Submitted:
28 June 2026
Posted:
29 June 2026
You are already at the latest version
Abstract
Keywords:
1. Introduction
2. Physical and Mathematical Model of the Active Horizontal Seat Suspension
3. Active Vibration Control with Energy Regenerative Braking
- changing the direct component is responsible for setting the magnetic flux,
- adjusting the quadrature component is responsible for controlling the motor torque.
4. Hardware Implementation
5. System Identification
6. Laboratory Experimental Results
7. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
Appendix A. Numerical Parameters of the BLDC Motor and Its Braking Subsystem
| Model parameters | Numerical values |
| amplitude of a flux induced by permanent magnets () | |
| first controller setting () | 7 |
| second controller setting () | 20 |
| ratio between maximum braking force and maximum | |
| active force () | |
| torque constant of a motor () | |
| inductance of a motor () | |
| length of the lever arm () | |
| number of pole pairs (p) | 3 |
| resistance of a motor () |
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| Mass load | ||||||
|---|---|---|---|---|---|---|
| Passive | Active | Regenerative | ||||
| Excitation | SEAT | Suspension | SEAT | Suspension | SEAT | Suspension |
| signal | factor | travel | factor | travel | factor | travel |
| Mass load 40 kg | ||||||
| WN1 | 1.172 | 22.5 mm | 0.501 | 35.8 mm | 0.886 | 36.3 mm |
| WN2 | 1.178 | 29.5 mm | 0.536 | 39.1 mm | 0.885 | 33.2 mm |
| WN3 | 1.186 | 34.3 mm | 0.609 | 39.1 mm | 0.936 | 40.1 mm |
| Mass load 60 kg | ||||||
| WN1 | 1.123 | 26.3 mm | 0.507 | 35.9 mm | 0.845 | 36.9 mm |
| WN2 | 1.145 | 34.3 mm | 0.551 | 40.5 mm | 0.894 | 38.5 mm |
| WN3 | 1.186 | 38.4 mm | 0.637 | 40.2 mm | 0.953 | 41.0 mm |
| Mass load 80 kg | ||||||
| WN1 | 1.095 | 30.0 mm | 0.501 | 37.6 mm | 0.832 | 35.5 mm |
| WN2 | 1.132 | 37.1 mm | 0.563 | 40.8 mm | 0.927 | 39.3 mm |
| WN3 | 1.179 | 40.5 mm | 0.669 | 40.7 mm | 0.975 | 41.5 mm |
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