+++ title = "Comparison and classification of high-precision actuators based on stiffness influencing vibration isolation" author = ["Dehaeze Thomas"] draft = false +++ Tags : [Vibration Isolation]({{< relref "vibration_isolation.md" >}}), [Actuators]({{< relref "actuators.md" >}}) Reference : (Ito and Schitter 2016) Author(s) : Ito, S., & Schitter, G. Year : 2016 ## Classification of high-precision actuators {#classification-of-high-precision-actuators}
| **Categories** | **Pros** | **Cons** | |----------------|---------------------------|-----------------------------| | Zero stiffness | No vibration transmission | Large and Heavy | | Low stiffness | High vibration isolation | Typically for low load | | High Stiffness | High control bandwidth | High vibration transmission | ## Time Delay of Piezoelectric Electronics {#time-delay-of-piezoelectric-electronics} In this paper, the piezoelectric actuator/electronics adds a time delay which is much higher than the time delay added by the voice coil/electronics. ## Definition of low-stiffness and high-stiffness actuator {#definition-of-low-stiffness-and-high-stiffness-actuator} - **Low Stiffness** actuator is defined as the ones where the transmissibility stays below 0dB at all frequency - **High Stiffness** actuator is defined as the ones where the transmissibility goes above 0dB at some frequency {{< figure src="/ox-hugo/ito16_low_high_stiffness_actuators.png" caption="Figure 1: Definition of low-stiffness and high-stiffness actuator" >}} ## Low-Stiffness / High-Stiffness characteristics {#low-stiffness-high-stiffness-characteristics} - The low stiffness actuators achieve smooth transition from active isolation to passive isolation. - The high stiffness actuators can have a gap between the passive and active isolation vibration where the vibrations are amplified in a certain frequency band. ## Controller Design {#controller-design} {{< figure src="/ox-hugo/ito16_transmissibility.png" caption="Figure 2: Obtained transmissibility" >}} ## Discussion {#discussion} The stiffness requirement for low-stiffness actuators can be rephrased in the frequency domain as: "the cross-over frequency of the sensitivity function of the feedback system must be larger than \\(\sqrt{2} \omega\_r\\) with \\(\omega\_r\\) is the resonant frequency of the uncontrolled system". In practice, this is difficult to achieve with piezoelectric actuators as their first resonant frequency \\(\omega\_r\\) is **too close to other resonant frequencies to ensure close-loop stability**. In contrast, the frequency band between the first and the other resonances of Lorentz actuators can be broad by design making them more suitable to construct a low-stiffness actuators. ## Bibliography {#bibliography}