Your search keyword '"vibrometry"' showing total 251 results

1. Challenges and Opportunities in Vibrometry‑Based Online Condition Monitoring of Mineral Processing Equipment

Author

Mishra, S. and Majumder, Arun Kumar

Published

2024

2. In-vivo sensing of the vibrations and thickness of the human tympanum with real-time profilometry using low-cost line-field spectral domain optical coherence tomography.

Author

George, Denny Melkay M, Nandakumar, Hari, Koushik, V, Josyula, Sai Prashanth, Chettri, Prajal, and Srivastava, Shailesh

Subjects

*OPTICAL coherence tomography, *MIDDLE ear, *TYMPANIC membrane

Abstract

In middle ear ailments, the thickness of tympanic membrane (TM) could change due to biofilm depositions. It is useful to measure the vibrations of the TM as well as its thickness and curvature. In the presence of unavoidable human motion, this becomes challenging and requires the use of expensive devices. We demonstrate a low-cost method for measuring these in real-time using a custom-built line-field spectral-domain optical coherence tomography device. Linearity of the amplitude response of the TM as well as its frequency response over the 1–2.5 kHz region is demonstrated. While an in-vivo sensitivity of 2 nm is achieved for the TM, a sensitivity of 200 pm is demonstrated on a membrane phantom. Our device enables a depth range of 6.2 mm using a line-field B-scan that covers a lateral extent of 3 mm with a lateral and depth resolution of 18 µm each. [ABSTRACT FROM AUTHOR]

Published

2024

3. Vibrometry as a noncontact alternative to dynamic and viscoelastic mechanical testing in cartilage

Author

Espinosa, M Gabriela, Otarola, Gaston A, Hu, Jerry C, and Athanasiou, Kyriacos A

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Engineering, Biomedical Engineering, Control Engineering, Mechatronics and Robotics, Arthritis, Bioengineering, Musculoskeletal, Biomechanical Phenomena, Bone and Bones, Cartilage, Articular, Elasticity, Knee Joint, Mechanical Tests, Stress, Mechanical, Viscosity, vibrometry, dynamic modulus, viscoelasticity, storage modulus, loss modulus, cartilage, General Science & Technology

Abstract

Physiological loading of knee cartilage is highly dynamic and may contribute to the progression of osteoarthritis. Thus, an understanding of cartilage's dynamic mechanical properties is crucial in cartilage research. In this study, vibrometry was used as a fast (2 h), noncontact and novel alternative to the slower (30 h), traditional mechanical and biochemical assays for characterization of cartilage from the condyle, patella, trochlear groove and meniscus. Finite-element models predicted tissue resonant frequencies and bending modes, which strongly correlated with experiments (R2 = 0.93). Vibrometry-based viscoelastic properties significantly correlated with moduli from stress relaxation and creep tests, with correlation strengths reaching up to 0.78. Loss modulus also strongly correlated with glycosoaminoglycan (GAG) content. Dynamic properties measured by vibrometry significantly differed among various knee cartilages, ranging between 6.1 and 56.4 MPa. Interestingly, meniscus viscoelastic properties suggest that contrary to common belief, it may lack shock absorption abilities; instead, condylar hyaline cartilage may be a better shock absorber. These data demonstrate for the first time that vibrometry is a noncontact approach to dynamic mechanical characterization of hyaline and fibrocartilage cartilage with concrete relationships to standard quasi-static mechanical testing and biochemical composition. Thus, with a single tool, vibrometry greatly facilitates meeting multiple regulatory recommendations for mechanical characterization of cartilage replacements.

Published

2021

4. Defect Detection in Carbon Fiber-Reinforced Plate by Imaging of Mechanical Nonlinearity-Induced Sideband Vibrations

Author

Tommaso Seresini, Sevilia Sunetchiieva, Helge Pfeiffer, Martine Wevers, and Christ Glorieux

Subjects

nondestructive testing, NDT, nonlinear acoustics, vibrometry, photorefractive optics, carbon fiber, Physics, QC1-999

Abstract

Laser Doppler scanning vibrometry is used for imaging spectral vibration components in a carbon fiber-reinforced composite plate that contains a sub-surface delamination defect caused by hammer impact. The images reveal sideband generation at the location of the defect, reflecting mechanical nonlinearity-induced mixing between a high amplitude, low-frequency vibration that modulates the stress–strain behavior near the defect and a low amplitude, high-frequency probe vibration. In this work, a multifrequency probe is used to tackle the problem that the mixing coefficients are, in practice, frequency dependent. Based on the measured sideband amplitudes, a study is presented on the expected feasibility of detecting defects by a full field imaging scheme based on a photorefractive interferometer that is configured as a vibrometer acting as a bandpass filter around a sideband frequency of interest.

Published

2023

5. Introduction to Multipath Doppler Vibrometry (MDV) for Validating Complex Models Accurately and Without Contact

Author

Eichenberger, Jerome, Sauer, Joerg, Di Maio, Dario, editor, and Baqersad, Javad, editor

Published

2023

6. Modeling a Fluid-Coupled Single Piezoelectric Micromachined Ultrasonic Transducer Using the Finite Difference Method.

Author

Goepfert, Valentin, Boulmé, Audren, Levassort, Franck, Merrien, Tony, Rouffaud, Rémi, and Certon, Dominique

Subjects

FINITE difference method, ULTRASONIC transducers, EQUATIONS of motion, GREEN'S functions, FINITE differences

Abstract

A complete model was developed to simulate the behavior of a circular clamped axisymmetric fluid-coupled Piezoelectric Micromachined Ultrasonic Transducer (PMUT). Combining Finite Difference and Boundary Element Matrix (FD-BEM), this model is based on the discretization of the partial differential equation used to translate the mechanical behavior of a PMUT. In the model, both the axial and the transverse displacements are preserved in the equation of motion and used to properly define the neutral line position. To introduce fluid coupling, a Green's function dedicated to axisymmetric circular radiating sources is employed. The resolution of the behavioral equations is used to establish the equivalent electroacoustic circuit of a PMUT that preserves the average particular velocity, the mechanical power, and the acoustic power. Particular consideration is given to verifying the validity of certain assumptions that are usually made across various steps of previously reported analytical models. In this framework, the advantages of the membrane discretization performed in the FD-BEM model are highlighted through accurate simulations of the first vibration mode and especially the cutoff frequency that many other models do not predict. This high cutoff frequency corresponds to cases where the spatial average velocity of the plate is null and is of great importance for PMUT design because it defines the upper limit above which the device is considered to be mechanically blocked. These modeling results are compared with electrical and dynamic membrane displacement measurements of AlN-based (500 nm thick) PMUTs in air and fluid. The first resonance frequency confrontation showed a maximum relative error of 1.13% between the FD model and Finite Element Method (FEM). Moreover, the model perfectly predicts displacement amplitudes when PMUT vibrates in a fluid, with less than 5% relative error. Displacement amplitudes of 16 nm and 20 nm were measured for PMUT with 340 µm and 275 µm diameters, respectively. This complete PMUT model using the FD-BEM approach is shown to be very efficient in terms of computation time and accuracy. [ABSTRACT FROM AUTHOR]

Published

2023

7. Validating Complex Models Accurately and Without Contact Using Scanning Laser Doppler Vibrometry (SLDV)

Author

Eichenberger, Jerome, Sauer, Joerg, Zimmerman, Kristin B., Series Editor, Di Maio, Dario, editor, and Baqersad, Javad, editor

Published

2022

8. A Rapid Method to Noninvasively Measure the Viscoelastic Properties of Synthetic Polymers Using Mechanical Vibrations and Photonics.

Author

Silver, Frederick H., Gonzalez-Mercedes, Michael, and Mesica, Arielle

Subjects

VIBRATION (Mechanics), ACOUSTIC vibrations, OPTICAL coherence tomography, BIOPOLYMERS, POLYMERS

Abstract

Noninvasive measurement of the viscoelastic properties of both natural and synthetic polymers is important for the analysis of implant design and performance as well as in industrial material development. In this study, we used vibrational optical coherence tomography (VOCT) to compare the elastic and viscoelastic properties of silicone polymers with standard tensile stress–strain measurements. VOCT uses acoustic vibrations and infrared light to measure the resonant frequency of viscoelastic materials. The elastic modulus was calculated from the in-phase deformation of the material at fixed frequencies using an empirical calibration curve. Viscous loss was measured after pulsing the samples based on the ratio of mechanovibrational peak widths to heights. The results showed that the optimal cure time and modulus values obtained using VOCT were like those obtained using conventional tensile testing. VOCT could capture results that were comparable to conventional testing while not destroying the material, suggesting its usefulness for in vivo and in situ measurements as well as for early quality control environments during end-use application and fabrication experiments. We conclude that VOCT is a new technique that is comparable to conventional testing for noninvasively and nondestructively measuring the viscoelastic properties of polymers. [ABSTRACT FROM AUTHOR]

Published

2022

9. Sound Induced Vibrations Deform the Organ of Corti Complex in the Low-Frequency Apical Region of the Gerbil Cochlea for Normal Hearing: Sound Induced Vibrations Deform the Organ of Corti Complex.

