Extrinsic Fabry–Perot interferometer vibration and acoustic sensor systems for airport ground traffic monitoring
Extrinsic Fabry–Perot interferometer vibration and acoustic sensor systems for airport ground traffic monitoring
- Author(s): N. Fürstenau ; M. Schmidt ; H. Horack ; W. Goetze ; W. Schmidt
- DOI: 10.1049/ip-opt:19971268
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- Author(s): N. Fürstenau 1 ; M. Schmidt 1 ; H. Horack 1 ; W. Goetze 1 ; W. Schmidt 1
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View affiliations
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Affiliations:
1: German Aerospace Research Establishment (DLR), Institute of Flight Guidance, Braunschweig, Germany
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Affiliations:
1: German Aerospace Research Establishment (DLR), Institute of Flight Guidance, Braunschweig, Germany
- Source:
Volume 144, Issue 3,
June 1997,
p.
134 – 144
DOI: 10.1049/ip-opt:19971268 , Print ISSN 1350-2433, Online ISSN 1359-7078
The authors describe new fibre optic vibrational and acoustic sensor systems developed for airport ground traffic monitoring. The theoretical background of the extrinsic Fabry–Perot interferometer (EFPI) sensors is derived, and results of laboratory experiments as well as initial field tests in an experimental surface movement guidance and control system (ESMGCS) at the Braunschweig airport are reported.
Inspec keywords: fibre optic sensors; monitoring; vibration measurement; acousto-optical devices; air traffic control; acoustic variables measurement; Fabry-Perot interferometers
Other keywords:
Subjects: Measurement of mechanical variables; Optical interferometry; Acousto-optical devices; Fibre optic sensors; Fibre optic sensors; fibre gyros; Air traffic control and navigation; Mechanical variables measurement; Fibre optic sensors; Measurement of acoustic variables; Aerospace control; Other nonelectric variables measurement
References
-
-
1)
- L. Meirovitch . (1975) Elements of vibration analysis.
-
2)
- Nano, H., Matsumoto, M., Fujimura, K., Hattori, K.: `Fiber-optic microphone using a Fabry–Perotinterferometer', Proceedings of 9th international conference on Optical fibersensors (OFS-9), 1993, Florenz, p. 155–158.
-
3)
- A.D. Kersey , M. Corke , D.A. Jackson . Linearized polarimetric fibre sensor using a heterodyne-type signalrecovery scheme. Electron. Lett. , 209 - 210
-
4)
- Kruschwitz, B., Claus, R.O., Murphy, K.A., May, R.G., Gunther, M.F.: `Optical fiber sensors for thequantitative measurement of strain in concrete structures', 1st European conference on Smart structures andmaterials, Proc. SPIE, 1994, 2361, Bellingham, Washington, p. 241–244.
-
5)
- Fürstenau, N.: ‘Setup of fiber-optic two-beaminterferometersand investigations on the strain andtemperature sensitivity’. European Space Agency, technical translation, Vol. 980, Sept. 1986, translationof: DFVLR-FB 85-56, pp. 20–22.
-
6)
- Dandridge, A.: `The development of fiber optic sensor systems', 10th Optical fiber sensor conference,Proc. SPIE, 1994, 2360, Glasgow, Scotland, p. 154–161.
-
7)
- R.D. Turner , D.G. Laurin , R.M. Measures . Localized dual-wavelength fiber-optic polarimeter for themeasurement of structural strain and orientation. Appl. Opt. , 2994 - 3003
-
8)
- A. Tardy , M. Jurczyszyn , J.-M. Caussignac , G. Morel , G. Briant . High sensitivity transducer for fiber-opticpressure sensing applied to dynamic mechanical testing and vehicle detection on roads. Springer Proc. Phys. , 215 - 221
-
9)
- Dippe, D.: `Elements and functions of the future airport ground movement managementsystem', Proceedings of Colloquium, ‘From sensors to situationassessment’, p. 23–35DLR-Mitteilung 96-02, .
-
10)
- M. Born , E. Wolf . (1975) Principles of optics.
-
11)
- Y.N. Ning , K.T.V. Grattan , A.W. Palmer . Fibre-optic interferometric systems using low-coherence lightsources. Sens. Actuators , 181 - 192
-
12)
- S.K. Sheem , T.G. Giallorenzi , K. Koo . Optical techniques to solve the signal fading problem in fiberinterferometers. Appl. Opt. , 689 - 693
-
13)
- K.A. Murphy , M.F. Gunther , A.M. Vengsarkar , R.O. Claus . Quadrature phase shifted extrinsic Fabry–Perotoptical fiber sensors. Opt. Lett. , 273 - 275
-
14)
- EUROCAE Working Group, : `Surface movement guidance and control systems', 41, Interim report, 1993, p. 104–109.
-
15)
- W. Beitz , K.-H. Küttner . (1987) Taschenbuch für den Maschinenbau.
-
16)
- L.B. Jeunhomme . Single-mode fiber optics. Opt. Eng. , 97 - 103
-
17)
- Measures, R., Alavie, T., Maaskant, R., Huang, S., LeBlanc, M.: `Bragg grating fiber optic sensing forbridges and other structures', 2nd European conference on Smart structures and materials,Proc. SPIE, 1994, 2361, Bellingham, Washington, p. 162–167.
-
18)
- A. Ezbiri , R.P. Tatam . Passive signal processing for a miniature Fabry–Perot interferometricsensor witha multimode laserdiode source. Opt. Lett. , 1818 - 1820
-
1)