Laser Doppler vibrometer

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A laser Doppler vibrometer (LDV) is a scientific instrument that is used to make non-contact vibration measurements of a surface. The laser beam from the LDV is directed at the surface of interest, and the vibration amplitude and frequency are extracted from the Doppler shift of the reflected laser beam frequency due to the motion of the surface. The output of an LDV is generally a continuous analog voltage that is directly proportional to the target velocity component along the direction of the laser beam.

Basic components of a laser Doppler vibrometer

Some advantages of an LDV over similar measurement devices such as an accelerometer are that the LDV can be directed at targets that are difficult to access, or that may be too small or too hot to attach a physical transducer. Also, the LDV makes the vibration measurement without mass-loading the target, which is especially important for MEMS devices.

Principles of operation

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A vibrometer is generally a two beam laser interferometer that measures the frequency (or phase) difference between an internal reference beam and a test beam. The most common type of laser in an LDV is the helium–neon laser, although laser diodes, fiber lasers, and Nd:YAG lasers are also used. The test beam is directed to the target, and scattered light from the target is collected and interfered with the reference beam on a photodetector, typically a photodiode. Most commercial vibrometers work in a heterodyne regime by adding a known frequency shift (typically 30–40 MHz) to one of the beams. This frequency shift is usually generated by a Bragg cell, or acousto-optic modulator.[1]

A schematic of a typical laser vibrometer is shown above. The beam from the laser, which has a frequency fo, is divided into a reference beam and a test beam with a beamsplitter. The test beam then passes through the Bragg cell, which adds a frequency shift fb. This frequency shifted beam then is directed to the target. The motion of the target adds a Doppler shift to the beam given by fd = 2*v(t)*cos(α)/λ, where v(t) is the velocity of the target as a function of time, α is the angle between the laser beam and the velocity vector, and λ is the wavelength of the light.

Light scatters from the target in all directions, but some portion of the light is collected by the LDV and reflected by the beamsplitter to the photodetector. This light has a frequency equal to fo + fb + fd. This scattered light is combined with the reference beam at the photo-detector. The initial frequency of the laser is very high (> 1014 Hz), which is higher than the response of the detector. The detector does respond, however, to the beat frequency between the two beams, which is at fb + fd (typically in the tens of MHz range).

The output of the photodetector is a standard frequency modulated (FM) signal, with the Bragg cell frequency as the carrier frequency, and the Doppler shift as the modulation frequency. This signal can be demodulated to derive the velocity vs. time of the vibrating target.

Applications

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LDVs are used in a wide variety of scientific, industrial, and medical applications. Some examples are provided below:

  • Aerospace – LDVs are being used as tools in non-destructive inspection of aircraft components.[2]
  • Acoustic – LDVs are standard tools for speaker design, and have also been used to diagnose the performance of musical instruments.[3]
  • Architectural – LDVs are being used for bridge and structure vibration tests.[4]
  • Automotive – LDVs have been used extensively in many automotive applications, such as structural dynamics, brake diagnostics, and quantification of Noise, vibration, and harshness (NVH), measurement of accurate speed.[5]
  • Biological – LDVs have been used for diverse applications such as eardrum diagnostics[6] and insect communication.[7]
  • Calibration – Since LDVs measure motion that can be calibrated directly to the wavelength of light, they are frequently used to calibrate other types of transducers.[8]
  • Hard disk drive diagnostics – LDVs have been used extensively in the analysis of hard disk drives, specifically in the area of head positioning.[9]
  • Dental Devices - LDVs are used in the dental industry to measure the vibration signature of dental scalers to improve vibration quality.[10]
  • Landmine detection – LDVs have shown great promise in the detection of buried landmines. The technique uses an audio source such as a loudspeaker to excite the ground, causing the ground to vibrate a very small amount with the LDV used to measure the amplitude of the ground vibrations. Areas above a buried mine show an enhanced ground velocity at the resonance frequency of the mine-soil system. Mine detection with single-beam scanning LDVs,[11] an array of LDVs,[12] and multi-beam LDVs[13] has been demonstrated.
  • Security – Laser Doppler vibrometers (LDVs) as non-contact vibration sensors have an ability of remote voice acquisition. With the assistance of a visual sensor (camera), various targets in the environment, where an audio event takes place, can be selected as reflecting surfaces for collecting acoustic signals by an LDV. The performance of the LDV greatly depends on the vibration characteristics of the selected targets (surfaces) in the scene, on which a laser beam strikes and from which it returns.[14]
  • Materials Research – Due to the non-contact method, Laser Vibrometers, especially Laser Scanning Vibrometers, can measure surface vibrations of modern materials like carbon plates. The vibration information can help identify and study defects as materials with defects will show a different vibration profile compared to materials without defect.[15]

