Zaawansowane systemy fotoniczne i elektroniczne : WILGA 2010

• Autorzy: Romaniuk R. S.

Warianty tytułu

EN

Advanced Photonic and Electronic Systems : WILGA 2010

• Języki publikacji: PL

Abstrakty

PL

Sympozjum WILGAgromadzi dwa razy w roku, w styczniu i w maju, nowych adeptów zaawansowanych systemów fotonicznych i elektronicznych. Spotkanie jest zorientowane na komponenty systemów i aplikacje. Sympozjum WILGA "Fotonika i Inżynieria Sieci Web" jest relatywnie szeroko znane na sieci Internet dzięki swojemu zaangażowaniu w promocję krajowej "młodej nauki" pod protektoratem największych międzynarodowych i krajowych naukowo-technicznych stowarzyszeń zawodowych jak IEEE, SPIE, oraz ich krajowych partnerów. WILGA jest sponsorowana przez najważniejsze organizacje krajowe w dziedzinie elektroniki jak Komitet Elektroniki i Telekomunikacji PAN oraz Polskie Stowarzyszenie Fotoniczne. Sympozjum jest organizowane od roku 1998. Do tej pory zgromadziło ponad 4000 młodych uczonych i opublikowało ponad 2000 artykułów, głównie zagranicą, w tym ponad 900 artykułów w 10 opublikowanych do tej pory tomach Proc. SPIE. Niniejszy artykuł jest przeglądem osiągnięć serii sympozjów WILGA oraz podsumowaniem Sympozjum WILGA 2010.

EN

SPIE - PSP WILGA Symposium gathers two times a year in January and in May new adepts of advanced photonic and electronic systems. The event is oriented on components and applications. WILGA Symposium on Photonics and Web Engineering is well known on the web for its devotion to "young research" promotion under the eminent sponsorship of international engineering associations like SPIE and IEEE and their Poland Sections or Counterparts. WILGA is supported by the most important national professional organizations like KEiT PAN and PSP-Photonics Society of Poland. The Symposium is organized since 1998 twice a year. It has gathered over 4000 young researchers and published over 2000 papers mainly internationally, including more than 900 in 10 published so far volumes of Proc. SPIE. This paper is a digest of WILGA Symposium Series and WILGA 2010 summary. Introductory part treats WILGA Photonics Applications characteristics over the period 1998-2010. Following part presents a short report on the XXVth and XXVIth Symposia held consecutively in January and May 2010

Słowa kluczowe

PL

Sympozjum WILGA; Oddziały studenckie SPIE; Sympozja SPIE i IEEE; konferencje młodych naukowców; doktoranci; fotonika; inżynieria sieci Internet; zaawansowane systemy elektroniczne i fotoniczne; IEEE; SPIE; SEP; PSP; KEiT PAN; PKOpto

EN

WILGA Symposium; SPIE Student Chapters; SPIE supported symposia; young researcher meetings; Ph.D. students; photonics and web engineering; advanced electronic and photonic systems; SPIE; IEEE; PSP; Photonics Society of Poland; IEEE Poland Section; SEP; KEiT PAN; PKOpto

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Elektronika : konstrukcje, technologie, zastosowania
• Rocznik: 2011
• Tom: Vol. 52, nr 1
• Strony: 94--108
• Opis fizyczny: Bibliogr. 158 poz., il., wykr.

Twórcy

autor

Romaniuk R. S.

