Forthcoming IOP Conferences
 

Programme: Thursday, 8 October

SESSION Th-01: Chemical, Environmental, Biological, and Medical Sensors
Chairs: Anna Grazia Mignani, Istituto di Fisica Applicata Nello Carrara (Italy); Robert Lieberman, Intelligent Optical Systems Inc. (USA)
Room: TBD

9:30 amApplications of hollow-core photonic syrstal fiber in bio- and chemical sensing (Invited Paper, Presentation Only), Kevin P. Chen, Univ. of Pittsburgh (United States) [OF101‑168]
10:00 am Experimental verification of the effect of slow light on molecular absorption, Luc Thevenaz, Sanghoon Chin, Isabelle Dicaire, Jean-Charles Beugnot, Stella Foaleng Mafang, Ecole Polytechnique Fédérale de Lausanne (Switzerland); Miguel González Herráez, Universidad de Alcalá (Spain) [OF101‑169]
10:12 amIn-vivo 4D imaging of the human lower airway using anatomical optical coherence tomography, Robert A. McLaughlin, The Univ. of Western Australia (Australia); Jonathan P. Williamson, Sir Charles Gairdner Hospital (Australia) and University of Western Australia (Australia); Andrea Curatolo, University of Western Australia (Australia); Vanessa A. Baker, David H. Hillman, Sir Charles Gairdner Hospital (Australia); Peter R. Eastwood, Sir Charles Gairdner Hospital (Australia) and University of Western Australia (Australia); David D. Sampson, The Univ. of Western Australia (Australia) [OF101‑170]
10:24 amHigh-speed imaging with endoscopic optical coherence tomography using bending vibration of optical fiber, Ryoichi Isago, Kentaro Nakamura, Tokyo Institute of Technology (Japan) [OF101‑171]
10:36 amDynamic analysis of laser ablation of biological tissue by real-time imaging of optical coherence tomography, Masato Ohmi, Makoto Ohnishi, Daisuke Takada, Masamitsu Haruna, Osaka Univ. (Japan) [OF101‑172]
10:48 am to 11:00 amRemote methane sensor using tuneable diode laser spectroscopy (TDLS) via a 1W Raman source, David M. Mitchell, Kevin Duffin, Walter Johnstone, Univ. of Strathclyde (United Kingdom) [OF101‑173]

SESSION Th-02: Interferometric and Polarimetric Sensors
Chairs: Jose L. Santos, Univ. de Porto (Portugal); Yun Jiang Rao, Univ. of Electronic Science & Technology (China)
Room: TBD

11:30 am Large interferometers for small displacements: a technological view of gravitational wave detection(Invited Paper), Stefan Hild, Univ. of Glasgow (United Kingdom) [OF101‑174]
12:00 pmFiber laser strain sensors: enabling a new generation of miniaturized high-erformance sensors, Geoffrey A. Cranch, Naval Research Laboratory (United States); Scott Foster, Defence Science and Technology Laboratory (Australia); Clay K. Kirkendall, Naval Research Lab. (United States) [OF101‑175]
12:12 pmSensitivity improvement of waveguide-type optical passive ring resonator gyroscope by carrier suppression, Huilian Ma, The Univ. of Tokyo (Japan) and Zhejiang University (China); Zuyuan He, Kazuo Hotate, The Univ. of Tokyo (Japan) [OF101‑176]
12:24 pmOptical load sensors utilizing fiber Bragg grating based Fabry-Perot resonators, Xuewen Shu, Kate Sugden, Ian Bennion, Aston Univ. (United Kingdom) [OF101‑177]
12:36 pmLinearized interrogation of FDML FBG sensor system using PMF Sagnac interferometer, Hwidon Lee, Eun Joo Jung, Myung Yung Jeong, Chang Seok Kim, Pusan National Univ. (Korea, Republic of) [OF101‑178]
12:48 pm to 1:00 pmHighly versatile in-reflection photonic crystal fibre interferometer, Rajan Jha, Joel Villatoro, Mark P. Kreuzer, Vittoria Finazzi, Valerio Pruneri, ICFO - Instituto de Ciencias Fotónicas (Spain) [OF101‑179]