Author

Meenderink, Sebastiaan W. F., Lin, Xiaohui, Park, B. Hyle, and Dong, Wei

Abstract

Human speech primarily contains low frequencies. It is well established that such frequencies maximally excite the cochlea near its apex. But, the micromechanics that precede and are involved in this transduction are not well understood. We measured vibrations from the low-frequency, second turn in intact gerbil cochleae using optical coherence tomography (OCT). The data were used to create spatial maps that detail the sound-evoked motions across the sensory organ of Corti complex (OCC). These maps were remarkably similar across animals and showed little variation with frequency or level. We identify four, anatomically distinct, response regions within the OCC: the basilar membrane (BM), the outer hair cells (OHC), the lateral compartment (lc), and the tectorial membrane (TM). Results provide evidence that active processes in the OHC play an important role in the mechanical interplay between different OCC structures which increases the amplitude and tuning sharpness of the traveling wave. The angle between the OCT beam and the OCC makes that we captured radial motions thought to be the effective stimulus to the mechano-sensitive hair bundles. We found that TM responses were relatively weak, arguing against a role in enhancing mechanical hair bundle deflection. Rather, BM responses were found to closely resemble the frequency selectivity and sensitivity found in auditory nerve fibers (ANF) that innervate the low-frequency cochlea. [ABSTRACT FROM AUTHOR]

Published

2022

10. Guided wave evaluation of pipes using the first and second order torsional wave mode

Author

Deere, Matthew and Wrobel, L.

Subjects

620.1, Ultrasonic, Defect, sizing, Fea, Vibrometry

Abstract

Guided wave inspection is a form of ultrasonic testing used for non-destructive testing (NDT). Guided waves are capable of propagating long distances bounded by the geometries of the specimen, such as pipes and plates. The technique is commercially used to detect defects in pipelines and is capable of a full volumetric screening many metres (often up to around 100m) from one location. Fundamental axisymmetric wave modes are used to inspect pipelines and are used to quantify defects and features. However, as the technology has progressed, a demand for improving defect sensitivity, spatial resolution and developing the technology into new fields has been recognised. Operating at medium range frequencies is one possibility that could provide the increase in defect sensitivity and spatial resolution required that may not be achieved at low range frequencies. The use of higher order wave modes could also provide additional information useful for defect sizing. Guided wave inspection is a complex ultrasonic technique due to the many wave modes that exist and testing at medium range frequencies requires some challenges to be overcome. The research presented here investigates the potential of using the second order torsional wave mode at medium range frequencies and provides a new sizing technique that for some applications is likely to offer advancement in guided wave inspection and monitoring. The approach firstly included the design and implementation of a setup for analysing the complex signal responses in order to access the higher order torsional wave mode T(0,2) for defect sizing. An efficient method of using FEA has been presented using segmented models to provide the capability of analysing defects with small increment changes that could not be achieved using a full 3D model of the pipe. Using a pipe segment to virtually represent the full pipe also allowed small changes in defect size to be investigated, which would otherwise be extremely difficult to accurately machine experimentally. The FEA modelling technique is also based on broadband signals in comparison to the conventional approach of using narrowband signals and is capable of obtaining a wide frequency spectrum from one model, which significantly reduces the number of models needed to conduct a frequency analysis. Following on from this work, a high density transducer array was developed and compared against a conventional transducer array used in guided wave inspection for the purpose of medium range frequency inspection, which can also be applied to conventional low range frequency inspection. Finally, a new defect sizing method using T(0,2) is presented, which is capable of predicting the depth using peak amplitude responses from spectral analysis and by comparing this to the cut-off frequency of the remaining wall thickness of the defect. The technique has the potential to improve defect sizing, defect sensitivity, increase spatial resolution, and increase the performance of medium range inspection.

Published

2017

11. Serotonin modulation in the male Aedes aegypti ear influences hearing.

Author

Xu, Yifeng Y. J., Loh, YuMin M., Tai-Ting Lee, Ohashi, Takuro S., Su, Matthew P., and Kamikouchi, Azusa

Subjects

AEDES aegypti, SEROTONIN, ORAL drug administration, EAR, SEROTONIN receptors

Abstract

Male Aedes aegypti (Ae. aegypti)mosquitoes rely on hearing to identify conspecific females for mating, with the male attraction to the sound of flying females ("phonotaxis") an important behavior in the initial courtship stage. Hearing thus represents a promising target for novel methods of mosquito control, and hearing behaviors (such as male phonotaxis) can be targeted via the use of sound traps. These traps unfortunately have proven to be relatively ineffective during field deployment. Shifting the target from hearing behavior to hearing function could therefore offer a novel method of interfering with Ae. aegypti mating. Numerous neurotransmitters, including serotonin (5-hydroxytryptamine, or 5-HT) and octopamine, are expressed in the male ear, with modulation of the latter proven to influence the mechanical responses of the ear to sound. The effect of serotoninmodulation however remains underexplored despite its significant role in determining many key behaviors and biological processes of animals. Here we investigated the influence of serotonin on the Ae. aegypti hearing function and behaviors. Using immunohistochemistry, we found significant expression of serotonin in the male and female Ae. aegypti ears. In the male ear, presynaptic sites identified via antibody labelling showed only partial overlap with serotonin. Next, we used RT-qPCR to identify and quantify the expression levels of three different serotonin receptor families (5-HT1, 5-HT2, and 5-HT7) in the mosquito heads and ears. Although all receptors were identified in the ears of both sexes, those from the 5-HT7 family were significantly more expressed in the ears relative to the heads. We then thoracically injected serotonin-related compounds into the mosquitoes and found a significant, reversible effect of serotonin exposure on the male ear mechanical tuning frequency. Finally, oral administration of a serotoninsynthesis inhibitor alteredmale phonotaxis. Themosquito serotonergic system and its receptors thus represent interesting targets for novelmethods of mosquito, and thus disease, control. [ABSTRACT FROM AUTHOR]

Published

2022

12. SELF-MIXING LASER VIBROMETER WITH RESOLUTION IN THE MICRO AND NANO METERS SCALE

Author

L. E. Filgueira and C. T. Schmiegelow

Subjects

interferometry, vibrometry, displacement measurement, laser diode, optical feedback, Physics, QC1-999

Abstract

We present the development of an interferometer capable of making contactless measurements of vibrations. The results show the we achieve micro- and/or nano-metric measurements without the stabilization of the laser. While there are multiple techniques to achieve this objective, in this case, we use a method whose main virtue is the low component count and the self-alignment capacity. The method is based on the optical feedback effect in a laser diode which relieson the use of an internal reference for calibration.

Published

2021

13. Diagnostics of Bridge Bed Sections and Approaches in Zones of Expansion Joints on Road Bridges

Author

V. A. Hodyakov, A. V. Kulan, E. N. Savina, I. L. Boiko, and V. A. Grechuhin

Subjects

relative deformation, sag, vibration velocity, vibration displacement, iso-area, durability, load, vibration response, unevenness, 3d-scanning, impact, stiffness, vibrometry, tensometry, dynamic impact, Technology

Abstract

The object of the study is durability of expansion joints in bridge structures; the subject of the research is the vibration response of a structure obtained under conditions of natural operation. Diagnostics of the road bridge expansion joints has been carried out in order to identify characteristic dependences between the value of structure vibration response and types of expansion joint designs during the period of their operation while taking into account the features of the bridge structure. For this purpose, we have tested the methodology for collecting and processing data on the vibration response of the structure under natural conditions of its operation. The paper presents results of data collection on the coverage topology which have been obtained while using three-dimensional scanning method. Data collection on the vibration response of the structure has been carried out by measuring the vibration velocity and deformation of the structure. The data obtained are analyzed. As a result of testing and analysis of the obtained data, the main characteristics have been revealed: the value of base unevenness, the amplitude of vibration velocity and vibration displacement of the structure elements. Two main parameters of the dynamic impact have been assigned, adjusted for the mass of a moving vehicle, which can be used as main parameter for assessing the magnitude of the dynamic impact. A comprehensive method for assessing the dynamic impact on bridge structures has been developed and proposed in the paper, and its use will make it possible to differentiate various designs of expansion joints according to the magnitude of the dynamic impact of vehicles. This, in its turn, will contribute to formulate new recommendations on the use of specific types of expansion joints for various categories of highway, which will increase operational durability of expansion joints and the structure as a whole.

