Motor|Basic
Driving 2-Phase Bipolar Stepping Motors: Part 1
2023.01.12
Points of this article
・A 2-phase bipolar stepping motor can be driven by using two channels, each employing an H bridge driving circuit.
・When driving a 2-phase bipolar stepping motor, current regeneration modes include Slow Decay, Fast Decay, and Mix Decay.
In succession to the basic stepping motor characteristics described in the previous article, stepping motor driving is here explained. Driving is explained separately for a 2-phase bipolar stepping motor and for a 2-phase unipolar stepping motor; in this article, driving of a 2-phase bipolar stepping motor is addressed.
Driving 2-Phase Bipolar Stepping Motors: Driving Circuits
We begin with a basic block diagram of a 2-phase bipolar driving circuit example.
The 2-phase bipolar stepping motor can be driven by using 2 channels of the H-bridge drive circuit. This block diagram is an example of a circuit that uses PWM operation for constant-current driving; operation is basically the same as in?“Driving Brushed DC Motors Using PWM Output”.
There are two current regeneration modes, Slow Decay and Fast Decay, during which the motor current attenuates. Depending on the mode, current tracking may be poor, resulting in vibrations and noise. To deal with this, there are drivers equipped with a mix decay function for externally adjusting the ratio of Slow Decay to Fast Decay. Current regeneration modes will be explained in more detail in Part 2.
Below are shown waveforms for driving a 2-phase bipolar stepping motor with two-phase excitation (Slow Decay), 1-2 phase excitation (2-phase full torque, Slow Decay), 1-2 phase excitation (2-phase torque = single-phase torque, Slow Decay), and 1/4-step excitation (Slow Decay). What should be noted here are the relations between the input signals INxx and output voltages OUTxx and the output currents, as well as the number of steps. Steps can be made finer when using 1/4-step excitation, and currents also change more gradually, so that the motor can be rotated smoothly.
Next, the Slow Decay and Fast Decay current regeneration modes, as well as Mix Decay, will be explained.
【Download Documents】 Basics of Stepping Motors and Driving Methods
Stepping motors are used in various devices and equipment, and there are many types of equipment that cannot function without stepping motors. This handbook presents the fundamentals of stepping motors, explaining their structure, principles of operation, characteristics, and driving methods.
Motor
Basic
-
Brushed DC Motor
- Construction of Brushed Motors
- Principle of Rotation
- Power Generation Principle
- Short Braking
- Characteristics of Brushed DC Motors
- Driving Brushed DC Motors with an H-Bridge:Principles
- Driving Brushed DC Motors with an H-Bridge:Switching Output States
- Driving Brushed DC Motors with an H-Bridge:High-Side Voltage Linear Control
- Driving of Brushed DC Motors Using BTL Amplifier Circuits: Linear Voltage Driving
- Driving of Brushed DC Motors Using BTL Amplifier Circuits: Linear Current Driving
- Driving Brushed DC Motors Using PWM Output: Principles of PWM Driving
- Driving Brushed DC Motors Using PWM Output: Current Regeneration Methods in PWM Driving
- Driving Brushed DC Motors Using PWM Output: Losses and Points to be Noted
- Driving Brushed DC Motors Using PWM Output: PWM Driving with an H-Bridge Circuit
- Driving Brushed DC Motors Using PWM Output: H Bridge Constant-Current Driving
- Driving Brushed DC Motors Using PWM Output: Driving in the Form of BTL Amplifier Input
- Single-Switch Circuit Driving and Half-Bridge Circuit Driving
- Driving Circuits for Brushed DC Motors – Summary
-
Stepping Motors
- Structure of Stepping Motors
- Basic Operating Principles of Stepping Motors
- Stepping Motors: Microstep Operation Principles
- Basic Characteristics of Stepping Motors
- Structure and Operating Principles of Hybrid Type Stepping Motors
- Stepping Motor Driving: Bipolar Connections and Unipolar Connections
- Driving 2-Phase Bipolar Stepping Motors: Part 1
- Driving 2-Phase Bipolar Stepping Motors: Part 2
- Driving 2-Phase Unipolar Stepping Motors
- Stepping Motors – Summary
-
3-Phase Brushless Motors
- Structure of 3-Phase Full-Wave Brushless Motors
- Principles of Rotation of 3-Phase Full-Wave Brushless Motors
- Position Detection in 3-Phase Full-Wave Brushless Motors
- Driving 3-Phase Full-Wave Brushless Motors: 120° Commutation Linear-Current Driving with Sensors
- Driving 3-Phase Full-Wave Brushless Motors: Sinusoidal Commutation PWM Driving with Sensors
- Driving 3-Phase Full-Wave Brushless Motors: Advance Angle Control
- Driving 3-Phase Full-Wave Brushless Motors: Maximization of Motor-Applied Voltage
- Driving 3-Phase Full-Wave Brushless Motors: Sensorless 120° Commutation Driving
- Methods of Sensorless 120° Commutation Driving Startup 1: Startup on Detection of Induced Voltage from Synchronous Operation
- Methods of Sensorless 120° Commutation Driving Startup 2: Startup on Detection of Permanent Magnet Stopped Position
- Features and Applications of 3-Phase Full-Wave Brushless Motors ーSummaryー
- What is a Motor?