SESSION Th-03: Micro and Nano-Engineered Sensors and Devices
Chairs: Hypolito Jose Kalinowski, Ctr. Federal de Educação Tecnológica do Paraná (Brazil); Luc Thevenaz, Ecole Polytechnique Fédérale de Lausanne (Switzerland)
Room: TBD

2:00 pmExposed-core microstructured fibres for real-time fluorescence sensing, Stephen C. Warren-Smith, Heike Ebendorff-Heidepriem, The Univ. of Adelaide (Australia); Tze C. Foo, The University of Adelaide (Australia); Roger Moore, The Univ. of Adelaide (Australia); Claire Davis, Defence Science and Technology Organisation (Australia); Tanya M. Monro, The Univ. of Adelaide (Australia) [OF101‑180]
2:12 pm Microstructured chalcogenide fibers for biological and chemical detection: case study: a CO2 sensor, Laurent Brilland, Plate-forme d'Étude et de Recherche sur les Fibres Optiques Spéciales (France); Frédéric Charpentier, Johann Troles, Bruno Bureau, Catherine Boussard-Plédel, Jean-luc Adam, Univ. de Rennes 1 (France); David Méchin, Denis Trégoat, Plate-forme d'Étude et de Recherche sur les Fibres Optiques Spéciales (France) [OF101‑181]
2:24 pmMiniature fiber optic temperature sensors based on silica/polymer microfiber knot resonators, Yu Wu, Yun-Jiang Rao, Yi-Huai Chen, Univ. of Electronic Science and Technology of China (China) [OF101‑182]
2:36 pmUltrasensitive refractive index sensor based on twin-core photonic bandgap fibers, Wu Yuan, Ole Bang, Technical Univ. of Denmark (Denmark) [OF101‑183]
2:48 pmPhotonic bandgap fiber tapers and interferometric sensors, Jian Ju, Lina Ma, Wei Jin, The Hong Kong Polytechnic Univ. (Hong Kong, China) [OF101‑184]
3:00 pmGas sensing with suspended core fibres and hollow-core band gap fibres: a comparative study, Hartmut Lehmann, Jens Kobelke, Kay Schuster, Reinhardt Willsch, Hartmut Bartelt, IPHT Jena (Germany); Rodrigo Amezcua-Correa, Jonathan C. Knight, Univ. of Bath (United Kingdom) [OF101‑185]
3:12 pmFibre laser using a microchannel-based loss tuning element for refractive index sensing, Chengbo Mou, Kaiming Zhou, Edward Davies, Lin Zhang, Ian Bennion, Aston Univ. (United Kingdom) [OF101‑186]
3:24 pm to 3:30 pmGuidelines for the characterization and use of fibre optic sensors (Announcement),Wolfgang R. Habel, Bundesanstalt für Materialforschung und -prüfung (Germany)

SESSION Th-04: Posters III
Room: TBD

3:30 to 5:30 pm

Guidelines for the characterization and use of fibre optic sensors: basic definitions and a proposed standard for FBG-based strain sensors, Wolfgang R. Habel, Bundesanstalt für Materialforschung und -prüfung (Germany); Ingolf Baumann, AOS GmbH Dresden (Germany); Francis Berghmans, Vrije Univ. Brussel (Belgium); Krzysztof Borzycki, National Institute of Telecommunications (Poland); Christoph Chojetzki, FBGS Technologies GmbH (Germany); Karl-Heinz Haase, Hottinger Baldwin Messtechnik GmbH (Germany); Leszek R. Jaroszewicz, Military Univ. of Technology (Poland); Thomas Kleckers, Hottinger Baldwin Messtechnik GmbH (Germany); Marc Niklès, Omnisens S.A. (Switzerland); Manfred Rothhardt, Institut für Photonische Technologien e.V. (Germany); Vivien Schlüter, Bundesanstalt für Materialforschung und -prüfung (Germany); Luc Thévenaz, Ecole Polytechnique Fédérale de Lausanne (Switzerland); Moshe Tur, Tel-Aviv Univ. (Israel) [OF101‑187]