Published

2021

14. Mechanical and Microstructural Characterization of Ultrasonic Metal Welded Large Cross Section Aluminum Wire/Copper Terminal Joints

Author

Gester, Andreas, Wagner, Guntram, Kesel, Ingo, Guenter, Friedhelm, and Chesonis, Corleen, editor

Published

2019

15. Millimetre-wave FMCW radar for remote sensing and security applications

Author

Cassidy, Scott L., Robertson, Duncan Alexander, and Smith, Graham Murray

Subjects

621.384, Radar, Millimetre wave, Sub-millimetre, FMCW, Coherent, Doppler, Vibrometry, Chirp nonlinearity, Phase noise, Imaging, Concealed object detection, Anomaly detection, Polarisation, Remote sensing, Tracking, Signal processing, Threading, GPU, TK6592.C65C2, Continuous wave radar, Remote sensing, Scanning systems, Security systems--Remote sensing

Abstract

This thesis presents a body of work on the theme of millimetre-wave FMCW radar, for the purposes of security screening and remote sensing. First, the development of an optimised software radar signal processor will be outlined. Through use of threading and GPU acceleration, high data processing rates were achieved using standard PC hardware. The flexibility of this approach, compared to specialised hardware (e.g. DSP, FPGA etc…), allowed the processor to be rapidly adapted and has produced a significant performance increase in a number of advanced real-time radar systems. An efficient tracker was developed and was successfully deployed in live trials for the purpose of real-time wave detection in an autonomous boat control system. Automated radar operation and remote data telemetry functions were implemented in a terrain mapping radar to allow continuous monitoring of the Soufrière Hills volcano on the Caribbean island of Montserrat. This work concluded with the installation of the system 3 km from the volcano. Hardware modifications were made to enable coherent measurement in a number of existing radar systems, allowing phase sensitive measurements, including range-Doppler, to be performed. Sensitivity to displacements of less than 200 nm was demonstrated, which is limited by the phase noise of the system. Efficient compensation techniques are presented which correct for quadrature mixer imbalance, FMCW chirp non-linearity, and scanner drive distortions. In collaboration with the Home Office, two radar systems were evaluated for the stand-off detection of concealed objects. Automatic detection capability, based on polarimetric signatures, was developed using data gathered under controlled conditions. Algorithm performance was assessed through blind testing across a statistically significant number of subjects. A detailed analysis is presented, which evaluates the effect of clothing and object type on detection efficiency.

Published

2015

16. Cochlear outer hair cell electromotility enhances organ of Corti motion on a cycle-by-cycle basis at high frequencies in vivo.

Author

Dewey, James B., Altoè, Alessandro, Shera, Christopher A., Applegate, Brian E., and Oghalai, John S.

Subjects

*HAIR cells, *CORTI'S organ, *MOLECULAR motor proteins, *FREQUENCIES of oscillating systems, *COCHLEA

Abstract

Mammalian hearing depends on an amplification process involving prestin, a voltage-sensitive motor protein that enables cochlear outer hair cells (OHCs) to change length and generate force. However, it has been questioned whether this prestin-based somatic electromotility can operate fast enough in vivo to amplify cochlear vibrations at the high frequencies that mammals hear. In this study, we measured sound-evoked vibrations from within the living mouse cochlea and found that the top and bottom of the OHCs move in opposite directions at frequencies exceeding 20 kHz, consistent with fast somatic length changes. These motions are physiologically vulnerable, depend on prestin, and dominate the cochlea's vibratory response to high-frequency sound. This dominance was observed despite mechanisms that clearly lowpass filter the in vivo electromotile response. Low-pass filtering therefore does not critically limit the OHC's ability to move the organ of Corti on a cycle-by-cycle basis. Our data argue that electromotility serves as the primary high-frequency amplifying mechanism within the mammalian cochlea. [ABSTRACT FROM AUTHOR]

Published

2021

17. Vibrometry and Sound Reproduction of Acoustic Sources on Moving Platforms Using Millimeter Wave Pulse-Doppler Radar

Author

Christopher T. Rodenbeck, Joshua B. Beun, Raghu G. Raj, and Ronald D. Lipps

Subjects

Millimeter wave radar, vibrometry, pulse-Doppler radar, motion compensation, audio recording, sound reproduction, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper presents millimeter wave (MMW) pulse-Doppler radar for the remote sensing of acoustic vibration for targets in motion. A key advance in this work is the development of precision motion compensation for MMW vibrometry, making it possible for a monostatic radar to extract and reproduce small-scale vibrations on platforms undergoing large-scale motion. The motion compensation methodology uses a hierarchical approach combining direct and indirect estimation for the time dependent variation of target motion parameters across coherent samples in radar fast time and slow time. Additionally, the wide bandwidth commonly available at MMW allows vibrations to be selectively detected and disambiguated in range across the length of moving targets. Stretch processing compresses the received radar bandwidth by more than 10x, so that Hilbert sampling can be used to acquire quadrature samples using a single analog-to-digital converter. The resulting complex baseband response directly reproduces the target's acoustic signature. To demonstrate the technique, a 94 GHz pulsed linear frequency modulated (LFM) radar accurately reproduces the pitch of audio waveforms generated by a speaker in the rear of an accelerating automobile at an outdoor test range. These results should have major consequences for the development of MMW vibrometry as a remote sensing technique.

Published

2020

18. Correction of Oblique-Angle Oscillation for Laser Doppler Vibrometry

Author

Vladimir Kindl, Tomas Kavalir, Jiri Sika, and Michal Krizek

Subjects

laser, doppler, vibrometry, measurement, prototype, oblique-angle, correction, Transportation and communications, HE1-9990, Science, Transportation engineering, TA1001-1280

Abstract

The paper proposes a correction method of the oblique-angle vibration for laser doppler vibrometry. It briefly discusses the key mathematical approach considering the surface of the analysed object to be a reference plane and gives a practical example of the method proper application. The proposed correction method is practically verified by laboratory measurement of natural frequencies and mode shapes for vibrations of high voltage transformer housing. The results are further compared to equivalent accelerometer measurement.

Published

2019

19. Pilot Studies of Vibrations Induced in Perambulators When Moving on Different Surfaces.

Author

Sierzputowski, Gustaw, Wróbel, Radosław, Mihaylov, Veselin, Janeczek, Maciej, Majewska-Pulsakowska, Marta, and Jarząb, Sławomir

Subjects

FREQUENCIES of oscillating systems, PILOT projects, FREE vibration, INFANTS, HUMAN comfort, CHANNEL estimation

Abstract

The ergonomics of transport is a topic widely described in the literature. One of the fields of ergonomics that researchers are engaged in is vibrometry (both laser and accelerometry) of travel and its translation into NVH (Noise, Vibration and Harshness). However, so far, the influence of baby carriage movement on the generated vibrations has not been described in more detail. The topic seems to be particularly important considering occurrence of vibrations with significant amplitudes, whose frequency range can have a direct bearing on the resonance frequencies of the child's internal organs. The article presents the results of research consisting in the measurement of vibrations to which an infant, lying in two different types of prams, may be exposed when being transported on different surfaces. The author's measurement system, based on accelerometry, was used for the research. The obtained weighted RMS acceleration values not only exceeded human comfort level in all cases (according to ISO standard) but several times were in the range of the highest discomfort (>2 m/s2). Furthermore, the observed vibration frequency range (≈0 ÷ 32 Hz) coincided with the frequencies of free vibration of organs and parts of the child's body. [ABSTRACT FROM AUTHOR]

Published

2021

20. Investigating peculiarities of piezoelectric detection methods for acoustic plate waves in material characterisation applications.

