Absolute displacement measurement using an inertial reference generated by linearised electromagnetic levitation

This paper proposes a novel passive absolute displacement measurement system (ADMS) utilising the electromagnetic levitation approach, instead of any mechanical spring. The most distinctive feature of the proposed ADMS is its measuring amplitude range of 30 mu m- 1.2 mm with a lower frequency limit of 2 Hz. Consequently, a wider measuring bandwidth and higher measurement accuracy for absolute displacement signals can be realised without feedback/serve-type inertia sensors, which are usually expensive and vulnerable. Both features make the proposed system promising for of low-frequency measurement applications, such as precision vibration isolation of optical platforms in vibrational environments, anti-shake UAV platforms, monitoring of seismic wave signals, ship equipment protection and safety inspection of long-span bridges. First, the principles of the proposed ADMS are introduced. Subsequently, the measuring performance of the proposed ADMS is simulated and analysed. Finally, a prototype of the ADMS is constructed and tested. The experimental results confirm the validity of the proposed ADMS design and demonstrate its capability to measure the absolute displacement with a low-frequency and wider amplitude range.

Automated summary

This paper proposes a novel passive absolute displacement measurement system (ADMS) that utilizes the electromagnetic levitation approach. The system has a measuring amplitude range of 30 mu m- 1.2 mm with a lower frequency limit of 2 Hz. This enables a wider measuring bandwidth and higher measurement accuracy without the need for expensive and vulnerable feedback/serve-type inertia sensors. The system has promising applications in low-frequency measurements such as precision vibration isolation, anti-shake UAV platforms, seismic wave signal monitoring, ship equipment protection, and safety inspection of long-span bridges.