Fiber Bragg grating strain sensor interrogation with 1.3μm Fourier domain mode-locked wavelength swept laser, Byoung Chang Lee, Min Hyun Oh, Chungnam National Univ. (Korea, Republic of); Eun Joo Jung, Chang-seok Kim, Pusan National Univ. (Korea, Republic of); Min Yong Jeon, Chungnam National Univ. (Korea, Republic of) [OF101‑188]

Bridge external prestressing monitoring based on FBG, Li Sheng, De-sheng Jiang, Wuhan Univ. of Technology (China) [OF101‑189]

FBG application in bridge health monitoring system of Wuhan Yangtze River 2th Bridge, Jun Liu, Wuhan Univ. of Technology (China) [OF101‑190]

Measurement of distributed strain and load identification using 1500mm gauge-ength FBG and optical frequency-domain reflectometry, Hirotaka Igawa, Japan Aerospace Exploration Agency (Japan); Hideaki Murayama, The Univ. of Tokyo (Japan); Toshiya Nakamura, Isao Yamaguchi, Japan Aerospace Exploration Agency (Japan); Kazuro Kageyama, Kiyoshi Uzawa, Daichi Wada, Isamu Ohsawa, Makoto Kanai, The Univ. of Tokyo (Japan); Koji Omichi, Fujikura Ltd. (Japan) [OF101‑191]

Innovative FBG sensing techniques for the railway industry: application to overhead contact line monitoring, Guillaume Laffont, Nicolas Roussel, Stephane Rougeault, Jonathan Boussoir, Laurent Maurin, Pierre Ferdinand, Commissariat à l'Énergie Atomique (France) [OF101‑193]

Superimposed long-period and short-period Bragg grating sensor for LRI monitoring, Sébastien Triollet, Laurent Robert, Ecole des Mines d'Albi (France); Emmanuel Marin, Youcef Ouerdane, Univ. Jean Monnet Saint-Etienne (France) [OF101‑194]

Brillouin optical fiber distributed sensor for settlement monitoring while tunneling the metro line 3 in Cairo, Egypt, Veronique Dewynter, Stéphane Rougeault, Sylvain Magne, Pierre Ferdinand, Commissariat à l'Energie Atomique (France); Francis Vallon, Laurent Avallone, Emmanuel Vacher, Michel De Broissia, Bouygues Travaux Publics (France); Christophe Canepa, Arnaud Poulain, ACOME (France) [OF101‑195]

Response of embedded fibre Bragg gratings: strain transfer effects, Eli J. Voet, Geert Luyckx, Joris Degrieck, Univ. Gent (Belgium) [OF101‑196]

Directional-bend sensor based on asymmetric long-period grating in photonic crystal fiber, Long Jin, The Hong Kong Polytechnic University (Hong Kong, China); Wei Jin, Jian Ju, The Hong Kong Polytechnic Univ. (Hong Kong, China) [OF101‑197]

Benchmarking the response of Bragg gratings written in microstructured and bow tie fiber embedded in composites, Geert Luyckx, Eli Voet, Univ. Gent (Belgium); Thomas Geernaert, Karima Chah, Tomasz A. Nasilowski, Vrije Univ. Brussel (Belgium); Wim De Waele, Univ. Gent (Belgium); Martin Becker, Hartmut Bartelt, IPHT Jena (Germany); Waclaw Urbanczyk, Wroclaw Univ. of Technology (Poland); Jan Wojcik, Univ. Marii Curie-Sklodowskiej (Poland); Joris Degrieck, Univ. Gent (Belgium); Francis Berghmans, Hugo Thienpont, Vrije Univ. Brussel (Belgium) [OF101‑198]

Fiber optic Fabry-Perot refractive-index tip sensor based on endlessly photonic crystal fiber, Ming Deng, Yunjiang Rao, Tao Zhu, Hong Li, Chongqing Univ. (China) [OF101‑199]