Types

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  • Single-point vibrometers – This is the most common type of LDV.[16] It can measure one directional out of plane movement.[17]
  • Scanning vibrometers – A scanning LDV adds a set of X-Y scanning mirrors, allowing the single laser beam to be moved across the surface of interest.
  • Holographic laser Doppler vibrometry (HLDV) – An extended-illumination LDV that relies on digital holography for image rendering to capture the motion of a surface at many points simultaneously.[18][19]
 
holographic vibrometry of the cantilevers of a musical box by frequency-division multiplexing [18][19]
  • 3-D vibrometers – A standard LDV measures the velocity of the target along the direction of the laser beam. To measure all three components of the target's velocity, a 3-D vibrometer measures a location with three independent beams, which strike the target from three different directions. This allows a determination of the complete in-plane and out-of-plane velocity of the target.[20]
  • Rotational vibrometers – A rotational LDV is used to measure rotational or angular velocity.
  • Differential vibrometers – A differential LDV measures the out-of-plane velocity difference between two locations on the target.
  • Multi-beam vibrometers – A multi-beam LDV measures the target velocity at several locations simultaneously.
  • Self-mixing vibrometers – Simple LDV configuration with ultra-compact optical head.[21] These are generally based on a laser diode with a built-in photodetector.[22][23]
  • Continuous scan laser Doppler vibrometry (CSLDV) – A modified LDV that sweeps the laser continuously across the surface of the test specimen to capture the motion of a surface at many points simultaneously

