A Fabry-Ṕrot fiber-optic ultrasonic hydrophone for the simultaneous measurement of temperature and acoustic pressure

Journal of the Acoustical Society of America

Volumn 125, Issue 6, 2009, Pages 3611-3622

  Morris, Paul ^a   Hurrell, Andrew ^b   Shaw, Adam ^c   Zhang, Edward ^a   Beard, Paul ^a  

^a UNIVERSITY COLLEGE LONDON   (United Kingdom)

^b Precision Acoustics Ltd   (United Kingdom)

^c NATIONAL PHYSICAL LABORATORY   (United Kingdom)

Author keywords

[No Author keywords available]

Indexed keywords

ACOUSTIC BANDWIDTH; ACOUSTIC PRESSURES; ACOUSTIC WAVEFORM; DUAL SENSING; ELECTROMAGNETIC INTERFERENCE; EQUIVALENT PRESSURE; HIGH INTENSITY FOCUSED ULTRASOUND; HIGH-INTENSITY FIELDS; INDUCED HEATING; INDUCED TEMPERATURE; MEASUREMENT BANDWIDTH; SIMULTANEOUS MEASUREMENT; SINGLE-MODE OPTICAL FIBER; TEMPERATURE CHANGES; THERMAL MEASUREMENTS; TISSUE MIMICKING PHANTOM; TRANSDUCTION MECHANISM; ULTRASONIC HYDROPHONE; ULTRASOUND FIELDS; VISCOUS HEATING;

ACOUSTIC WAVES; ELECTROMAGNETIC PULSE; FIBER OPTICS; HEATING; HYDROPHONES; OPTICAL FIBERS; POLYMER FILMS; SENSORS; ULTRASONIC APPLICATIONS; ULTRASONIC MEASUREMENT; ULTRASONICS;

ACOUSTIC FIELDS;

POLYMER;

ACOUSTICS; ARTICLE; ELECTROMAGNETIC FIELD; FIBER OPTICS; HEATING; HIGH INTENSITY FOCUSED ULTRASOUND; INTERFEROMETER; PIEZOELECTRICITY; PRIORITY JOURNAL; SENSOR; SOUND PRESSURE; TEMPERATURE MEASUREMENT; ULTRASONIC HYDROPHONE; ULTRASOUND; ALGORITHM; EQUIPMENT DESIGN; IMAGE QUALITY; INSTRUMENTATION; METHODOLOGY; PRESSURE; TEMPERATURE; TIME;

ACOUSTICS; ALGORITHMS; EQUIPMENT DESIGN; FIBER OPTIC TECHNOLOGY; HEATING; PHANTOMS, IMAGING; PRESSURE; TEMPERATURE; TIME FACTORS; ULTRASONICS;

EID: 67649126703     PISSN: 00014966     EISSN: None     Source Type: Journal    
DOI: 10.1121/1.3117437     Document Type: Article

References (34)