Health monitoring of engine blades by using an in-line fiber optic F-P strain sensor based on hollow-core photonic crystal fiber, Yunjiang Rao, Yanen N. Fan, Hong Li, Tao Zhu, Chongqing Univ. (China) [OF101‑200]

Fiber Bragg grating system for continuous large-scale monitoring of convergence in Rossio Tunnel, Cristina Barbosa, FiberSensing (Portugal); Luis Ferreira, Francisco Araújo, FiberSensing (Portugal) and INESC Porto (Portugal); Luis Gonçalves, Empresa Portuguesa de Obras Subterrâneas (Portugal); Carlos D. Gama, Univ. Técnica de Lisboa (Portugal); Rui Malva, Angela Silva, Vitor Freitas, Rede Ferroviária Nacional EPE (Portugal) [OF101‑201]

Technical textiles with embedded fibre Bragg grating sensors, Lucia B. Bilro, Instituto de Engenharia Electrónica e Telemática de Aveiro (Portugal); Hugo Cunha, CITEVE - Technological Centre for the Textile and Clothing Industries of Portugal (Portugal); João Lemnos Pinto, Rogério N. Nogueira, Univ. de Aveiro (Portugal) [OF101‑202]

A miniature fiber optic refractive-index sensor based on laser-machined Fabry-Perot interferometer tip, Zengling Ran, Key Lab of Broadband Optical Fiber Transmission & Communication Networks Technology (Ministry of Edu (United States); Yunjiang Rao, Univ. of Electronic Science and Technology of China (China); Jian Zhang, Bing Xu, Key Lab of Broadband Optical Fiber Transmission & Communication Networks Technology (China) [OF101‑203]

Fiber optic pressure sensor based on polarization-maintaining photonic crystal fiber for downhole application, H. Y. Fu, The Hong Kong Polytechnic University (Hong Kong, China); Chuang Wu, Dalian University of Technology (China); M. L. V. Tse, The Hong Kong Polytechnic University (Hong Kong, China); Lin Zhang, Dalian University of Technology (China); H. Y. Tam, The Hong Kong Polytechnic University (Hong Kong, China); Bai-Ou Guan, Dalian University of Technology (China); C. Lu, P. K. A. Wai, The Hong Kong Polytechnic University (Hong Kong, China) [OF101‑204]

Fluid-filled microstructured optical fibers and switching applications, Yiping Wang, Optoelectronics Research Centre, University of Southampton, Southampton, SO17 1BJ (United Kingdom); Wei Jin, Long Jin, Xiaoling Tan, Department of Electrical Engineering, The Hong Kong Polytechnic University, Kowloon (Hong Kong, China); Hartmut Bartelt, Wolfgang Ecke, Klaus Moerl, Hartmut Lehmann, Jens Kobelke, Kerstin Schroeder, Reinhardt Willsch, Manfred Rothhardt, Liye Shan, Sven Brueckner, Institute of Photonic Technology, Albert-Einstein-Str. 9, 07745 Jena (Germany); David J. Richardson, Optoelectronics Research Centre, University of Southampton, Southampton, SO17 1BJ (United Kingdom) [OF101‑205]

Practical sensitive fluorescence sensing with microstructured fibres, Erik P. Schartner, The Univ. of Adelaide (Australia); Richard White, Steven Warren-Smith, Tanya Monro, The University of Adelaide (Australia) [OF101‑206]

Optical fibre cavity ring down measurement of refractive index with a microchannel drilled by femtosecond laser, Kaiming Zhou, Aston Univ. (United Kingdom); David Webb, Chengbo Mou, Aston University (United Kingdom); Mark Farries, Gooch & Housego Torquay Ltd (United Kingdom); Neil Hayes, EvanesCo Ltd (United Kingdom); Ian Bennion, Aston University (United Kingdom) [OF101‑207]

Phase sensitivity of hollow-core photonic bandgap fiber to acoustic pressure, Pang Meng, Kong Hong Polytechnic University (Hong Kong, China); Wei Jin, Hong Kong Polytechnic University (Hong Kong, China) [OF101‑208]