Author

Claes, Leander, Schmiegel, Hanna, Grünsteidl, Clemens, Johannesmann, Sarah, Webersen, Manuel, and Henning, Bernd

Subjects

LAMB waves, SOUND waves, WAVENUMBER, ACOUSTICAL materials, MATERIALS testing, MODE shapes

Abstract

Copyright of Technisches Messen is the property of De Gruyter and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2021

21. Upgrading of The Single Point Laser Vibrometer into a Laser Scanning Vibrometer

Author

Tomas Kavalir, Michal Krizek, Jiri Sika, and Vladimir Kindl

Subjects

modal analysis, laser, doppler, vibrometry, measurement, prototype, Transportation and communications, HE1-9990, Science, Transportation engineering, TA1001-1280

Abstract

The paper proposes a construction design of measuring device for fast and reliable non-contact modal analysis of object surfaces which cannot be measured using classical methods. The design combines conventional non-contact laser interferometer with an active optics module to be able to measure multiple points in a rapid sequence. The paper briefly discusses all the key constructional components and describes in detail the system functional layout. It also introduces the experimental measurement of a HV transformer under operation to demonstrate the system functionality.

Published

2018

22. Nanometer-Resolved Imaging Vibrometer

Author

Mahjoubfar, Ata, Chen, Claire Lifan, Jalali, Bahram, Mahjoubfar, Ata, Chen, Claire Lifan, and Jalali, Bahram

Published

2017

23. Non-destructive holographic vibrometric testing of the adhesive joint in metal-polymer laminates (Rapid communication).

Author

Nowak-Grzebyta, Jagoda, Meijer, Frans, and Stachowska, Ewa

Subjects

ADHESIVE joints, NONDESTRUCTIVE testing, LAMINATED materials, TESTING, POLYAMIDES

Abstract

Copyright of Polimery is the property of Industrial Chemistry Research Institute and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

24. An innovative method for in situ monitoring of the detachments in architectural coverings of ancient structures.

Author

Mariani, Francesca, Savoia, Alessandro S., and Caliano, Giosuè

Subjects

*SURFACE analysis, *COMPUTERS, *PERSONAL computers, *GEOGRAPHIC boundaries, *TESTING laboratories

Abstract

Detecting the presence, the position and the extension of architectural coverings separations, both on horizontal and vertical layers – such as mosaics, plasters, slabs or other functional and decorative layers – is at the base of the analysis of the state of conservation of ancient structures. Non-destructive investigations used to find detachments, like Laser Doppler Vibrometry (LDV), are hardly executable in situ. They are also influenced by the boundary conditions and often need the intervention of onerous technical consultations. For this reason, traditionally, conservators rely on the technique of auscultation, which entails gently knocking with the hand, listening to the sound produced by the surface and perceiving the vibration of it. Together with the thermographic analysis, the results of these examinations are translated into the graphic documentation of the discontinuities of the structural elements, detachments and cracks between layers, in order to achieve the conservative diagnosis and outline a project of intervention. Analysis carried out with such method is accurate, but introduces a strong subjective conservator's connotation, which makes it not repeatable. In this contribution, after having briefly examined the state of the art of in situ technologies, an innovative acoustic-vibrational technique for the detection of detachment phenomena between layers and discontinuity is introduced. The proposed technique also allows tracing an accurate map, using an image correlation method between an acoustic "snap" of the point of interest and a "reference snap". The analysis of the entire surface produces a graphics map of the detachments. This graphic documentation represents the "acoustic signature" of the structure, i.e. the "status quo" of the surface during the analysis. This representation can be used to monitor the state of conservation of the structure over time. In this paper, the method is developed and tested in laboratory using a personal computer and a hardware device specifically designed and fabricated, with the aim of providing a qualitative yet repeatable assessment of the state of conservation of a covering. The proposed method could be implemented in an easy-to-use and inexpensive portable version of the system using a smartphone, to which the developed hardware device would be connected through the audio jack to acquire the acoustic information, making the new system suitable for "in situ" operation. It can be also used for monitoring the evolution of the conservative scenario. The first results achieved on a test object are showed. [ABSTRACT FROM AUTHOR]

Published

2020

25. Optically Detecting Wavefronts and Wave Speeds in Water Using Refracto-Vibrometry

Author

Huber, Matthew T., Hoffmeister, Brent K., Huber, Thomas M., Zimmerman, Kristin B., Series editor, De Clerck, James, editor, and Epp, David S., editor

Published

2016

26. Vibration thresholds in carpal tunnel syndrome assessed by multiple frequency vibrometry: a case-control study

Author

Magnus Flondell, Birgitta Rosén, Gert Andersson, Tommy Schyman, Lars B. Dahlin, and Anders Björkman

Subjects

Carpal tunnel syndrome, Vibrometry, Sensibility, Touch thresholds, Vibrotactile sense, Vibration perception threshold, Industrial medicine. Industrial hygiene, RC963-969

Abstract

Abstract Background Carpal tunnel syndrome (CTS) is the most common compression neuropathy, but there is no gold standard for establishing the diagnosis. The ability to feel vibrations in the fingertips is dependent on the function in cutaneous receptors and afferent nerves. Our aim was to investigate vibration perception thresholds (VPTs) in patients with CTS using multi-frequency vibrometry. Methods Sixty-six patients (16 men and 50 women) with CTS, diagnosed from clinical signs and by electroneurography, and 66 matched healthy controls were investigated with multi-frequency vibrometry. The VPTs were assessed at seven frequencies (8, 16, 32, 64, 125, 250, and 500 Hz) in the index finger and little finger bilaterally. The severity of the CTS was graded according to Padua and the patient’s subjective symptoms were graded according to the Boston carpal tunnel questionnaire. Touch thresholds were assessed using the Semmes-Weinstein monofilaments. Results Patients with CTS had significantly higher VPTs at all frequencies in the index finger and in 6 out of 7 frequencies in the little finger compared to the controls. However, the VPT was not worse in patients with more severe CTS. Patients with unilateral CTS showed significantly higher VPTs in the affected hand. There were no correlations between VPTs and electrophysiological parameters, subjective symptoms, or touch threshold. Conclusions Patients with CTS had impaired VPTs at all frequencies compared to the controls. Since the VPTs are dependent on function in peripheral receptors and their afferent nerves, multi-frequency vibrometry could possibly lead to diagnosis of CTS.

Published

2017

27. Physiological Validation of an Airborne Ultrasound Based Surface Motion Camera for a Contactless Characterization of Breathing Pattern in Humans

Author

Marie-Cécile Niérat, Pierantonio Laveneziana, Bruno-Pierre Dubé, Pavel Shirkovskiy, Ros-Kiri Ing, and Thomas Similowski

Subjects

breathing pattern, breathing variability, observer effect, vibrometry, airborne ultrasound, contactless breathing measurement, Physiology, QP1-981

Abstract

Characterizing the breathing pattern in naturally breathing humans brings important information on respiratory mechanics, respiratory muscle, and breathing control. However, measuring breathing modifies breathing (observer effect) through the effects of instrumentation and awareness: measuring human breathing under true ecological conditions is currently impossible. This study tested the hypothesis that non-contact vibrometry using airborne ultrasound (SONAR) could measure breathing movements in a contactless and invisible manner. Thus, first, we evaluated the validity of SONAR measurements by testing their interchangeability with pneumotachograph (PNT) measurements obtained at the same time. We also aimed at evaluating the observer effect by comparing breathing variability obtained by SONAR versus SONAR-PNT measurements. Twenty-three healthy subjects (12 men and 11 women; mean age 33 years – range: 20–54) were studied during resting breathing while sitting on a chair. Breathing activity was described in terms of ventilatory flow measured using a PNT and, either simultaneously or sequentially, with a SONAR device measuring the velocity of the surface motion of the chest wall. SONAR was focused either anteriorly on the xiphoid process or posteriorly on the lower part of the costal margin. Discrete ventilatory temporal and volume variables and their coefficients of variability were calculated from the flow signal (PNT) and the velocity signal (SONAR) and tested for interchangeability (Passing-Bablok regression). Tidal volume (VT) and displacement were linearly related. Breathing frequency (BF), total cycle time (TT), inspiratory time (TI), and expiratory time (TE) met interchangeability criteria. Their coefficients of variation were not statistically significantly different with PNT and SONAR-only. This was true for both the anterior and the posterior SONAR measurements. Non-contact vibrometry using airborne ultrasound is a valid tool for measuring resting breathing pattern.