1. G. Harris, " Progress in medical ultrasound exposimetry.," IEEE Trans. Ultrason. Ferroelectr. Freq. Control 0885-3010 52, 717-736 (2005). 10.1109/TUFFC.2005.1503960
2. W. J. Fry and R. B. Fry, " Determination of absolute sound levels and acoustic absorption coefficients by thermocouple probes-Theory.," J. Acoust. Soc. Am. 0001-4966 26, 294-310 (1954). 10.1121/1.1907332
3. C. C. Coussios, C. H. Farny, G. T. Haar, and R. A. Roy, " Role of acoustic cavitation in the delivery and monitoring of cancer treatment by high-intensity focused ultrasound (HIFU).," Int. J. Hyperthermia 0265-6736 23, 105-120 (2007). 10.1080/02656730701194131
4. H. Morris, I. Rivens, A. Shaw, and G. ter Haar, " Investigation of the viscous heating artefact arising from the use of thermocouples in a focused ultrasound field.," Phys. Med. Biol. 0031-9155 53, 4759-4776 (2008). 10.1088/0031-9155/53/17/020
5. D. R. Bacon and A. Shaw, " Experimental validation of predicted temperature rises in tissue-mimicking materials.," Phys. Med. Biol. 0031-9155 38, 1647-1659 (1993). 10.1088/0031-9155/38/11/010 (Pubitemid 23332895)
6. A. Shaw, N. M. Pay, R. C. Preston, and A. D. Bond, " Proposed standard thermal test object for medical ultrasound.," Ultrasound Med. Biol. 0301-5629 25, 121-132 (1999). 10.1016/S0301-5629(98)00136-7
7. IEC, " IEC62306 Ultrasonics-field characterization-test objects for determining temperature elevation in diagnostic ultrasound fields.," International Electrotechnical Commission, Geneva, 2006.
8. R. L. Phillips, " Proposed fiberoptic acoustical probe.," Opt. Lett. 0146-9592 5, 318-320 (1980). 10.1364/OL.5.000318
9. J. Staudenraus and W. Eisenmenger, " Fiberoptic probe hydrophone for ultrasonic and shock-wave measurements in water.," Ultrasonics 0041-624X 31, 267-273 (1993). 10.1016/0041-624X(93)90020-Z
10. C. Wurster, J. Staudenraus, and W. Eisenmenger, " The fiber optic probe hydrophone.," Proc.-IEEE Ultrason. Symp. 1051-0117 2, 941-944 (1994).
11. P. A. Lewin, S. Umchid, A. Sutin, and A. Sarvazyan, " Beyond 40 MHz frontier: The future technologies for calibration and sensing of acoustic fields.," J. Phys.: Conf. Ser. 1742-6588 1, 38-43 (2004). 10.1088/1742-6596/1/1/010
12. J. E. Parsons, C. A. Cain, and J. B. Fowlkes, " Cost-effective assembly of a basic fiber-optic hydrophone for measurement of high-amplitude therapeutic ultrasound fields.," J. Acoust. Soc. Am. 0001-4966 119, 1432-1440 (2006). 10.1121/1.2166708
13. V. A. Leitao, W. N. Simmons, Y. F. Zhou, J. Qin, G. Sankin, F. H. Cocks, J. Fehre, B. Granz, R. Nanke, G. M. Preminger, and P. Zhong, " Comparison of light spot hydrophone (LSHD) and fiber optic probe hydrophone (FOPH) for lithotripter field characterization.," Renal Stone Disease 900, 377-380 (2007).
14. V. Wilkens and C. Koch, " Fiber-optic multilayer hydrophone for ultrasonic measurement.," Ultrasonics 0041-624X 37, 45-49 (1999). 10.1016/S0041-624X(98)00037-7
15. V. Wilkens, " Characterization of an optical multilayer hydrophone with constant frequency response in the range from 1 to 75 MHz.," J. Acoust. Soc. Am. 0001-4966 113, 1431-1438 (2003). 10.1121/1.1553457
16. V. Wilkens, C. Wiemann, C. Koch, and H. J. Foth, " Fiber-optic dielectric multilayer temperature sensor: In situ measurement in vitreous during Er:YAG laser irradiation.," Opt. Laser Technol. 0030-3992 31, 593-599 (1999). 10.1016/S0030-3992(00)00004-9
17. P. C. Beard and T. N. Mills, " Extrinsic optical-fiber ultrasound sensor using a thin polymer film as a low-finesse Fabry-Ṕrot interferometer.," Appl. Opt. 0003-6935 35, 663-675 (1996). 10.1364/AO.35.000663 (Pubitemid 126645012)