Highly birefringent suspended-core microstructured fibre for sensing application, Maxim Ryabko, Institute of Radio Engineering and Electronics (Russian Federation); Yurii Chamorovskiy, Vladimir Gubin, Igor' Vorob'ev, Nikolay Starostin, Sergey Nikitov, Sergey Morshnev, Oleg Okhotnikov, [OF101‑210]

Response of a fibre optic long-period grating operating at the phase matching turning point to the deposition of a nanostructured coating, Stephen W. James, S C. Cheung, Stephen M. Topliss, Ralph P. Tatam, Cranfield Univ. (United Kingdom) [OF101‑213]

Low-loss fusion splicing of single-mode fiber and a photonic crystal fiber suitable for construction of a patch cord for measurement devices, Leszek R. Jaroszewicz, Military Univ. of Technology (Poland); Michal Murawski, Karol Stasiewicz, Pawel Marc, Military Univ. of Technoogy (Poland) [OF101‑214]

Photonic crystal fiber pressure sensor, Fernando C. Fávero, Pontifícia Univ. Católica do Rio de Janeiro (Brazil); Sully Quintero, Vinicius Silva, Cicero Martelli, Arthur Braga, Isabel Carvalho, Roberth Llerena, Pontifícia Universidade Católica do Rio de Janeiro (Brazil) [OF101‑215]

Enhancement of temperature measurement by using photonic bandgap effect, Yifan Zhang, Nanyang Technological Univ. (Singapore); Chi Chiu Chan, Jian Sun, Nanyang Technological University (Singapore) [OF101‑217]

Fiber optic surface plasmon resonance sensors with subwavelength metallic gratings: numerical study, Sookyoung Roh, Hwi Kim, Byoungho Lee, Seoul National Univ. (Korea, Republic of) [OF101‑218]

Three-dimensional colloidal crystals microstructure fiber: fabrication and characterization, Haitao Yan, Nanjing Normal Univ. (China); Wang Ming, Ge YiXian, Nanjing Normal University (China); Yu Ping, Nanjing Normal Unversity (China) [OF101‑219]

Optical sampling technique applied to high-resolution distributed fibre sensors, Stella Foaleng-Mafang, Jean-Charles Beugnot, Luc Thevenyz, Ecole Polytechnique Fédérale de Lausanne (Switzerland) [OF101‑220]

General analytical model for distributed Brillouin sensors with submeter spatial resolution, Luc Thevenaz, Jean-Charles Beugnot, Ecole Polytechnique Fédérale de Lausanne (Switzerland) [OF101‑221]

Single-ended distributed temperature or strain sensor based on stimulated Brillouin scattering, Weiwen Zou, Zuyuan He, Kazuo Hotate, The Univ. of Tokyo (Japan) [OF101‑222]

Simultaneous measurement of strain and temperature by means of polarization division multiplexing optical frequency-domain reflectometry, Koji Omichi, Yoshihiro Terada, Akira Sakamoto, Shunichiro Hirafune, Fujikura Ltd. (Japan); Daichi Wada, Hideaki Murayama, The University of Tokyo (Japan); Hirotaka Igawa, Japan Aerospace Exploration Agency (Japan) [OF101‑223]

Distortion-free Brillouin distributed sensor with ultra-low leakage RF pulses, Ander Zornoza, Univ. Publica de Navarra (Spain); David Olier, Mikel Sagues, Alayn Loayssa, Universidad Publica de Navarra (Spain) [OF101‑224]

Temperature-dependent attenuation characteristics of fibers for distributed temperature sensing in hot geothermal wells, Thomas Reinsch, GeoForschungsZentrum Potsdam e.V. (Germany); Jan Henninges, Helmholtz-Centre Potsdam, German Research Centre for Geosciences - GFZ (Germany) [OF101‑225]

Signal-to-noise ratio improvement in Brillouin sensing, Nicolas Linze, Wenhai Li, Xiaoyi Bao, University of Ottawa (Canada) [OF101‑226]