Published

2019

28. Pilot Studies of Vibrations Induced in Perambulators When Moving on Different Surfaces

Author

Gustaw Sierzputowski, Radosław Wróbel, Veselin Mihaylov, Maciej Janeczek, Marta Majewska-Pulsakowska, and Sławomir Jarząb

Subjects

infant’s health, pram, baby carriage, vibrometry, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The ergonomics of transport is a topic widely described in the literature. One of the fields of ergonomics that researchers are engaged in is vibrometry (both laser and accelerometry) of travel and its translation into NVH (Noise, Vibration and Harshness). However, so far, the influence of baby carriage movement on the generated vibrations has not been described in more detail. The topic seems to be particularly important considering occurrence of vibrations with significant amplitudes, whose frequency range can have a direct bearing on the resonance frequencies of the child’s internal organs. The article presents the results of research consisting in the measurement of vibrations to which an infant, lying in two different types of prams, may be exposed when being transported on different surfaces. The author’s measurement system, based on accelerometry, was used for the research. The obtained weighted RMS acceleration values not only exceeded human comfort level in all cases (according to ISO standard) but several times were in the range of the highest discomfort (>2 m/s2). Furthermore, the observed vibration frequency range (≈0 ÷ 32 Hz) coincided with the frequencies of free vibration of organs and parts of the child’s body.

Published

2021

29. A New Approach to the Phase-Based Video Motion Magnification for Measuring Microdisplacements.

Author

Popek, Mateusz P. and Iskander, D. Robert

Subjects

*HILBERT transform, *CAMCORDERS, *ULTRASONIC transducers, *TIME series analysis, *MOTION, *VIBRATION measurements

Abstract

Video motion magnification (VMM) techniques have recently gained attention as a low-cost accurate method for measuring microdisplacements. VMM techniques are known to have incorrect frequency responses when handling dynamic measurements consisting of multiple frequencies. New phase-based VMM method utilizing radial fractional steerable 2-D Hilbert transform is proposed and contrasted, in terms of the frequency response, with two other established VMM methods. Typical VMM workflow includes amplifying phase changes between subsequent video frames on many spatial frequencies separately using image pyramids, which are then collapsed forming new, motion-magnified video. In this paper, Hilbert transform is used to extract local phase changes. The modified Kullback–Leibler divergence was calculated between the spectral estimates of the time series of vibrating plate measured using a high-speed video camera and a reference time series synchronously acquired with high-precision air-coupled ultrasonic transducer. Time series consisted of micrometer range multicomponent vibrations (one, two, and three sine frequencies) recorded with different motion magnification factors. The results show that in the majority of cases, the proposed method, out of three considered, resulted in the most uniform frequency response and generated the lowest amount of unwanted frequencies. To conclude, a novel approach to VMM is proposed, which substantially improves frequency response and makes this technique more suitable for the measurements of phenomena consisting of multiple frequencies. [ABSTRACT FROM AUTHOR]

Published

2020

30. Principles of surface-phase-resolved shearography.

Author

DeWeert, Michael J., Acker, Andrew N., Noguchi, Reid, Dugan Yoon, and Sawai, Gary

Subjects

*REMOTE sensing, *IMAGING systems, *SPECKLE interference, *RANDOM noise theory, *INFORMATION needs

Abstract

There is a need to remotely measure the full phase and amplitude information of small-scale acoustoseismic vibrations in order to detect the presence of buried objects (e.g., tunnels, etc.), or for other purposes. This remote sensing information may need to be collected with a large area coverage rate and at a safe standoff distance. To accomplish this, we have implemented a shearographic imaging system that incorporates phase stepping in a novel way, automatically separating random speckle noise from surface motion, without requiring an intermediate unwrapping step. This method, which we call surface-phase-resolved shearography, is especially effective for very low-amplitude motions that generate less than one light-wavelength of phase change. In laboratory studies, we have demonstrated sensitivity of two nanometers RMS with 532-nm-wavelength light. [ABSTRACT FROM AUTHOR]

Published

2019

31. CORRECTION OF OBLIQUE-ANGLE OSCILLATION FOR LASER DOPPLER VIBROMETRY.

Author

Kindl, Vladimir, Kavalir, Tomas, Sika, Jiri, and Krizek, Michal

Subjects

*PLANE geometry, *ACOUSTIC vibrations, *ACCELEROMETERS, *ELECTRIC potential, *HOUSING

Abstract

The paper proposes a correction method of the oblique-angle vibration for laser doppler vibrometry. It briefly discusses the key mathematical approach considering the surface of the analysed object to be a reference plane and gives a practical example of the method proper application. The proposed correction method is practically verified by laboratory measurement of natural frequencies and mode shapes for vibrations of high voltage transformer housing. The results are further compared to equivalent accelerometer measurement. [ABSTRACT FROM AUTHOR]

Published

2019

32. Physiological Validation of an Airborne Ultrasound Based Surface Motion Camera for a Contactless Characterization of Breathing Pattern in Humans.

Author

Niérat, Marie-Cécile, Laveneziana, Pierantonio, Dubé, Bruno-Pierre, Shirkovskiy, Pavel, Ing, Ros-Kiri, and Similowski, Thomas

Subjects

RESPIRATORY measurements, RESPIRATORY muscle physiology, SONAR, VELOCITY measurements, ULTRASONIC imaging

Abstract

Characterizing the breathing pattern in naturally breathing humans brings important information on respiratory mechanics, respiratory muscle, and breathing control. However, measuring breathing modifies breathing (observer effect) through the effects of instrumentation and awareness: measuring human breathing under true ecological conditions is currently impossible. This study tested the hypothesis that non-contact vibrometry using airborne ultrasound (SONAR) could measure breathing movements in a contactless and invisible manner. Thus, first, we evaluated the validity of SONAR measurements by testing their interchangeability with pneumotachograph (PNT) measurements obtained at the same time. We also aimed at evaluating the observer effect by comparing breathing variability obtained by SONAR versus SONAR-PNT measurements. Twenty-three healthy subjects (12 men and 11 women; mean age 33 years – range: 20–54) were studied during resting breathing while sitting on a chair. Breathing activity was described in terms of ventilatory flow measured using a PNT and, either simultaneously or sequentially, with a SONAR device measuring the velocity of the surface motion of the chest wall. SONAR was focused either anteriorly on the xiphoid process or posteriorly on the lower part of the costal margin. Discrete ventilatory temporal and volume variables and their coefficients of variability were calculated from the flow signal (PNT) and the velocity signal (SONAR) and tested for interchangeability (Passing-Bablok regression). Tidal volume (VT) and displacement were linearly related. Breathing frequency (BF), total cycle time (TT), inspiratory time (TI), and expiratory time (TE) met interchangeability criteria. Their coefficients of variation were not statistically significantly different with PNT and SONAR-only. This was true for both the anterior and the posterior SONAR measurements. Non-contact vibrometry using airborne ultrasound is a valid tool for measuring resting breathing pattern. [ABSTRACT FROM AUTHOR]

Published

2019

33. Effective Use of Scanning Laser Doppler Vibrometers for Modal Testing

Author

Weekes, Ben, Ewins, David, Proulx, Tom, Series editor, and Allemang, Randall, editor

Published

2014

34. Measurement of Mechanical Properties of Soft Tissue with Ultrasound Vibrometry

Author

Nenadich, I., Bernal, M., Greenleaf, J.F., André, Michael P., editor, Jones, Joie P., editor, and Lee, Hua, editor

Published

2011

35. Vibro-Acoustography of Arteries

Author

Pislaru, Cristina, Greenleaf, James F., Kantor, Birgit, Fatemi, Mostafa, Suri, Jasjit S., editor, Kathuria, Chirinjeev, editor, and Molinari, Filippo, editor

Published

2011

36. Towards contactless optical coherence elastography with acoustic tissue excitation

Author

Düwel Dino, Otte Christoph, Schulz Kevin, Saathoff Thore, and Schlaefer Alexander

Subjects

optical coherence tomography, vibrometry, elastography, oce, oct, tissue classification, mechanical tissue properties, Medicine

Abstract

Elastography presents an interesting approach to complement image data with mechanical tissue properties. Typically, the tissue is excited by direct contact to a probe. We study contactless elastography based on optical coherence tomography (OCT) and dynamic acoustic tissue excitation with airborne sound. We illustrate the principle and an implementation using sound waves of 135 Hz to excite the tissue. The displacement is measured and results of several tests indicate the feasibility to obtain a qualitative measure of the mechanical tissue properties. The approach is interesting for optical palpation, e.g., to enhance navigation and tissue characterization in minimally invasive and robot-assisted surgery.

