltage ranges, as well as splash‐proof,
IP65 rated stepper motors. For wash‐down or explosion‐proof motors, contact the factory direct. For AC
lines that contain voltage spikes, a line regulator (filter) will likely be required. Note: If your application
requires welding, or if welding is done in the same work environment, contact the factory for advice on
how to protect the stepper motor driver and controller.

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Stepper Motor Basics
Problem: Pulse rates (Clock or Step) to the driver are too high.
Solution: The typical half‐step driver can drive a stepper motor at a maximum rate of 20,000 pulse per
second. Pulse rates of above 60,000 pulses per second can damage the driver. See individual
specification sheets for the motor and driver combination for best performance.
Problem: The stepper motor is stalling.
Solution: In some cases, stalling the stepper motor causes a large voltage spike that often damages the
phase transistors on the driver. Some drivers are designed to protect itself from such an occurrence. If
not, Transient Suppression Devices can be added externally. Consult the factory for further information.
Problem: The stepper motor is back‐driving the stepper driver.
Solution: A stepper motor that is being turned by a load creates a back EMF voltage on the driver.
Higher speeds will produce higher voltage levels. If the rotational speed gets very high, this voltage
might cause damage to the driver. This is especially dangerous when the motor is back‐driven while the
driver is still on. Put a mechanical stop or brake in applications that might be subject to these
phenomena.

NOTE: Please use a RMA Form should you need to return a product for REPAIR. This form can be
found in Support, Forms, RMA Request, on this web site. Never return a product without contacting
Anaheim Automation first! It is advised that a customer contact Anaheim Automation by phone,
email, or a faxed form, prior to returning a product, so that we can assess what would be the most
cost‐effective way to handle the Repair/Return. 714‐992‐6990, phone, or 714‐992‐0471, Fax
Email: info@anaheimautomation.com

General Safety Considerations for Stepper Motor Applications
The following safety considerations must be observed during all phases of operation, service and repair.
Failure to comply with these precautions violates safety standards of design, manufacture, and intended
use of the stepper motor, driver and controller. Anaheim Automation, Inc. assumes no liability for the
customer’s failure to comply with these requirements. Even well designed and perfectly manufactured
products, operated or installed improperly, can be hazardous. Safety precautions must be observed by
the user with respect to the load and operating environment. In all cases, the customer is responsible
for proper selection, installation and operation of the products purchased from Anaheim Automation.

In Summary:
• Use caution when handling, testing, and adjusting during installation, set‐up and operation
• Service should not be performed with power applied
• Exposed circuitry should be properly guarded or enclosed to prevent unauthorized human contact
with live circuitry
• All products should be securely mounted and adequately grounded
• Provide adequate air flow and heat dissipation
• Do not operate in the presence of flammable gases, vapors, liquids or dust

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