Distributed perfluorinated POF strain sensor using OTDR and OFDR techniques, Sascha Liehr, Mario Wendt, Katerina Krebber, BAM (Germany) [OF101‑227]

Deformation of Brillouin scattered light power spectrum shape by linear strain distribution, Kei Yasuda, Mie Univ. (Japan); Hiroshi Naruse, Mie University (Japan); Li Che Hsien, Neubrex Co., Ltd. (Japan); Mitsuhiro Tateda, Chiba University (Japan) [OF101‑228]

A new model to calculate the Rayleigh scattering profiles in polymer optical fibers for distirbuted strain sensing, Philipp Lenke, Katerina Krebber, Bundesanstalt für Materialforschung und -prüfung (Germany) [OF101‑229]

Regional selectable distributed sensor based on reflected optical pulse correlation measurement, Xunjian Xu, Kochi Univ. of Technology (Japan) [OF101‑230]

Distributed optical fibre sensing of temperature using time-correlated two-photon excited fluorescence, Craig J. Dalzell, Thomas P. J. Han, University of Strathclyde (United Kingdom); Ivan S. Ruddock, Univ. of Strathclyde (United Kingdom) [OF101‑231]

The two-photon absorption cross-section of ruby and distributed crystal fibre sensing, Craig J. Dalzell, Thomas P. J. Han, Ivan S. Ruddock, Univ. of Strathclyde (United Kingdom) [OF101‑232]

Multipoint refractometry using tilted fiber Bragg gratings interrogated by a time-domain technique, Christophe Caucheteur, Marc Wuilpart, Patrice Mégret, Faculté Polytechnique de Mons (Belgium); Jacques Albert, Carleton University (Canada) [OF101‑233]

Simultaneous Brillouin backscattering and Raman spontaneous distributed fiber sensor: analytical and numerical approach, Livia Ribeiro, Instituto Nacional de Pesquisas Espaciais (Brazil); Antonio Toledo, Instituto Nacional de Estudos Espaciais (Brazil) [OF101‑234]

Pipeline monitoring by Brillouin-scattering-based fibre optic distributed strain sensors: pipeline wall thickness detection, Gordon P. Gu, Winston Revie, CANMET Materials Technology Lab (Canada); Lufan Zou, Omur Sezerman, OZ Optics Ltd. (Canada) [OF101‑235]

Demonstration of stable Raman fibre laser with asymmetrical laser cavity including broadband chirped FBG, Young-Eun Im, Gwangju Institute of Science and Technology (Korea, Republic of) and Korea Photonics Technology Institute (Korea, Republic of); Kyungwon Chun, Gwangju Institute of Science and Technology (Korea, Republic of); Hangeul Kim, Swook Hann, Korea Photonics Technology Institute (Korea, Republic of); Dong-Hwan Kim, Doosan Defense and System (Korea, Republic of); Youngjoo Chung, Chang-Soo Park, Gwangju Institute of Science and Technology (Korea, Republic of) [OF101‑236]

Align-and-shine photolithography, Davide Iannuzzi, Audrius Petrusis, Jan H. Rector, Kirsten Smith, Sven de Man, Vrije Univ. Amsterdam (Netherlands) [OF101‑237]

Application of π-shifted short scan interferometry to remote sensing, Ronan O'Byrne, Sergey V. Sergeyev, Waterford Institute of Technology (Ireland) [OF101‑238]

Femtosecond laser-induced refractive index structures in polymer optical fibre (POF) for sensing, Shi-Jie Liang, The Univ. of Manchester (United Kingdom); Patricia Scully, The University of Manchester (United Kingdom); Joerg Schille, University of Applied Sciences Mittweida (Germany); John Vaughan, The University of Manchester (United Kingdom); Walter Perrie, The University of Liverpool (United Kingdom) [OF101‑239]

