Integration of Thin Film Strain Sensors Into Hard Drives for Active Feedback Vibration Suppression

Felix, Sarah; Horowitz, Roberto

doi:10.1109/jsen.2012.2235177

Cited by 3 publications

(2 citation statements)

References 32 publications

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“…The peak stress of 6.64 MPa, 4.98 MPa, and 4.56 MPa were observed in the hexagonal MPS, kirigami MPS, and CPS, respectively. It is worth mentioning that these stress values are sufficiently below the yield strength of both PVDF and PC (30-80 MPa) [46][47][48]. The membrane/MetaMem transfers the stress of the applied bending over the PVDF.…”

Section: 𝜁 =mentioning

confidence: 99%

MetaMembranes for the Sensitivity Enhancement of Wearable Piezoelectric MetaSensors

Farhangdoust

Georgeson

Ihn

2022

Sensors

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The low stretchability of plain membranes restricts the sensitivity of conventional diaphragm-based pressure and inflatable piezoelectric sensors. Using theoretical and computational tools, we characterized current limitations and explored metamaterial-inspired membranes (MetaMems) to resolve these issues. This paper develops two MetaMem pressure sensors (MPSs) to enrich the sensitivity and stretchability of the conventional sensors. Two auxetic hexagonal and kirigami honeycombs are proposed to create a negative Poisson’s ratio (NPR) in the MetaMems which enables them to expand the piezo-element of sensors in both longitudinal and transverse directions much better, and consequently provides the MPSs’ diaphragm a higher capability for flexural deformation. Polyvinylidene fluoride (PVDF) and polycarbonate (PC) are considered as the preferable materials for the piezo-element and MetaMem, respectively. A finite element analysis was conducted to investigate the stretchability behavior of the MetaMems and study its effect on the PVDF’s polarization and sensor sensitivity. The results obtained from theoretical analysis and numerical simulations demonstrate that the proposed MetaMems enhance the sensitivity of pressure sensors up to 3.8 times more than an equivalent conventional sensor with a plain membrane. This paper introduces a new class of flexible MetaMems to advance wearable piezoelectric metasensor technologies.

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Section: 𝜁 =mentioning

confidence: 99%

MetaMembranes for the Sensitivity Enhancement of Wearable Piezoelectric MetaSensors

Farhangdoust

Georgeson

Ihn

2022

Sensors

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“…The piezoelectric cantilever beams are critical in designing intelligent systems [1][2][3] as the primary structure of sensors. The cantilever beam structures [4], characterized by wide operating bandwidth, lightweight, powerful driving force, and high electromechanical conversion efficiency, have been used in the fields of micrometer/nanomechanical systems [5][6][7], server hard disk failure detection [8,9] and controller model validation [10,11]. Therefore, the modeling analysis and dynamic motion behavior of piezoelectric cantilever beams have attracted significant works in the literature [12,13].…”

Section: Introductionmentioning

confidence: 99%

Electric-Force Conversion Performance of Si-Based LiNbO3 Devices Based on Four Cantilever Beams

Zhang,

Qiao,

Wei

et al. 2023

Micromachines

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In micron or nano smart sensing systems, piezoelectric cantilever beams are distributed as major components in microsensors, actuators, and energy harvesters. This paper investigates the performance of four cantilever beam devices with “electric-force” conversion based on the inverse piezoelectric effect of lithium niobate (LiNbO3, LN) single-crystal materials. A new compact piezoelectric smart device model is proposed, designed as a single mass block connected by four beams, where devices exhibit smaller lateral errors (0.39–0.41%). The relationship between the displacement characteristics of cantilever beams and driving voltage was researched by applying excitation signals. The results show that the device has the maximum displacement at a first-order intrinsic frequency (fosc = 11.338 kHz), while the displacement shows a good linear relationship (R2 = 0.998) with driving voltage. The square wave signals of the same amplitude have greater “electrical-force” conversion efficiency. The output displacement can reach 12 nm, which is much higher than the output displacement with sinusoidal excitation. In addition, the relative displacement deviation of devices can be maintained within ±1% under multiple cycles of electrical signal loading. The small size, high reliability, and ultra-stability of Si–LN ferroelectric single-crystal cantilever beam devices with lower vibration amplitudes are promising for nanopositioning techniques in microscopy, diagnostics, and high-precision manufacturing applications.

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Temperature Effects on a Simplified Self-Sensing Actuation Circuit for PZT Micro-Actuator in HDDs

Sengchuai

Panyavoravaj²,

Jindapetch

2019

IEEE Sensors J.

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Integration of Thin Film Strain Sensors Into Hard Drives for Active Feedback Vibration Suppression

Cited by 3 publications

References 32 publications

MetaMembranes for the Sensitivity Enhancement of Wearable Piezoelectric MetaSensors

MetaMembranes for the Sensitivity Enhancement of Wearable Piezoelectric MetaSensors

Electric-Force Conversion Performance of Si-Based LiNbO3 Devices Based on Four Cantilever Beams

Temperature Effects on a Simplified Self-Sensing Actuation Circuit for PZT Micro-Actuator in HDDs

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