• Politechnika Warszawska, Instytut Systemów Elektronicznych

Bibliografia

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• [44] Romaniuk R., Dorosz J.: Mechanical properties of hollow optical fibers. Proc.SPIE 6347, 2006, art no 634711.
• [45] Romaniuk R.: Optical fiber capillaries in trunk telecommunications. Proc. SPIE 6347, 2006, art no 634712.
• [46] Romaniuk R., Dorosz J.: Atom guiding in single mode capillary. Proc. SPIE 6347, 2006, art no 634713.
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• [52] Romaniuk R., Dorosz J.: Measurement techniques of tailored optical fibres. Proc. SPIE 5064, 2003, pp. 210-221.
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• [54] Romaniuk R., Pozniak K., Salanski R.: HOST - hybrid optoelectronic versatile telemetric system for local community. Proc. SPIE 5125, 2002, pp. 38-58.
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• [57] Romaniuk R.: Measurements of nonlinear optical fibers, Proc. SPIE 5125, 2002, pp. 59-75.
• [58] Pozniak K., et al.: Gigabit optical link test system for RPC muon trigger at CMS experiment, Proc. SPIE 5125, 2002, pp. 155-164.
• [59] Romaniuk R., Dorosz J.: Temperature sensor based on double core optical fibre. Proc. SPIE 4887, 2002, pp. 55-66.
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• [61] Dorosz J., Romaniuk R.: Current development of multi crucible technology of tailored optical fibers. Proc. SPIE 3731, 1999, pp. 32-58.
• [62] Dorosz J., Romaniuk R.: Recent developments of optical fiber technology at Fiberoptic Department of Biaglass Co. Proc. SPIE 3731, 1999, pp. 9-31.
• [63] Maciejewski J., et al.: Correction of fiber optic ion sensor readings with use of fiber optic temperature sensor. Proc. SPIE 3731, 1999, pp. 161-166.
• [64] Romaniuk R., Pozniak K., Dybko A.: Intranet & Internet metrological network with photonic sensors and transmission. Part I, Proc. SPIE 3731, 1999, pp. 224-245.
• [65] Romaniuk R., et al.: Intranet & Internet metrological network with photonic sensors and transmission. Part II, Proc. SPIE 3731, 1999, pp. 246-273.
• [66] Romaniuk R., et al.: Environmental tests of Intranet & Internet metrological station and network with photonic sensors and transmission. Proc. SPIE 3731, 1999, pp. 274-295.
• [67] Burd A., et al.: Piofthesky-automated search for fast optical transients over the whole sky. Astronomische Nachrichten, 325 (6-8), p. 674.
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• [69] Rutkowski R., et al.: FPGA based TESLA cavity SIMCON DOOCS server design, implementation and application, Proc. SPIE 5484, 2004, pp. 153-170.
• [70] Czarski T., et al.: Cavity control system - optimization methods for single cavity driving and envelope detection. Proc. SPIE 5484, 2004, pp. 99-110.
• [71] Cwiok M., et al.: Search for optical flashes accompanying gamma ray bursts. Pi of the Sky Collaboration, Proc. SPIE 5484, 2004. pp. 283-289.
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• [83] Romaniuk R., Stępień R.: Glass-ceramic fiber optic sensors. Proc. SPIE1368, 1991, pp. 73-84.
• [84] Just J. R., Romaniuk R. S.: Highly parallel distributed computing system with optical interconnections. Microprocessing and Microprogramming 27(1-5), 1989, pp. 489-493.
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• [89] Romaniuk R.: Directions of applications of optical fiber technology in medicine and health protection systems, Proc. SPIE 713, 1987, pp. 28-35.
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• [99] Dorosz J., Romaniuk R.: Production of multilayer optical fibers with complex refractive index profiles by means of multicrucible technology. Elektronika Warszawa 24 (1-2), 1983, pp. 27-31.
• [100] Romaniuk I. U., et al.: Light-conducting-fibre properties of retinal receptors. Klinika Oczna 83 (10), 1981, pp. 29-30.
• [101] Romaniuk I. U., et al.: The use of light-conducting fibres in ophthalmological equipment. Klinika Oczna 83 (10), 1981, pp. 30-33.
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• [106] Romaniuk R.: Optical fiber technology in medicine. Proc. SPIE 576, 1985, pp. 105-109.
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• [108] Romaniuk R., Dorosz J.: Family of multicore optical fibre based sensors and instrumentation systems. Proc. SPIE 514, 1984, pp. 275-278.
• [109] Kasprowicz G., et al.: CCD detectors for wide field optical astronomy. Photonics Letters of Poland, 1 (2), 2009, pp. 82-84.
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• [111] Romaniuk R.: POLFEL- Free Electron Laser in Poland, Photonics Letters of Poland 1 (3), 2009, pp. 103-108.
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• [113] Romaniuk R.: Proceedings of SPIE - The International Society for Optical Engineering: Introduction. Proc. SPIE 5848, 2005, pp.xvii-xxi.
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• [120] Dorosz J., Romaniuk R.: The role of regional developments in optical fiber technology and photonics. Proc. SPIE 5028, 2003, pp.xi-xii.
• [121] Romaniuk R., Pozniak K.: Foreword: Photonics and electronics for astronomy and high energy physics experiments in Poland. Proc. SPIE 5125, 2002, pp.xiii-xxxiv.
• [122] Romaniuk R., Kulpa K.: Photonics applications in Astronomy, Communications Industry and High-Energy Physics Experiments 2009: Introduction, Proc. SPIE 7502, 2009, art no 750201, pp.xxiii-xxiv.
• [123] Dorosz J., Romaniuk R., Wolinski T.: Eleventh conference on optical fibers and their applications, Proc. SPIE 7120, 2008, pp.xiii-xv.
• [124] Romaniuk R.: WILGA Symposium on photonics applications, Photonics Letters of Poland 1 (2), 2009, pp. 46-48.
• [125] Romaniuk R.: Photonics and Web Engineering in Poland, WILGA2009, Proc. SPIE 7502, 2009, art no. 750202.
• [126] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Measurement of the muon stopping power in lead tungstate, Journal of Instrumentation, Vol. 5, No. 3, art. P03007, 2010.