N-doped-silica-core polarization maintaining fibre for gyros and other sensors for application in space industry, Yuri K. Chamorovskii, Oleg V. Butov, Gennadi I. Ivanov, Alexander O. Kolosovskii, Victor V. Voloshin, Igor L. Vorob'ev, Konstantin M. Golant, Institute of Radio-Engineering and Electronics (Russian Federation) [OF101‑240]

MOEMS accelerometer based on microfiber knot resonator, Yu Wu, Univ. of Electronic Science and Technology of China (China) and Zhejiang Univ. (China); Xu Zeng, Zhejiang Univ. (China); Yun-Jiang Rao, Univ. of Electronic Science and Technology of China (China); Chang-Lun Hou, Guo-Guang Yang, Zhejiang Univ. (China) [OF101‑241]

Novel interrogation technique for tilted fiber Bragg gratings sensors based on single-wavelength time delay measurements, Marco Pisco, Univ. degli Studi del Sannio (Italy); Armando Ricciardi, Univ. of Naples Parthenope (Italy); Stefania Campopiano, Univ. degli Studi di Napoli Parthenope (Italy); Christophe Caucheteur, Patrice Mégret, Faculté Polytechnique de Mons (Belgium); Antonello Cutolo, Andrea Cusano, Univ. degli Studi del Sannio (Italy) [OF101‑242]

Fiber optic refractive index sensor based on cladding-mode resonance, Fufei Pang, Huanhuan Liu, Na Chen, Yunqi Liu, Xianglong Zeng, Zhenyi Chen, Tingyun Wang, Shanghai Univ. (China) [OF101‑243]

Refractive index sensitivity enhancement of 81° tilted Bragg gratings by cladding etching, Edward M. Davies, Pouneh Saffari, Chengbo Mou, Kaiming Zou, Lin Zhang, Ian Bennion, Aston Univ. (United Kingdom) [OF101‑244]

In-fiber Michelson interferometer based on double-cladding fiber for refractive index sensing, Fufei Pang, Huanhuan Liu, Na Chen, Yunqi Liu, Xianglong Zeng, Zhenyi Chen, Tingyun Wang, Shanghai Univ. (China) [OF101‑245]

A tunable high-resolution FBG demodulation system using photonic crystal fiber loop mirrors, Tatiana Bakhvalova, Technical Univ. (Russian Federation); Ginu Rajan, Yuliya Semenova, Gerald Farrell, Dublin Institute of Technology (Ireland) [OF101‑246]

The quest for inexpensive, compact, low-phase noise laser sources for fiber optic sensing applications, Robert E. Bartolo, Alan B. Tveten, Clay Kirkendall, Naval Research Lab. (United States) [OF101‑247]

Regeneration of complex Bragg gratings, Somnath Bandyopadhyay, Central Glass and Ceramic Research Institute (India); John Canning, The Univ. of Sydney (Australia); Palas Biswas, Rijuparna Chakraborty, Kamal Dasgupta, Central Glass and Ceramic Research Institute (India) [OF101‑248]

Capillary optical-fiber linking approach for biosensors, Libo Yuan, Harbin Engineering Univ. (China) [OF101‑249]

Measurement of refractive index profiles variation along a fusion-splicing tapered optical fiber, Meng-Hsun Wan, Lon Alex Wang, National Taiwan Univ. (Taiwan) [OF101‑250]

Fiber Bragg grating cladding-mode resonance liquid-level sensor, Na Chen, Shanghai Univ. (China) and Southeast Univ. (China); Binfeng Yun, Yiping Cui, Southeast Unv. (China) [OF101‑251]

Photo-annealing effects for erbium-doped fiber sources after gamma irradiation tests by using 532nm and 976nm lasers, Tz-Shiuan Peng, Yen-Wei Huang, Lon A. Wang, National Taiwan Univ. (Taiwan); Ren-Young Liu, National Space Organization (Taiwan); Fong-In Chou, National Tsing Hua Univ. (Taiwan) [OF101‑252]

Influence of system configuration on a ratiometric wavelength measurement system, Qiang Wu, Pengfei Wang, Yuliya Semenova, Gerald Farrell, Dublin Institute of Technology (Ireland) [OF101‑253]