18. P. C. Beard and T. N. Mills, " Miniature optical fibre ultrasonic hydrophone using a Fabry-Ṕrot polymer film interferometer.," Electron. Lett. 0013-5194 33, 801-803 (1997). 10.1049/el:19970545 (Pubitemid 127598056)
19. Y. Uno and K. Nakamura, " Pressure sensitivity of a fiber-optic microprobe for high-frequency ultrasonic field.," Jpn. J. Appl. Phys., Part 1 0021-4922 38, 3120-3123 (1999). 10.1143/JJAP.38.3120 (Pubitemid 30514505)
20. P. Beard, A. Hurrell, and T. Mills, " Characterization of a polymer film optical fiber hydrophone for use in the range 1 to 20 MHz: A comparison with PVDF needle and membrane hydrophones.," IEEE Trans. Ultrason. Ferroelectr. Freq. Control 0885-3010 47, 256-264 (2000). 10.1109/58.818769
21. J. M. Vaughan, The Fabry-Ṕrot Interferometer: History, Theory, Practice and Applications (Hilger, London, 1989).
22. J. G. Laufer, P. C. Beard, S. P. Walker, and T. N. Mills, " Photothermal determination of optical coefficients of tissue phantoms using an optical fibre probe.," Phys. Med. Biol. 0031-9155 46, 2515-2530 (2001). 10.1088/0031-9155/46/10/301
23. P. Morris, P. Morris, A. Hurrell, E. Zhang, S. Rajagopal, and P. Beard, " A Fabry-Ṕrot fibre-optic hydrophone for the measurement of ultrasound induced temperature change.," Proc.-IEEE Ultrason. Symp. 1051-0117, 536-539 (2006).
24. P. Morris, " A Fabry-Ṕrot fibre-optic hydrophone for the characterisation of ultrasound fields.," Ph.D. thesis, University College London, London (2008).
25. B. T. Cox and P. C. Beard, " The frequency-dependent directivity of a planar Fabry-Ṕrot polymer film ultrasound sensor.," IEEE Trans. Ultrason. Ferroelectr. Freq. Control 0885-3010 54, 394-404 (2007). 10.1109/TUFFC.2007.253
26. P. C. Beard, F. Perennes, E. Draguioti, and T. N. Mills, " Optical fiber photoacoustic-photothermal probe.," Opt. Lett. 0146-9592 23, 1235-1237 (1998). 10.1364/OL.23.001235 (Pubitemid 128597718)
27. K. Nakamura and K. Nimura, " Measurements of ultrasonic field and temperature by a fiber optic microprobe.," J. Acoust. Soc. Jpn. E 21, 267-269 (2000). 10.1250/ast.21.267 0388-2861
28. SCS, " Parylene properties.," www.scscoatings.com (2008), URL http://www.scscoatings.com/docs/coatspec.pdf (date last viewed 4/20/09).
29. Z. Y. Zhang, P. Zhao, P. Lin, and F. G. Sun, " Thermo-optic coefficients of polymers for optical waveguide applications.," Polymer 0032-3861 47, 4893-4896 (2006). 10.1016/j.polymer.2006.05.035
30. R. A. Smith and D. R. Bacon, " A multiple-frequency hydrophone calibration technique.," J. Acoust. Soc. Am. 0001-4966 87, 2231-2243 (1990). 10.1121/1.399191
31. R. O. Ebewele, Polymer Science and Technology (CRC, Boca Raton, FL, 1996).
32. E. Z. Zhang and P. Beard, " Broadband ultrasound field mapping system using a wavelength tuned, optically scanned focused laser beam to address a Fabry-Ṕrot polymer film sensor.," IEEE Trans. Ultrason. Ferroelectr. Freq. Control 0885-3010 53, 1330-1338 (2006). 10.1109/TUFFC.2006. 1665081
33. P. Morris, P. Beard, and A. Hurrell, " Development of a 50 MHz optical fibre hydrophone for the characterisation of medical ultrasound fields.," Proc.-IEEE Ultrason. Symp. 3, 1747-1750 (2005). (Pubitemid 46285160)
34. E. Zhang, J. G. Laufer, and P. Beard, " Backward-mode multiwavelength photoacoustic scanner using a planar Fabry-Ṕrot polymer film ultrasound sensor for high resolution three-dimensional imaging of biological tissues.," Appl. Opt. 0003-6935 47, 561-577 (2008). 10.1364/AO.47.000561