• [127] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Commissioning of the CMS experiment and the cosmic run at four tesla, JINST5 (3), art. T03001, 2010.
• [128] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Performance of the CMS Level-1 trigger during commissioning with cosmic ray muons and LHC beams, JINST 5 (3), art. T03002, 2010.
• [129] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Performance of the CMS drift-tube chamber local trigger with cosmic rays, JINST 5 (3), art. T03003, 2010.
• [130] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Fine synchronization of the CMS muon drift-tube local trigger using cosmic rays, JINST 5 (3), art. T03004, 2010.
• [131] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Commissioning of the CMS High-Level Trigger with cosmic rays, JINST 5 (3), art. T03005, 2010.
• [132] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), CMS data processing workflows during an extended cosmic ray run, JINST 5 (3), art. T03006, 2010.
• [133] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Commissioning and performance of the CMS pixel tracker with cosmic ray muons, JINST 5 (3), art. T03007, 2010.
• [134] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Commissioning and performance of the CMS silicon strip tracker with cosmic ray muons, JINST 5 (3), art. T03008, 2010.
• [135] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Alignment of the CMS silicon tracker during commissioning with cosmic rays, JINST 5 (3), art. T03009, 2010.
• [136] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Performance and operation of the CMS electromagnetic calorimeter, JINST 5 (3), art. T03010, 2010.
• [137] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Time reconstruction and performance of the CMS electromagnetic calorimeter, JINST5 (3), art. T03011, 2010.
• [138] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Performance of the CMS hadron calorimeter with cosmic ray muons and LHC beam data, JINST 5 (3), art. T03012, 2010.
• [139] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Performance of CMS hadron calorimeter timing and synchronization using test beam, cosmic ray, and LHC beam data, JINST 5 (3), art. T03013, 2010.
• [140] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Identification and filtering of uncharacteristic noise in the CMS hadron calorimeter, JINST 5 (3), art. T03014, 2010.
• [141] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Performance of the CMS drift tube chambers with cosmic rays, JINST 5 (3), art. T03015, 2010.
• [142] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Calibration of the CMS drift tube chambers and measurement of the drift velocity with cosmic rays, JINST 5 (3), art. T03016, 2010.
• [143] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Performance study of the CMS barrel resistive plate chambers with cosmic rays, JINST 5 (3), art. T03017, 2010.
• [144] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Performance of the CMS cathode strip chambers with cosmic rays, JINST 5 (3), art. T03018, 2010.
• [145] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Aligning the CMS muon chambers with the muon alignment system during an extended cosmic ray run, JINST 5 (3), art. T03019, 2010.
• [146] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Alignment of the CMS muon system with cosmic-ray and beam-halo muons, JINST 5 (3), art. T03020, 2010.
• [147] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Precise mapping of the magnetic field in the CMS barrel yoke using cosmic rays, JINST 5 (3), art. T03021, 2010.
• [148] Poźniak K., Romaniuk R., Zabołotny W., et. al.: (CMS Collaboration), Performance of CMS muon reconstruction in cosmic-ray events, JINST 5 (3), art. T03022, 2010.
• [149] WILGA 2002: Romaniuk R. S., Poźniak K. T. (editors): Proc. SPIE 5125; Photonics Applications in Astronomy, Communications, Industry, and High-Energy Physics Experiments 2002; ISBN 9780819449856; 472 pages, 55 papers; (2003).
• [150] WILGA 2003: Romaniuk R. S. (editor): Proc.SPIE 5484; PhotonicsApplications in Astronomy, Communications, Industry, and High-Energy Physics Experiments 2003; ISBN 9780819454157; 734 pages, 94 papers; (2004).
• [151] WILGA 2004: Romaniuk R. S. (editor): Proc. SPIE 5775; Photonics Applications in Astronomy, Communications, Industry, and High-Energy Physics Experiments 2005; ISBN 9780819457561; 710 pages, 92 papers; (2005).
• [152] WILGA 2005 bis: Romaniuk R. S., Simrock S., Lutkovski V. M. (editors), Proc. SPIE 5948, Photonics Applications in Industry and Research 2005; ISBN 9780819459558; 864 pages, 89 papers; (2005).
• [153] WILGA 2005: Romaniuk R. S. (editor): Proc. SPIE 6159; Photonics Applications in Astronomy, Communications, Industry, and High-Energy Physics Experiments 2005; ISBN 9780819462114; 1244 pages, 172 papers; (2006).
• [154] WILGA 2006: Romaniuk R. S. (editor): Proc. SPIE 6347; Photonics Applications in Astronomy, Communications, Industry, and High-Energy Physics Experiments 2006; ISBN 9780819464316; 874 pages, 111 papers; (2006).
• [155] WILGA 2007: Romaniuk R. S. (editor): Proc. SPIE 6937; Photonics Applications in Astronomy, Communications, Industry, and High-Energy Physics Experiments 2007; ISBN 9780819471246; 1274 pages, 152 papers; (2008).
• [156] WILGA 2008: Romaniuk R. S., Woliński T. R. (editors): Proc. SPIE 7124; Photonics Applications in Astronomy, Communications, Industry, and High-Energy Physics Experiments 2008; ISBN 9780819473585; 312 pages, 35 papers; (2008)
• [157] WILGA 2009: Romaniuk R. S., Kulpa K. S. (editors): Proc. SPIE 7502; Photonics Applications in Astronomy, Communications, Industry, and High-Energy Physics Experiments 2009; 9780819478139; 786 pages, 100 papers; (2009).
• [158] WILGA 2010: Romaniuk R. S. (editor): Proc. SPIE 7376; Photonics Applications in Astronomy, Communications, Industry, and High-Energy Physics Experiments 2006; ISBN 9780819464316; 300 pages, 35 papers; (2010).