Innovative spectroscopy of liquids: a fiber optic supercontinuum source and an integrating cavity for scattering-free absorption measurements, Anna G. Mignani, Istituto di Fisica Applicata Nello Carrara (Italy); Heidi Ottevaere, Vrije Univ. Brussel (Belgium); Leonardo Ciaccheri, Istituto di Fisica Applicata Nello Carrara (Italy); Hugo Thienpont, Vrije Univ. Brussel (Belgium); Ilaria Cacciari, Istituto di Fisica Applicata Nello Carrara (Italy); Olivier Parriaux, Univ. Jean Monnet Saint-Etienne (France); Mark Johnson, Sagentia Ltd. (United Kingdom) [OF101‑254]

Realization of 7-cell hollow-core photonic crystal fibers with low loss in the region between 1.4 µm and 2.3 µm, Jens K. Lyngsoe, Crystal Fibre A/S (Denmark) and DTU Fotonik (Denmark); Brian J. Mangan, Univ. of Bath (United Kingdom); Christian Jakobsen, Crystal Fibre A/S (Denmark); Peter John Roberts, DTU Fotonik (Denmark) [OF101‑255]

A simple method for fabricating phase-shifted fibre Bragg gratings with flexible choice of centre wavelength, Edmon Chehura, Stephen W. James, Ralph Tatam, Cranfield Univ. (United Kingdom) [OF101‑256]

Fiber Bragg grating arrays for high-resolution manometry, Martin Becker, Manfred Rothhardt, Hartmut Bartelt, IPHT Jena (Germany); Sebastian Voigt, Technische Univ. Chemnitz (Germany); Andreas Teubner, Clinical Center Chemnitz GmbH (Germany); Thomas Lüpke, Christoph Thieroff, Kunststoff-Zentrum in Leipzig GmbH (Germany); Christoph Chojetzki, FBGS Technologies GmbH (Germany) [OF101‑257]

Bending and directional characteristics of weakly tilted fiber Bragg grating, Yinping Miao, Nankai Univ. (China) [OF101‑258]

Flat supercontinuum-generation pumped by femtosecond pulses in zero-dispersion wavelength of photonic crystal fiber, Yuan Guo, Shuangchen Ruan, Yongqin Yu, Chenlin Du, Peiguang Yan, Shenzhen Univ. (China) [OF101‑259]

Coupling between a conventional single-mode fiber and an annular-core fiber by fused biconical taper, Libo Yuan, Harbin Engineering Univ. (China) [OF101‑260]

Real-time optical fiber sensor for hydro-alcoholic solutions, Eric Fujiwara, Rafael T. Takeishi, Eduardo Ono, Juliana S. dos Santos, Aya Hase, Carlos K. Suzuki, Univ. Estadual de Campinas (Brazil) [OF101‑261]

Fibre Bragg gratings in polymer optical fibre at 980nm, Johan Terblanche, Diethelm Schmieder, Johan Meyer, Univ. of Johannesburg (South Africa) [OF101‑262]

All fiber tunable loss filter, Jinesh Mathew, Ginu Rajan, Yuliya Semenova, Gerald Farrell, Dublin Institute of Technology (Ireland) [OF101‑263]

High-temperature resistant fiber Bragg grating lasers for sensing applications, Bai-Ou Guan, Jinan Univ. (China); Yang Zhang, Hong-Jun Wang, Da Chen, Dalian Univ. of Technology (China); Hwa-Yaw Tam, Hong Kong Polytechnic Univ. (Hong Kong, China) [OF101‑264]

Optimal cladding structure of holey fiber designed for broadband fiber-optic wave plate, Zhi-Dong Shi, Ming-Jia Li, Jun Yin, Jian-Qiang Lin, Xue-Nong Xiang, Shanghai Univ. (China) [OF101‑265]

Application of FBG sensors in strengthening and maintenance monitoring of old bridges, Lina Yue, Wuhan Univ. of Technology (China) [OF101‑11]

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