Restricted accessResearch articleFirst published online 2026
A spread spectrum and compensation method for magnetoelectric velocity sensors applied to measurement in ultra-low frequency magnetic levitation vibration isolation systems
This paper presents a spectrum expansion and bias compensation method for a magnetoelectric velocity sensor used in low-frequency magnetic levitation vibration isolation systems. To enable accurate measurement in the low-frequency range, a compensation circuit is introduced in series with the sensor, extending its cutoff frequency from 3.9 Hz to 0.3 Hz. To mitigate the zero-drift phenomenon caused by ambient temperature variations, a particle-genetic optimized artificial neural network (PG-ANN) algorithm is developed for bias compensation, effectively reducing the sensor offset to quasi-zero level. A low-frequency magnetic levitation vibration isolation system is further designed using a quasi-zero-stiffness isolator that combines positive and negative stiffness through a reversed magnetic pole structure. This design enhances the magnetic field intensity in the air gap, increases the levitation force to support heavier loads, and reduces the system’s natural frequency to 1 Hz. To suppress low-frequency vibrations, an active control strategy combining absolute velocity feedback and ground feedforward is implemented. Experimental results show that the proposed method reduces vibration transmissibility by more than 30 dB at the natural frequency and achieves less than −40 dB transmissibility at 10 Hz. Comparative testing using sensors before and after spectrum expansion verifies that the proposed method significantly improves the system’s low-frequency isolation performance.
AmerWSAmerTSStarostaR, et al. (2024) Resonance in the cart-pendulum system—an asymptotic approach. Applied Sciences11(23): 11567. https://doi.org/10.3390/app112311567
2.
Chang MyungLEvgenyKVladimirG, et al. (2024) Parametric control of quasi-zero stiffness mechanisms for vibration isolation at near-zero frequencies. Journal of Vibration and Control31(7-8): 1347–1358. https://doi.org/10.1177/10775463241239381
3.
Chang-MyungLEvgenyKVladimirG, et al. (2025) Parametric control of quasi-zero stiffness mechanisms for vibration isolation at near-zero frequencies. Journal of Vibration and Control31(7-8): 1347–1358. https://doi.org/10.1177/10775463241239381
4.
ChenP (2024) Modeling and robust active control of a pneumatic vibration isolator. Journal of Vibration and Control13(11): 1553–1571. https://doi.org/10.1177/1077546307078246
5.
ChoiYGweon (2011) A high-precision dual-servo stage using halbach linear active magnetic bearings. IEEE/ASME Transactions on Mechatronics16(5): 925–931. https://doi.org/10.1109/tmech.2010.2056694
6.
DaneshARSafiallahMPuH, et al. (2024) An isolated frequency compensation technique for ultra-low-power low-noise two-stage OTAs. IEEE Transactions on Circuits and Systems71(1): 6–10. https://doi.org/10.1109/tcsii.2023.3298890
7.
DingBLiXChenS-C, et al. (2023) Modular quasi-zero-stiffness isolator based on compliant constant-force mechanisms for low-frequency vibration isolation. Journal of Vibration and Control30(13-14): 3006–3020. https://doi.org/10.1177/10775463231188160
8.
ErkayaS (2012) Analysis of the vibration characteristics of an experimental mechanical system using neural networks. Journal of Vibration and Control18(13): 2059–2072. https://doi.org/10.1177/1077546311429059
9.
FakhariVChoiSChoC (2015) A new robust adaptive controller for vibration control of active engine mount subjected to large uncertainties. Smart Materials and Structures24(4): 1–10. https://doi.org/10.1088/0964-1726/24/4/045044
10.
GuoZLuCWangY, et al. (2016) Design and experimental research of a temperature compensation system for silicon-on-sapphire pressure sensors. IEEE Sensors Journal17(3): 709–715. https://doi.org/10.1109/jsen.2016.2633324
11.
JureviciusMVekterisVTurlaV, et al. (2019) Investigation of the dynamic efficiency of complex passive low-frequency vibration isolation systems. Journal of Low Frequency Noise, Vibration and Active Control38(2): 608–614. https://doi.org/10.1177/1461348418822230
12.
KaiLDonglangCLizhanZ (2021) Analysis and improvement of zero stiffness magnetic levitation gravity compensator. Micro Motor54(7): 5–10.
13.
KuoPHoseinAFarmanbordaMS (2013) Nonlinear output feedback control of a flexible link using adaptive neural network: stability analysis. Journal of Vibration and Control19(11): 1690–1708. Available at: https://doi.org/10.1177/1077546312445498
14.
LiCGuoZZhenM, et al. (2024) A noncontact rotational speed sensor for bearing cages in a high-temperature and high-speed environment. IEEE Sensors Journal24(14): 22773–22780. https://doi.org/10.1109/jsen.2024.3405793
15.
LiangCZhouYZhangD, et al. (2024) Research on the temperature characteristic of magnetic sensor in the magnetic drift compensation fiber-optic gyroscope. Optik172: 91–96. https://doi.org/10.1016/j.ijleo.2018.07.015
16.
LiuJQiaoBZhangX, et al. (2019) Adaptive vibration control on electrohydraulic shaking table system with an expanded frequency range: theory analysis and experimental study. Mechanical Systems and Signal Processing132: 122–137. https://doi.org/10.1016/j.ymssp.2019.06.024
17.
LiuHMaGMGuoY, et al. (2023) Low cut-off frequency extension and amplitude decoupling analysis in non-contact transient measurement. IEEE Transactions on Instrumentation and Measurement72: 1–9. https://doi.org/10.1109/tim.2023.3314806
18.
MaZZhouRYangQ (2022) Recent advances in quasi-zero stiffness vibration isolation systems. An Overview and Future Possibilities10(9): 813. https://doi.org/10.3390/machines10090813
19.
