What Are the Effects of an Excessive Distance Between the Driver and the Stepper Motor?

Effects of an excessive distance between the driver and the stepper motor:

1. Voltage Drop and Reduced Output Torque

• At low speeds: Insufficient torque may occur, potentially failing to drive the load.
• At high speeds: Torque drop is particularly severe, making the motor more prone to stalling (losing steps).

2. Current Waveform Distortion and Edge Degradation

• Slower current rise/fall times: The distributed inductance impedes rapid current changes, causing the rising and falling edges of the current waveform to become sluggish. This prevents the motor winding current from tracking the drive pulses accurately and promptly.
• Additional heating: Both the motor and driver can overheat abnormally due to these ineffective oscillating currents.
• Increased noise: The operational noise of the motor becomes significantly louder.
• Reduced positioning accuracy: Imprecise current control directly affects the accuracy of the step angle.
• Potential driver damage: Severe voltage overshoot could damage the driver's power transistors.

3. Signal Integrity and Electromagnetic Interference (EMI)

• Susceptibility to interference: Long cables act like antennas, making them more susceptible to external electromagnetic interference (e.g., from inverters, relays, power lines). This interference can couple into control signals, causing malfunctions. Simultaneously, high-frequency noise generated on the motor side is more easily conducted through the long cable, affecting the entire system's EMC performance.

4. System Response Delay

• Although electrical signals propagate very quickly, in applications requiring extremely high dynamic response (e.g., high-speed start/stop, precise interpolation), the tiny delay introduced by long cables can become a bottleneck for system control precision.

Methods to Mitigate or Avoid These Effects:

• Use thicker cables: Employ motor cables with a larger cross-sectional area (e.g., 1.0 mm² or above) to effectively reduce resistance and minimize voltage drop.
• Use twisted pairs: The motor power wires (A+, A-, B+, B-) should use twisted pairs (one pair for phase A, one pair for phase B). Twisting significantly reduces the loop area, lowering distributed inductance and the ability to radiate/receive interference.
• Use shielded cables: The shield can effectively block external EMI. The shield should be grounded at both ends (driver and motor), but care must be taken to avoid ground loops. Often, single-point grounding at the driver end is recommended for safety.
• Increase the drive voltage: Raising the drive voltage compensates for the voltage loss over the long cable, thereby speeding up current buildup and improving high-speed performance. This is a very critical measure.
• Shorten power cables, lengthen communication cables: Install the controller remotely and place the driver close to the motor. This keeps the power cables very short, with only the communication bus requiring long-distance transmission, which is far less sensitive to distance than power lines.

Summary: Excessive distance is not recommended. Try to keep the distance within 3 meters. Cable lengths exceeding 3 meters will generally impact performance, depending also on the motor size and slot fill ratio. The guiding principles are: keep cables as short as possible, use thick and high-quality cables, and ensure sufficient drive voltage. When long-distance wiring is unavoidable, increasing the drive voltage is often one of the most effective measures to compensate for performance loss.

Updated on: 26/09/2025