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David A. Jackson
Researcher at King's College London
Publications - 1166
Citations - 76015
David A. Jackson is an academic researcher from King's College London. The author has contributed to research in topics: Optical fiber & Interferometry. The author has an hindex of 136, co-authored 1095 publications receiving 68352 citations. Previous affiliations of David A. Jackson include University of California, Berkeley & University of Alberta.
Papers
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Proceedings ArticleDOI
A novel miniature optical fibre probe for MHz frequency ultrasound
J. Surowiec,Norman E. Fisher,David J. Webb,David A. Jackson,Leonid R. Gavrilov,Jeffrey Hand,L. Zhang,Ian Bennion +7 more
TL;DR: In this article, the authors investigate the feasibilty of using in-fibre Bragg gratings to measure ultrasonic fields for medical applications, and two signal processing schemes for interrogating the gratings are described.
Proceedings ArticleDOI
Recent progress in experiments on a Brillouin loss-based distributed sensor
TL;DR: Optical fibres, which have been developed for long distance, high bandwidth communications, possess a very low loss, are cheap to manufacture and are readily available in long length as mentioned in this paper, have been widely used in long distance communications.
Proceedings ArticleDOI
Response of in-fibre bragg gratings to focused ultrasonic fields
Norman E. Fisher,S.F. O'Neill,David J. Webb,Christopher N. Pannell,David A. Jackson,Leonid R. Gavrilov,Jeffrey Hand,Leishi Zhang,Ian Bennion +8 more
TL;DR: There is a need for the assessment of the safety of ultrasound for medical applications due to the trend towards increasing output powers from diagnostic ultrasound equipment and the widening use of high intensity ultrasonic fields in a range of therapeutic applications.
Measurement of Branching Fractions for B ! pp , Kp, and KK Decays
Kazuo Abe,I. Adachi,H. Aihara,M. Akatsu,Gianluca Alimonti,Y. Asano,Tsukasa Aso,V. M. Aulchenko,T. Aushev,A. M. Bakich,W. Bartel,S. Behari,P. K. Behera,D. Beiline,A.E. Bondar,A. Bozek,T. E. Browder,B. C. K. Casey,P. Chang,Y. Chao,K. F. Chen,B. G. Cheon,Y. Choi,S. Eidelman,Yuji Enari,Ryoji Enomoto,H. Fujii,Masaki Fukushima,A. Garmash,Ascelin Gordon,K. Gotow,R. Guo,J. Haba,H. Hamasaki,F. Handa,K. Hara,T. Hara,N. C. Hastings,H. Hayashii,Masashi Hazumi,E. M. Heenan,I. Higuchi,T. Higuchi,H. Hirano,T. Hojo,Y. Hoshi,Y. Igarashi,T. Iijima,Hirokazu Ikeda,K. Inami,A. Ishikawa,Hirokazu Ishino,R. Itoh,Go Iwai,Hiroyuki Iwasaki,Y. Iwasaki,David A. Jackson,Pawel Jalocha,H. K. Jang,Matthew Jones,H. Kakuno,J. Kaneko,J. H. Kang,J. S. Kang,N. Katayama,Hikaru Kawai,T. Kawasaki,H. Kichimi,D. W. Kim,Heejong Kim,Hyunyong Kim,Hyunwoo Kim,S. K. Kim,K. Kinoshita,S. Kobayashi,P. Krokovny,R. Kulasiri,S. Kumar,Alexei Kuzmin,J. S. Lange,M. H. Lee,S. H. Lee,D. Liventsev,Daniel Robert Marlow,T. Matsubara,S. Matsumoto,T. Matsumoto,Y. Mikami,K. Miyabayashi,Hirokazu Miyake,H. Miyata,G. R. Moloney,Shigeki Mori,T. Mori,A. Murakami,T. Nagamine,Yasushi Nagasaka,T. Nakadaira,E. Nakano,M. Nakao,J. W. Nam,S. Narita,S. Nishida,S. Noguchi,T. Nozaki,S. Ogawa,T. Ohshima,T. Okabe,S. Okuno,S. L. Olsen,H. Ozaki,P. Pakhlov,H. Palka,M. D. Peters,L. E. Piilonen,J. L. Rodriguez,M. Rozanska,Krzysztof A. Rybicki,J. Ryuko,Hiroyuki Sagawa,Y. Sakai,Hiroshi Sakamoto,M. Satapathy,A. Satpathy,S. Schrenk,S. Semenov,K. Senyo,M. E. Sevior,H. Shibuya,B. Shwartz,Vladimir A. Sidorov,J. B. Singh,S. Stani,A. Sugi,A. Sugiyama,K. Sumisawa,T. Sumiyoshi,Kei Suzuki,S. Y. Suzuki,S. Y. Suzuki,S. K. Swain,H. Tajima,T. Takahashi,F. Takasaki,M. Takita,K. Tamai,N. Tamura,J. Tanaka,M. Tanaka,G. N. Taylor,Y. Teramoto,Makoto Tomoto,T. Tomura,S.N. Tovey,K. Trabelsi,T. Tsuboyama,T. Tsukamoto,S. Uehara,K. Ueno,Y. Unno,S. Uno,Y. Ushiroda,Y. Usov,S. E. Vahsen,G. S. Varner,Kevin Varvell,C. C. Wang,C. H. Wang,J. G. Wang,Z. Wang,Y. Watanabe,E. Won,B. D. Yabsley,Yasuhiko Yamada,M. Yamaga,A. Yamaguchi,H. Yamamoto,Y. Yamashita,M. Yamauchi,S. Yanaka,Masashi Yokoyama,Y. Yusa,H. Yuta,C. C. Zhang,Jia-ju Zhang,H. W. Zhao,Y. Zheng,V.N. Zhilich +187 more
Journal ArticleDOI
Reduction of semiconductor laser diode phase and amplitude noise in interferometric fiber optic sensors
TL;DR: An optical configuration employing two conventional Michelson interferometers and a fiber Fabry-Perot interferometer connected in parallel is used to demonstrate the principle of common mode rejection of both the amplitude and frequency noise of a semiconductor laser.