Fiber-Optic Sensor Applications in Civil and Geotechnical Engineering

Wolfgang R. HABEL; Katerina KREBBER

doi:10.1007/s13320-011-0011-x

[1] M. Schallert, J. Stahlmann, and W. R. Habel, “Strukturintegrierter faseroptischer Mikrodehnungsaufnehmer für die Bewertung von Betonpfahlen mit dynamischen Pfahlprüfmethoden,” (Structureintegrated fiber-optic microstrain sensor for evalutation of concrete piles by means of dynamic pile testing methods), in Messen in der Geotechnik 2010, Scientific series published by Technical University of Braunschweig, Inst. for Foundation Engineering and Soil Mechanics, Braunschweig, pp. 265-286, 2010.

[2] M. Schallert, W. R. Habel, I. Gobel, J. Stahlmann, and P. Wardinghus, “Dynamic, and static testing of concrete foundation piles with structure-integrated fiber optic sensors,” in Proc. of the 8th International Conference on Application of stress wave theory to piles, Lisbon, Portugal, September, pp. 625-635, 2008.

[3] M. Schallert, W. R. Habel, and D. Hofmann, Strukturanalyse von Betonpfahlen durch eingebettete faseroptische Sensoren (Analysis of Concrete Foundation Piles Using Structure-Integrated Fiber-Optic Sensors in tm-Technisches Messen, vol. 75. München: Oldenbourg-Verlag, 2008, pp. 485-500.

[4] W. R. Habel and T. Gutmann, “Embedded Quasi-distributed Fiber Optic Sensors for Long-term Monitoring of 4,500 kN Rock Anchors in the Eder Gravity Dam in Germany,” in Proc. of SHMII-2 Conference, Shenzhen, China, BALKEMA Taylor & Francis, vol. 1, pp. 289-297, 2006.

[5] N. Nother, A. Wosniok, K. Krebber, and E. Thiele, “A Distributed fiber optic sensor system for dike monitoring using Brillouin optical frequency domain analysis,” in Proc. Conf. on Smart Structures and Materials, SPIE, San Diego, USA, 2008, vol. 6933, pp. 69330T-1-69330T-9.

[6] A. Wosniok, N. Nother, K. Krebber, and E. Thiele, “Distributed monitoring of mechanical deformation in river dikes,” in Proc. of the Conf. Eurosensors XXII Dresden, Düsseldorf: VDI-Verlag, 2008, pp. 1457-1460.

[7] P. Lenke, S. Liehr, K. Krebber, F. Weigand, and E. Thiele, “Distributed strain measurement with polymer optical fiber integrated in technical textiles using the optical time domain reflectometry technique,” In Proc. of the 16th International POF Conference, Turin, Italy, Sept., pp. 21-24, 2007.

[8] S. Liehr, M. Wendt, and K. Krebber, “Distributed strain measurement in perfluorinated polymer optical fibers using optical frequency domain reflectometry,” Meas. Sci. Technol., vol. 21, no. 9, pp. 094023-1-094023-6, 2010.

[9] S. Liehr, P. Lenke, M. Wendt, K. Krebber, M. Seeger, E. Thiele, H. Metschies, B. Gebreselassie, and J. C. Muenich, “Polymer Optical Fiber Sensor for Distributed Strain Measurement and Application in Structural Health Monitoring,” IEEE Sensors J., vol. 9, no. 11, pp.1330-1338, 2009.

[10] P. Lenke, S. Liehr, and K. Krebber, “Improvements of the distributed strain sensor based on optical time domain reflectometry measurement in polymer optical fibers,” presented at Proc. 17th Intern. Conf. on Plastic Optical Fibers, Santa Clara, USA, 2008.

[11] K. Krebber, P. Lenke, S. Liehr, et al., “Technology and Application of Smart Technical Textiles Based on POF,” presented at Proc. 17th Intern. Conf. on Plastic Optical Fibers, Santa Clara, USA, 2008.

[12] N. Dantan and W. R. Habel, “Monitoring of corrosion protection — a concrete-embeddable pH optode,” in BFT International-Concrete Plant + Precast Technology (Betonwerk+Fertigteiltechnik) Bau Verlag - Springer Science + Business Media, vol. 72, pp. 48-55, 2006.