MoatimidGMAmerTEllabbanY (2024) A novel methodology for a time-delayed controller to prevent nonlinear system oscillations. Journal of Low Frequency Noise, Vibration and Active Control43(1): 525–542. https://doi.org/10.1177/14613484231195276
20.
NyawakoDSReynoldsP (2017) Observer-based controller for floor vibration control with optimization algorithms. Journal of Vibration and Control23(3): 345–360. https://doi.org/10.1177/1077546315581229
21.
RenMXieXZhangZ (2023) Subband reinforced adaptive feedback control algorithm in mechanical vibration control. Journal of Vibration and Control29(3–4): 736–745. Available at: https://doi.org/10.1177/10775463211051451
22.
SalviaJCMelamudRChandorkarSA, et al. (2010) Real-time temperature compensation of MEMS oscillators using a nintegrated micro-oven and a phase-locked loop. Micro electro mech. Syst19(1): 192–201. https://doi.org/10.1109/jmems.2009.2035932
23.
TerasavaTSanoA (2005) Fully adaptive vibration control for uncertain structure installed with MR damper. American Control Conference7: 4753–4759.
24.
ValeevA (2018) Dynamics of a group of quasi-zero stiffness vibration isolators with slightly different parameters. Journal of Low Frequency Noise, Vibration and Active Control37(3): 640–653. https://doi.org/10.1177/1461348418756022
25.
WangHYuKZhaoR, et al. (2024) Study on the effect of nonlinear inertia on the vibration isolation performance of quasi-zero-stiffness isolators. Journal of Vibration and Control31(17-18): 3705–3718. https://doi.org/10.1177/10775463241276022
26.
WangQJinYTianF, et al. (2026a) Parameter patterns of an AMB-flexible rotor in linear operatingconditions. Nonlinear Dynamics114: 108. https://doi.org/10.1007/s11071-025-11905-7
27.
WangQTianFJinY, et al. (2026b) Vibration control of flexible rotors based on modeling of magnetic saturation and full-dimensional observers. Science China Technological Sciences59(2): 184–198.
28.
WuTChenSWuP, et al. (2019) A high precision software compensation algorithm for silicon piezoresistive pressure sensor. Chinese Journal of Electronics28(4): 748–753. https://doi.org/10.1049/cje.2019.05.001
29.
WuQLiuZAnF, et al. (2024) Self-tuning PID feedback control method for magnetic suspension active vibration isolation system with parameters uncertainty. Journal of Vibration and Control31(3-4): 431–443. https://doi.org/10.1177/10775463241228018
30.
XiaoFWangXChengY, et al. (2025) A dynamic temperature compensation method for micro electromagnetic force load cell. IEEE Sensors Journal25(19): 35844–35852. https://doi.org/10.1109/jsen.2025.3598735
31.
XuDYangZZhaoH, et al. (2016) A temperature compensation method for MEMS accelerometer based on LM-BP neural network. IEEE SENSORS10: 1–3.
32.
YabuiSSuzukiMFukazawaS, et al. (2024) Compensation for low-frequency vibration in lateral control of truck by adaptive feed-forward cancellation. Journal of Vibration and Control30(9-10): 2083–2092. https://doi.org/10.1177/10775463231174681
33.
YadavKPNarayanJRK (2025) Robust control approach for a nonlinear 2-DOF quasi-zero stiffness vibration isolator. Journal of Vibration and Control. Available at: https://doi.org/10.1177/10775463251382097.
34.
YuanJJinGYeT, et al. (2024) Theoretical modeling and analysis of a quasi-zero-stiffness vibration isolator equipped with extensible and axially magnetized negative stiffness modules. Journal of Vibration and Control13(11): 1553–1571.
35.
ZhangHKouBQJinYX, et al. (2015) Modeling and analysis of a new cylindrical magnetic levitation gravity compensator with low stiffness for the 6-DOF fine stage. IEEE Transactions on Industrial Electronics62(6): 3629-3639.
36.
ZhaoBShiWSunD, et al. (2021) Compensation network for temperature dependency and bandwidth expanding of magnetoelectric velocity sensor based on phase prediction compensator. IEEE Sensors Journal21(2): 1704–1714. https://doi.org/10.1109/jsen.2020.3016224
37.
ZhengHQinHRenM, et al. (2024) Active vibration control for the time-varying systems with a new adaptive algorithm. Journal of Vibration and Control30(1–2): 237–249.
38.
ZhengYZhangXMaC, et al. (2016) An ultra-low frequency pendulum isolator using a negative stiffness magnetic spring. International Journal of Applied Electromagnetics and Mechanics52(2016): 1313–1320. https://doi.org/10.3233/jae-162161
39.
ZhengHQinHRenM, et al. (2020) Active vibration control for the time-varying systems with a new adaptive algorithm. Journal of Vibration and Control26(3-4): 200–213. https://doi.org/10.1177/1077546319878297
40.
ZhongJLiJDingB, et al. (2024) Design and experimental verification of programmable metastructures based on constant force cells. Smart Materials and Structures34: 015002. https://doi.org/10.1088/1361-665x/ad95cd
41.
ZhouZChenSXiaD, et al. (2019) The design of negative stiffness spring for precision vibration isolation using axially magnetized permanent magnet rings. Journal of Vibration and Control25(19-20): 2667–2677. https://doi.org/10.1177/1077546319866035
42.
ZhuYLiQXuD, et al. (2012) Modeling of axial magnetic force and stiffness of ring-shaped permanent-magnet passive vibration isolator and its vibration isolating experiment. IEEE Transactions on Magnetics48(7): 2228–2238.