Published

2015

37. A Rapid Method to Noninvasively Measure the Viscoelastic Properties of Synthetic Polymers Using Mechanical Vibrations and Photonics

Author

Frederick H. Silver, Michael Gonzalez-Mercedes, and Arielle Mesica

Subjects

silicone, viscoelasticity, elastic modulus, viscous loss, tensile testing, infrared light, acoustic vibrations, vibrometry, Radiology, Nuclear Medicine and imaging, Instrumentation, Atomic and Molecular Physics, and Optics

Abstract

Noninvasive measurement of the viscoelastic properties of both natural and synthetic polymers is important for the analysis of implant design and performance as well as in industrial material development. In this study, we used vibrational optical coherence tomography (VOCT) to compare the elastic and viscoelastic properties of silicone polymers with standard tensile stress–strain measurements. VOCT uses acoustic vibrations and infrared light to measure the resonant frequency of viscoelastic materials. The elastic modulus was calculated from the in-phase deformation of the material at fixed frequencies using an empirical calibration curve. Viscous loss was measured after pulsing the samples based on the ratio of mechanovibrational peak widths to heights. The results showed that the optimal cure time and modulus values obtained using VOCT were like those obtained using conventional tensile testing. VOCT could capture results that were comparable to conventional testing while not destroying the material, suggesting its usefulness for in vivo and in situ measurements as well as for early quality control environments during end-use application and fabrication experiments. We conclude that VOCT is a new technique that is comparable to conventional testing for noninvasively and nondestructively measuring the viscoelastic properties of polymers.

Published

2022

38. Study of plant fibre composites with damage induced by laser and mechanical impacts.

Author

Malinowski, Paweł H., Ostachowicz, Wiesław M., Touchard, Fabienne, Boustie, Michel, Chocinski-Arnault, Laurence, Gonzalez, Pedro Pascual, Berthe, Laurent, Silva De Vasconcellos, Davi, and Sorrentino, Luigi

Subjects

*PLANT fibers, *LASER damage, *COMPOSITE materials, *FIBER-reinforced plastics, *POLYLACTIC acid

Abstract

Abstract Polymer composite materials provide good strength to weight ratio and tailored mechanical properties thanks to the reinforcing fibres. Until recently, the need for taking into account the whole life cycle of a composite structure was neglected and only the service aspects were important. Today, the designers of a new composite structure have to take into account the environmental aspects from the sustainability of raw materials to the management of end life products. There are recycling issues related to the most popular composites. A solution for the recycling issue can be sought in green composites with reinforcing fibre originating from plants. The behaviour of eco-composites, when subjected to laser or mechanical impact loadings, is not well known yet. Short fibre composites were made with spruce fibres. Another set of samples was made of flax fibres. Also a woven hemp fabric-based eco-composite was investigated. A fully synthetic woven composite was used for comparison with green composites. Mechanical impacts were performed by means of a falling dart impact testing machine. Laser impacts were made with high power laser source. Four assessment techniques were employed in order to analyse and compare impact damage. Damage detection thresholds for each material and technique were obtained. [ABSTRACT FROM AUTHOR]

Published

2018

39. Remote Vibration Estimation Using Displaced-Phase-Center Antenna SAR for Strong Clutter Environments.

Author

Campbell, Justin B., Perez, Francisco, Wang, Qi, Santhanam, Balasubramaniam, Doerry, Armin W., Atwood, Thomas, Hayat, Majeed M., and Dunkel, Ralf

Subjects

*SYNTHETIC aperture radar, *VIBROMETERS, *FOURIER transforms, *KALMAN filtering, *REMOTE sensing

Abstract

It has been previously demonstrated that it is possible to perform remote vibrometry using synthetic aperture radar (SAR) in conjunction with the discrete fractional Fourier transform (DFrFT). Specifically, the DFrFT estimates the chirp parameters (related to the instantaneous acceleration of a vibrating object) of a slow-time signal associated with the SAR image. However, ground clutter surrounding a vibrating object introduces uncertainties in the estimate of the chirp parameter retrieved via the DFrFT method. To overcome this shortcoming, various techniques based on subspace decomposition of the SAR slow-time signal have been developed. Nonetheless, the effectiveness of these techniques is limited to values of signal-to-clutter ratio ≥5 dB. In this paper, a new vibrometry technique based on displaced-phase-center antenna (DPCA) SAR is proposed. The main characteristic of a DPCA-SAR is that the clutter signal can be canceled, ideally, while retaining information on the instantaneous position and velocity of a target. In this paper, a novel method based on the extended Kalman filter (EKF) is introduced for performing vibrometry using the slow-time signal of a DPCA-SAR. The DPCA-SAR signal model for a vibrating target, the mathematical characterization of the EKF technique, and vibration estimation results for various types of vibration dynamics are presented. [ABSTRACT FROM AUTHOR]

Published

2018

40. Investigation of the Young’s Modulus and the Residual Stress of 4H-SiC Circular Membranes on 4H-SiC Substrates

Author

Jaweb Ben Messaoud, Jean-François Michaud, Dominique Certon, Massimo Camarda, Nicolò Piluso, Laurent Colin, Flavien Barcella, and Daniel Alquier

Subjects

4h-sic, bulk micromachining, electrochemical etching, circular membrane, bulge test, vibrometry, mechanical properties, young’s modulus, residual stress, fem, Mechanical engineering and machinery, TJ1-1570

Abstract

The stress state is a crucial parameter for the design of innovative microelectromechanical systems based on silicon carbide (SiC) material. Hence, mechanical properties of such structures highly depend on the fabrication process. Despite significant progresses in thin-film growth and fabrication process, monitoring the strain of the suspended SiC thin-films is still challenging. However, 3C-SiC membranes on silicon (Si) substrates have been demonstrated, but due to the low quality of the SiC/Si heteroepitaxy, high levels of residual strains were always observed. In order to achieve promising self-standing films with low residual stress, an alternative micromachining technique based on electrochemical etching of high quality homoepitaxy 4H-SiC layers was evaluated. This work is dedicated to the determination of their mechanical properties and more specifically, to the characterization of a 4H-SiC freestanding film with a circular shape. An inverse problem method was implemented, where experimental results obtained from bulge test are fitted with theoretical static load-deflection curves of the stressed membrane. To assess data validity, the dynamic behavior of the membrane was also investigated: Experimentally, by means of laser Doppler vibrometry (LDV) and theoretically, by means of finite element computations. The two methods provided very similar results since one obtained a Young’s modulus of 410 GPa and a residual stress value of 41 MPa from bulge test against 400 GPa and 30 MPa for the LDV analysis. The determined Young’s modulus is in good agreement with literature values. Moreover, residual stress values demonstrate that the fabrication of low-stressed SiC films is achievable thanks to the micromachining process developed.

Published

2019

41. Linear-Stokes Hyper Temporal Polarimeter for Long-Range Characterization of Vibrating Objects

Author

Sasian, Jose M., Koshel, R. John, Richter, Juliana, Sasian, Jose M., Koshel, R. John, and Richter, Juliana

Abstract

The Hyper-Temporal Polarimeter [HyTeP] is a linear-Stokes polarimeter capable of sensing vibration modes in a distant target. Solar panels present on almost all satellites are illuminated with incoherent sunlight and reflect partially polarized light according to the Fresnel reflection coefficients, which will vary with angle of incidence. Mechanical vibrations in a target deflect the surface normal and thus the effective angle of incidence and exiting polarization state for a stationary source. The extent by which the light is partially polarized is quantified as the degree of linear polarization [DoLP] and the orientation of linear polarization is given as the angle of linear polarization [AoLP] for the incoherent sum across the observed bandwidth. Temporal imaging captures structural information with low noise at high speeds. With sufficient imaging speed, a discrete Fourier transform converts temporal DoLP and AoLP data to frequency space, where these surface deflections can be understood as vibrational frequencies. Prior work has demonstrated that vibrational frequencies are unique to a target and can be understood as a polarization signature useful for identification and monitoring. HyTeP has demonstrated accurate frequency measurement from 10 to 1500 Hz with 0.5 Hz RMS accuracy when sampling a target at 3.36 kHz. Amplitude tests indicate that HyTeP can detect vibrations with amplitudes as small as 2.2 microns. This body of work examines optimal polarimeter designs, whether the science goal demands imaging speed, SNR, or estimation of satellite orientation; as well as adaptations for novel applications for remote passive-illumination polarimetric vibrometry.

