Motor Control Terminology

A

AC Induction Motor (ACIM)
ACIM have windings on the rotor, but the rotor does not draw current from a physical connection. The rotor current is induced by a rotating stator field. Surrounded by the stator field, the induced rotor current results in a mechanical force moving the rotor (Faraday's Law of Induction). An ACIM is classified as an asynchronous motor because the rotor's motion may not keep up with the stator field's rotation. The difference between the rotor and the stator field is called "slip."
AC Motor
Alternate Current (AC) Motors are motors in which a variable current flows through the stator. The current variations can be in a series of smooth sinusoidal cycles or can occur in abrupt digital transitions. Rotation of an AC motor is caused by sequencing the current cycles among the individual stator windings. Depending upon the material used to make the rotor, the rotor will be drawn toward an activated winding by either magnetic attraction or magnetic reluctance. The speed of an AC motor's rotation is dependent upon the speed in which the current changes are sequenced through the stator windings.
Air Gap
Air Gap refers to the distance between the rotor and the stator. The amount of current needed to influence a motor's magnetic field is directly dependent upon the size of the air gap. Motors with larger air gaps consume more current than motors with smaller air gaps. If the air gap is too small, the variances in the magnetic field will overcome the stiffness of the drive shaft causing the rotor to bump against the stator as it rotates.
Asynchronous Motor
Asynchronous Motors are Alternating Current (AC) motors designed such that the rotor movement is not synchronized with the moving stator field. An asynchronous motor's rotating stator field induces a current in the rotor windings. This induced current, in turn, generates a force, drawing the rotor toward the stator. In an asynchronous motor, torque is only generated when the rotor is not in phase with the stator. If the rotor were to become aligned with the stator field, the torque would disappear, thus, causing the rotor to pause. The stator field basically pulls the rotor. This lag between the stator and the rotor is commonly referred to as a "slip."

B

Brushless DC Motor (BLDC)
A Brushless DC Motor (BLDC) is a synchronous electric motor driven by a DC current supplied through an inverter or switching power source, which supplies a bi-directional AC current to each drive phase of the motor. The generated AC input does not need to be a smooth sinusoidal signal, but it must be periodic. The period of the input determines the speed of the motor.
Brushed DC Motor
A Brushed DC Motor is an internally commutated electric motor designed to be run from a direct current power source. The stator provides a permanent magnetic field. A current going through the rotor induces a mechanical force causing the rotor to commutate. The current is supplied to the rotor through a mechanical connection or "brush." Changing the rotor current or the stator field will alter the speed of the motor.

C

Commutation
Commutation is the action needed to induce motor in a motor. In an AC motor, commutation is achieved by sequentially switching current in the phases. In Brushless DC motors, commutation is self-induced as the rotor motion causes the motor to commutate.

D

DC Motor
Direct Current (DC) Motors are motors in which the rotor is activated by a steady current. The force causing the rotation in a DC motor is caused by the interaction of the rotor current with the stator's magnetic field. The speed of the motor's rotation is a function of the amount of current flowing through the stator.

R

Rotor
The Rotor is the portion of the motor that rotates in an electric motor. The rotor is attached to the drive shaft and interacts with the stator.

S

Stator
The Stator is the stationary portion of an electric motor.
Stepper Motor
A Stepper Motor is a DC motor that moves in discrete steps. The coils are organized into phases. When the phases are energized in sequence the motor will rotate in precise increments.
Synchronous Motor
Synchronous Motors are Alternating Current (AC) motors in which the rotor maintains the same frequency and phase as the rotating stator field.
Switched Reluctance Motors
Switched Reluctance Motors have a stator design similar to a BLDC Motor. The rotor in a switched reluctance motor is made up of soft iron laminates rather than the permanent magnets of a BLDC motor. Torque is created by the attraction of the electromagnetic stator and the iron rotor. Not commonly used because this motor type can be subject to torque ripple.

T

Torque
Torque is the measure of how much force is acting on a motor to make it rotate. Typically defined in terms of Newton-Meters (N m), torque (𝜏) is a calculation of the amount of force (F) asserted on the motor and the distance (r) from the fulcrum in which the force is asserted.
Torque Ripple
Torque Ripple is the variance in a motor's torque as the rotor moves through the stator windings. Quantified as a percent of change in a motor's power output, torque ripple can be of significant concern in applications where a smoothly operating motor is essential. Motors with excessive torque ripple will experience vibration and may emit audible noise.
© 2024 Microchip Technology, Inc.
Notice: ARM and Cortex are the registered trademarks of ARM Limited in the EU and other countries.
Information contained on this site regarding device applications and the like is provided only for your convenience and may be superseded by updates. It is your responsibility to ensure that your application meets with your specifications. MICROCHIP MAKES NO REPRESENTATIONS OR WARRANTIES OF ANY KIND WHETHER EXPRESS OR IMPLIED, WRITTEN OR ORAL, STATUTORY OR OTHERWISE, RELATED TO THE INFORMATION, INCLUDING BUT NOT LIMITED TO ITS CONDITION, QUALITY, PERFORMANCE, MERCHANTABILITY OR FITNESS FOR PURPOSE. Microchip disclaims all liability arising from this information and its use. Use of Microchip devices in life support and/or safety applications is entirely at the buyer's risk, and the buyer agrees to defend, indemnify and hold harmless Microchip from any and all damages, claims, suits, or expenses resulting from such use. No licenses are conveyed, implicitly or otherwise, under any Microchip intellectual property rights.