See also

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References

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  1. ^ Lutzmann, Peter; Göhler, Benjamin; Hill, Chris A.; Putten, Frank van (2016). "Laser vibration sensing at Fraunhofer IOSB: review and applications". Optical Engineering. 56 (3): 031215. Bibcode:2017OptEn..56c1215L. doi:10.1117/1.OE.56.3.031215. ISSN 0091-3286. S2CID 125618909.
  2. ^ Kilpatrick, James M.; Markov, Vladimir (2008). "<title>Matrix laser vibrometer for transient modal imaging and rapid nondestructive testing</title>". In Tomasini, Enrico P (ed.). Eighth International Conference on Vibration Measurements by Laser Techniques: Advances and Applications. Vol. 7098. p. 709809. doi:10.1117/12.802929. S2CID 109520649.
  3. ^ Bissinger, George.; Oliver, David (July 2007). "3-D Laser Vibrometry on Legendary Old Italian Violins" (PDF). Sound and Vibration. Retrieved 2013-01-24.
  4. ^ GmbH, Polytec. "Civil Engineering". www.polytec.com.
  5. ^ Baldini, Francesco; Moir, Christopher I.; Homola, Jiri; Lieberman, Robert A. (2009). "Miniature laser doppler velocimetry systems". In Baldini, Francesco; Homola, Jiri; Lieberman, Robert A (eds.). Optical Sensors 2009. Vol. 7356. pp. 73560I–73560I–12. doi:10.1117/12.819324. S2CID 123294042.
  6. ^ Huber, Alexander M; Schwab, C; Linder, T; Stoeckli, SJ; Ferrazzini, M; Dillier, N; Fisch, U (2001). "Evaluation of eardrum laser doppler interferometry as a diagnostic tool" (PDF). The Laryngoscope. 111 (3): 501–7. doi:10.1097/00005537-200103000-00022. PMID 11224783. S2CID 8296563.
  7. ^ Fonseca, P.J.; Popov, A.V. (1994). "Sound radiation in a cicada: the role of different structures". Journal of Comparative Physiology A. 175 (3). doi:10.1007/BF00192994. S2CID 22549133.
  8. ^ Sutton, C. M. (1990). "Accelerometer Calibration by Dynamic Position Measurement Using Heterodyne Laser Interferometry". Metrologia. 27 (3): 133–138. Bibcode:1990Metro..27..133S. doi:10.1088/0026-1394/27/3/004. S2CID 250757084.
  9. ^ Abdullah Al Mamun; GuoXiao Guo; Chao Bi (2007). Hard Disk Drive: Mechatronics And Control. CRC Press. ISBN 978-0-8493-7253-7. Retrieved 24 January 2013.
  10. ^ "Vibrations Inc. – Laser Doppler Vibrometers". www.vibrationsinc.com.
  11. ^ Xiang, Ning; Sabatier, James M. (2000). "<title>Land mine detection measurements using acoustic-to-seismic coupling</title>". In Dubey, Abinash C; Harvey, James F; Broach, J. Thomas; et al. (eds.). Detection and Remediation Technologies for Mines and Minelike Targets V. Vol. 4038. p. 645. doi:10.1117/12.396292. S2CID 12131129.
  12. ^ Burgett, Richard D.; Bradley, Marshall R.; Duncan, Michael; Melton, Jason; Lal, Amit K.; Aranchuk, Vyacheslav; Hess, Cecil F.; Sabatier, James M.; Xiang, Ning (2003). "Mobile mounted laser Doppler vibrometer array for acoustic landmine detection". In Harmon, Russell S; Holloway, Jr, John H; Broach, J. T (eds.). Detection and Remediation Technologies for Mines and Minelike Targets VIII. Vol. 5089. p. 665. doi:10.1117/12.487186. S2CID 62559102.
  13. ^ Lal, Amit; Aranchuk, Slava; Doushkina, Valentina; Hurtado, Ernesto; Hess, Cecil; Kilpatrick, Jim; l'Esperance, Drew; Luo, Nan; Markov, Vladimir (2006). "<title>Advanced LDV instruments for buried landmine detection</title>". In Broach, J. Thomas; Harmon, Russell S; Holloway, Jr, John H (eds.). Detection and Remediation Technologies for Mines and Minelike Targets XI. Vol. 6217. p. 621715. doi:10.1117/12.668927. S2CID 62566351.
  14. ^ Rui Li; Tao Wang; Zhigang Zhu; Wen Xiao (2011). "Vibration Characteristics of Various Surfaces Using an LDV for Long-Range Voice Acquisition". IEEE Sensors Journal. 11 (6): 1415. Bibcode:2011ISenJ..11.1415L. doi:10.1109/JSEN.2010.2093125. S2CID 37916336.
  15. ^ Polytec, GmbH. "Material Research". www.polytec.com.
  16. ^ Laura Rodríguez, High temperature surface measurement with Aries Laser Vibrometer, VELA. Original paper presented at AIVELA Conferences 2012.June 2012.
  17. ^ "Single-Point Vibrometers".
  18. ^ a b Verrier, Nicolas and Atlan, Michael. Optics Letters 5 (2013); https://doi.org/10.1364/ol.38.000739; https://arxiv.org/abs/1211.5328
  19. ^ a b François Bruno, Jérôme Laurent, Daniel Royer, and Michael Atlan. Appl. Phys. Lett. 104, 083504 (2014); https://doi.org/10.1063/1.4866390; https://arxiv.org/abs/1401.5344
  20. ^ Jorge Fernández Heredero, 3D Vibration Measurement using LSV. Original paper presented at AdMet 2012.February 2012.
  21. ^ "OMS – Laser Doppler Vibrometers". www.omscorporation.com.
  22. ^ Scalise, Lorenzo; Paone, Nicola (2000). "Self-mixing laser Doppler vibrometer". In Tomasini, Enrico P (ed.). Fourth International Conference on Vibration Measurements by Laser Techniques: Advances and Applications. Vol. 4072. pp. 25–36. doi:10.1117/12.386763. S2CID 119778488.
  23. ^ Heterodyned self-mixing laser diode vibrometer – US Patent 5838439 Archived 2011-06-12 at the Wayback Machine. Issued on November 17, 1998. Patentstorm.us. Retrieved on 2013-06-17.
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