+++ title = "A soft 6-axis active vibration isolator" author = ["Dehaeze Thomas"] draft = false +++ Tags : [Stewart Platforms]({{< relref "stewart_platforms.md" >}}), [Vibration Isolation]({{< relref "vibration_isolation.md" >}}) Reference : (Spanos, Rahman, and Blackwood 1995) Author(s) : Spanos, J., Rahman, Z., & Blackwood, G. Year : 1995 **Stewart Platform** (Figure [1](#figure--fig:spanos95-stewart-platform)): - Voice Coil - Flexible joints (cross-blades) - Force Sensors - Cubic Configuration {{< figure src="/ox-hugo/spanos95_stewart_platform.png" caption="Figure 1: Stewart Platform" >}} Total mass of the paylaod: 30kg Center of gravity is 9cm above the geometry center of the mount (cube's center?). Limitation of the **Decentralized Force Feedback**: - high frequency pole due to internal resonances of the struts - low frequency zero due to the rotational stiffness of the flexible joints After redesign of the struts: - high frequency pole at 4.7kHz - low frequency zero at 2.6Hz but non-minimum phase (not explained). Small viscous damping material in the cross blade flexures made the zero minimum phase again. {{< figure src="/ox-hugo/spanos95_iff_plant.png" caption="Figure 2: Experimentally measured transfer function from voice coil drive voltage to collocated load cell output voltage" >}} The controller used consisted of: - second order low pass filter to gain stabilize the plant at high frequencies and provide steep roll-off - first order lead filter to provide adequate phase margin at the high frequency crossover - first order lag filter to provide adequate phase margin at the low frequency crossover - a first order high pass filter to attenuate the excess gain resulting from the low frequency zero The results in terms of transmissibility are shown in Figure [3](#figure--fig:spanos95-results). {{< figure src="/ox-hugo/spanos95_results.png" caption="Figure 3: Experimentally measured Frobenius norm of the 6-axis transmissibility" >}} ## Bibliography {#bibliography}