Published

2022

42. Low-Cost, Open-Source XYZ Nanopositioner for High-Precision Analytical Applications

Author

Hwu, Edwin

Subjects

Dynamics and Dynamical Systems, Computational Engineering, Stick slip mechanism, Digital to analog converter (DAC), Semiconductor and Optical Materials, Statistical, Nonlinear, and Soft Matter Physics, Systems and Communications, Other Electrical and Computer Engineering, Teacher Education and Professional Development, Physical Sciences and Mathematics, Nanotechnology, Computer Engineering, Interferometer, Biomedical Engineering and Bioengineering, Biological and Chemical Physics, Systems Biology, Physics, Atomic force microscope, Hacking, Life Sciences, Industrial Technology, Robotics, Electrical and Computer Engineering, Nanoscience and Nanotechnology, Nanomedicine, Special Education and Teaching, Other Engineering Science and Materials, Electromagnetics and Photonics, Nano inspection, Scanning probe microscopy (SPM), Statistics and Probability, Scanning electron microscopy (SEM), Lock-in amplifier, Electrical and Electronics, Operational Research, Vibrometry, Optical pick-up unit (OPU), Education, Nano metrology, Engineering Mechanics, Industrial Engineering, FOS: Mathematics, Arduino, High resolution imaging, Electronic Devices and Semiconductor Manufacturing, Other Physical Sciences and Mathematics, FOS: Nanotechnology, Curriculum and Instruction, Applied Mechanics, Nano imaging, Mechanical Engineering, Other Materials Science and Engineering, Nano machining, Optics, Nanopositioning, Higher Education, Elementary Particles and Fields and String Theory, High-voltage amplifier, Open-source Nanopositioner, Piezoelectric, Mathematics, Tribology, Systems Engineering, FOS: Mechanical engineering, Biomechanical Engineering, Optical microscopy, Engineering, Materials Science and Engineering, Science and Mathematics Education, Medicine and Health Sciences, Long range nanopositioning, Data Storage Systems, Resonant frequency, Microscopy, Quantum Physics, Statistical Models, Applied Mathematics, Biology and Biomimetic Materials, Microstring resonator, 3D printing, Other Operations Research, Systems Engineering and Industrial Engineering, Mechanics of Materials, SEM, Other Physics, Other Mechanical Engineering, Engineering Education, Engineering Physics, Other Computer Engineering, Structural Materials, Hardware Systems, Engineering Science and Materials, FOS: Physical sciences, Nanotechnology Fabrication, Electro-Mechanical Systems, Ultra high vacuum (UHV), Operations Research, Systems Engineering and Industrial Engineering, Atomic resolution, Statistical Theory, Design of Experiments and Sample Surveys, Computer-Aided Engineering and Design, Statistical Methodology, Manufacturing, Nanoscale, Atomic, Molecular and Optical Physics, Digital Circuits, Acoustics, Dynamics, and Controls, Signal Processing, Secondary Education, Doppler vibrometer

Abstract

Published article location: https://doi.org/10.1016/j.ohx.2022.e00317 Authors: Hsien-Shun Liao(a), Christian Werner(b), Roman Slipets(c), Peter Emil Larsen(c), Ing-Shouh Hwang(d), Tien-Jen Chang(c), Hans Ulrich Danzebrink(b), Kuang-Yuh Huang(a), and En-Te Hwu(c,*) Affiliations: (a)Department of Mechanical Engineering, National Taiwan University, 10617, Taipei, Taiwan. (b)Physikalisch-Technische Bundesanstalt, Bundesallee 100, 38116 Braunschweig, Germany. (c)The Danish National Research Foundation and Villum Foundation’s Center for Intelligent Drug Delivery and Sensing Using Microcontainers and Nanomechanics, Department of Health Technology, Technical University of Denmark, 2800 Kgs. Lyngby, Denmark. (d)Institute of Physics, Academia Sinica, 11529, Taipei, Taiwan *corresponding author contact: etehw@dtu.dk Abstract Nanoscale positioning has numerous applications in both academia and industry. A growing number of applications require devices with long working distances and nanoscale resolutions. Friction–inertia piezoelectric positioners, which are based on the stick–slip mechanism, achieve both nanometer resolution and centimeter-scale travel. However, the requirements of complex preload mechanism, precision machining, and precise assembly increase the cost of conventional friction–inertia nanopositioners. Herein we present the design of an open-source XYZ-axis nanopositioning system. Utilizing a magnet-based stick–slip driving mechanism, the proposed XYZ nanopositioner provides several advantages, including sub-nanometer resolution, a payload capacity of up to 12 kg (horizontal), compact size, low cost, and easy assembly; furthermore, the system is adjustment-free. The performance tests validate the precision of the system in both scanning and stepping operation modes. Moreover, the resonant spectra affirm the rigidity and dynamic response of the mechanism. In addition, we demonstrate the practical applications of this nanopositioner in various measurement techniques, including scanning electron microscopy, vibrometry, and atomic force microscopy. Furthermore, we present 11 variations of the nanopositioner designs that are either compatible with ultra-high-vacuum systems and other existing systems, 3D printable, or hacking commercial linear slides.

Published

2022

43. UPGRADING OF THE SINGLE POINT LASER VIBROMETER INTO A LASER SCANNING VIBROMETER.

Author

Kavalir, Tomas, Krizek, Michal, Sika, Jiri, and Kindl, Vladimir

Subjects

*VIBROMETERS, *LASER interferometers, *MODAL analysis, *PROTOTYPES, *DOPPLER effect

Abstract

The paper proposes a construction design of measuring device for fast and reliable non-contact modal analysis of object surfaces which cannot be measured using classical methods. The design combines conventional non-contact laser interferometer with an active optics module to be able to measure multiple points in a rapid sequence. The paper briefly discusses all the key constructional components and describes in detail the system functional layout. It also introduces the experimental measurement of a HV transformer under operation to demonstrate the system functionality. [ABSTRACT FROM AUTHOR]

Published

2018

44. Vibration thresholds in carpal tunnel syndrome assessed by multiple frequency vibrometry: a case-control study.

Author

Flondell, Magnus, Rosén, Birgitta, Andersson, Gert, Schyman, Tommy, Dahlin, Lars B., and Björkman, Anders

Subjects

CARPAL tunnel syndrome, TOUCH, VIBRATION (Mechanics), CASE-control method, DIAGNOSIS

Abstract

Background: Carpal tunnel syndrome (CTS) is the most common compression neuropathy, but there is no gold standard for establishing the diagnosis. The ability to feel vibrations in the fingertips is dependent on the function in cutaneous receptors and afferent nerves. Our aim was to investigate vibration perception thresholds (VPTs) in patients with CTS using multi-frequency vibrometry. Methods: Sixty-six patients (16 men and 50 women) with CTS, diagnosed from clinical signs and by electroneurography, and 66 matched healthy controls were investigated with multi-frequency vibrometry. The VPTs were assessed at seven frequencies (8, 16, 32, 64, 125, 250, and 500 Hz) in the index finger and little finger bilaterally. The severity of the CTS was graded according to Padua and the patient's subjective symptoms were graded according to the Boston carpal tunnel questionnaire. Touch thresholds were assessed using the Semmes-Weinstein monofilaments. Results: Patients with CTS had significantly higher VPTs at all frequencies in the index finger and in 6 out of 7 frequencies in the little finger compared to the controls. However, the VPT was not worse in patients with more severe CTS. Patients with unilateral CTS showed significantly higher VPTs in the affected hand. There were no correlations between VPTs and electrophysiological parameters, subjective symptoms, or touch threshold. Conclusions: Patients with CTS had impaired VPTs at all frequencies compared to the controls. Since the VPTs are dependent on function in peripheral receptors and their afferent nerves, multi-frequency vibrometry could possibly lead to diagnosis of CTS. [ABSTRACT FROM AUTHOR]

Published

2017

45. Three-axis vibration sensor with a modular measuring system

Subjects

Ñ‚Ñ€ÐµÑ Ð¾ÑÐµÐ²Ð¾Ð¹ пьезоэектричейский акслерометр, виброметрия, виброметр, vibrometry, three-axis piezoectric acclerometer, vibrometer

Abstract

Тема выпускной квалификационной работы: Â«Ð¢Ñ€ÐµÑ Ð¾ÑÐµÐ²Ð¾Ð¹ вибродатчик с модульной измерительной системой». Данная дипломная работа посвящена разработке треосевого вибродатчика с модульной системой измерений с возможностью подключения к персональному компьютеру. Вопросы, которые были рассмотрены в процессе выполнения работы. Изучение Ð¸Ð¼ÐµÑŽÑ‰Ð¸Ñ ÑÑ на рынке Ñ‚Ñ€ÐµÑ Ð¾ÑÐµÐ²Ñ‹Ñ Ð¿ÑŒÐµÐ·Ð¾Ð´Ð°Ñ‚Ñ‡Ð¸ÐºÐ¾Ð². Анализ существующей конструкции датчика. Сравнение и выбор пьезоматериалов. Разработка методов расчета Ñ‚Ñ€ÐµÑ Ð¾ÑÐµÐ²Ð¾Ð³Ð¾ датчика с одной инертной массой Разработка ÑÑ ÐµÐ¼Ñ‹ подключения модульной системы. Ð’Ñ Ð¾Ð´Ðµ выполнения данной работы была разработана методика проектировки Ñ‚Ñ€ÐµÑ Ð¾ÑÐµÐ²Ð¾Ð³Ð¾ датчика с одной инертной массой с минимальными разбросами Ñ Ð°Ñ€Ð°ÐºÑ‚ÐµÑ€Ð¸ÑÑ‚Ð¸Ðº в Ñ‚Ñ€ÐµÑ Ð¾ÑÑÑ Ð¸Ð·Ð¼ÐµÑ€ÐµÐ½Ð¸Ð¹. Так же была спроектирована система подключения датчика к персональному компьютеру при помощи модулей NI., Topic of the final qualification work: "Three-axis vibration sensor with a modular measuring system". This thesis is devoted to the development of a three-axis vibration sensor with a modular measurement system with the ability to connect to a personal computer. Issues that were considered in the course of the work.1. Examination of three-axis piezo sensors available on the market. 2. Analysis of the existing sensor design. 3. Comparison and selection of piezo materials. 4. Development of methods for calculating a three-axis sensor with one inertial mass. 5. Development of a modular system connection diagramIn the course of this work, a technique was developed for designing a three-axis sensor with one inertial mass with minimal scatter in characteristics in three measurement axes. The system for connecting the sensor to a personal computer using NI modules was also designed.

Published

2022

46. Vibrometry as a noncontact alternative to dynamic and viscoelastic mechanical testing in cartilage

Author

M. Gabriela Espinosa, Gaston A. Otarola, Jerry C. Hu, and Kyriacos A. Athanasiou

Subjects

Cartilage, Articular, Knee Joint, General Science & Technology, storage modulus, Biomedical Engineering, Biophysics, Bioengineering, Stress, Biochemistry, Bone and Bones, Biomaterials, vibrometry, viscoelasticity, Life Sciences–Engineering interface, Viscosity, Arthritis, Mechanical, Elasticity, Biomechanical Phenomena, Cartilage, Musculoskeletal, dynamic modulus, Mechanical Tests, Stress, Mechanical, loss modulus, Articular, Biotechnology

Abstract

Physiological loading of knee cartilage is highly dynamic and may contribute to the progression of osteoarthritis. Thus, an understanding of cartilage's dynamic mechanical properties is crucial in cartilage research. In this study, vibrometry was used as a fast (2 h), noncontact and novel alternative to the slower (30 h), traditional mechanical and biochemical assays for characterization of cartilage from the condyle, patella, trochlear groove and meniscus. Finite-element models predicted tissue resonant frequencies and bending modes, which strongly correlated with experiments (R2= 0.93). Vibrometry-based viscoelastic properties significantly correlated with moduli from stress relaxation and creep tests, with correlation strengths reaching up to 0.78. Loss modulus also strongly correlated with glycosoaminoglycan (GAG) content. Dynamic properties measured by vibrometry significantly differed among various knee cartilages, ranging between 6.1 and 56.4 MPa. Interestingly, meniscus viscoelastic properties suggest that contrary to common belief, it may lack shock absorption abilities; instead, condylar hyaline cartilage may be a better shock absorber. These data demonstrate for the first time that vibrometry is a noncontact approach to dynamic mechanical characterization of hyaline and fibrocartilage cartilage with concrete relationships to standard quasi-static mechanical testing and biochemical composition. Thus, with a single tool, vibrometry greatly facilitates meeting multiple regulatory recommendations for mechanical characterization of cartilage replacements.

Published

2021

47. Adaptive Contactless Fiber-Optic Vibration Displacement Sensor.

Author

Yurin, A., Dmitriev, A., Krasivskaya, M., and Zlodeev, G.

Subjects

*TRANSDUCERS, *VIBRATIONAL spectra, *DETECTORS, *PHOTODETECTORS, *LIGHT sources

Abstract

The construction of a contactless adaptive vibration sensor based on an externally modulated reflectometer-type fiber-optic transducer is discussed. The sources of measurement error and ways of reducing them are determined. An experimental prototype fiber-optic contactless adaptive vibration sensor and a method for correcting its transfer function are described. [ABSTRACT FROM AUTHOR]

Published

2017

48. New Optical Approach of SAW Delay Line Characterization.

Author

Djoumi, Lyes, Smagin, Nikolay, Vanotti, Meddy, Fall, Dame, Herth, Etienne, Duquennoy, Marc, Ouaftouh, Mohammadi, Blondeau-Patissier, Virginie, and Jenot, Fréderic

Subjects

DELAY lines, DISPLACEMENT (Mechanics), INTERFEROMETERS, SURFACES (Technology), SUBSTRATES (Materials science)

Abstract

Surface acoustic wave devices are usually characterized solely through their electrical parameters. Mechanical displacements can also be numerically computed using finite element software. In this paper, we show that this characterization can be supplemented using an interferometer system capable of measuring out-of-plane mechanical displacement over the entire sensor structure. Conventionally, interferometer imagery is limited to 20MHz, but this work reports the results of the characterization of Rayleigh wave-based SAW sensors operating at a frequency of 78.8MHz using ultrahigh-frequency scanning laser vibrometry. An overview of the conventional methods used to characterize SAW devices is presented here, as well as a comparison between the results obtained using these methods and laser vibrometry. It is shown that the latter technique also provides access to time-resolved ultrasonic fields over the entire rsubstrate surface and provides an insight into important reflection and divergence phenomena . Comparison with standard network analyzer measurement is shown to assess the performance of Laser Doppler Vibrometry system. Mechanical and electrical characterization and comparison with a model results are presented and discussed. The purpose of this article is to review these latest developments tools in the SAW sensor measurement and present an outlook of the future of these characterizations in the next generation piezo-sensors. [ABSTRACT FROM AUTHOR]

Published

2016

49. Ultrasonic-assisted laser welding on AISI 321 stainless steel

Author

Tarasov, S. Yu., Vorontsov, A. V., Fortuna, S. V., Rubtsov, V. E., Krasnoveikin, V. A., and Kolubaev, E. A.

Published

2019

50. Digital Image Correlation Vibrometry with Low Speed Equipment.

Author

Warburton, J., Lu, G., Buss, T., Docx, H., Matveev, M., and Jones, I.

Subjects

*DIGITAL image correlation, *MODE shapes, *ALUMINUM plates, *FINITE element method, *STROBOSCOPES

Abstract

A low-cost method is presented which enables digital image correlation (DIC) with conventional cameras (i.e. not high-speed) to be used for determination of vibration deflected shapes via the use of a stroboscopic lamp and some simple ancillary circuits. For each natural frequency of the structure under consideration, a sequence of images is captured asynchronously with the vibrations using the DIC system and the resulting displacement fields are correlated with the excitation signal driving the vibration using a least-squares approach. Three approaches for performing this correlation are outlined, one of which is developed into the algorithm used for processing the present results to obtain the amplitude and phase of the vibration at each point on the specimen, allowing the deflected shape to be reconstructed. This process is illustrated using the example of a vibrating aluminium plate. The resulting shapes and frequencies agree well with finite element modal analyses of the plate. [ABSTRACT FROM AUTHOR]

Published

2016