Advanced Photonic and Electronic Systems WILGA 2018

• Autorzy: Romaniuk R. S.

Identyfikatory

DOI

10.24425/123539

• Języki publikacji: EN

Abstrakty

EN

WILGA annual symposium on advanced photonic and electronic systems has been organized by young scientist for young scientists since two decades. It traditionally gathers around 400 young researchers and their tutors. Ph.D students and graduates present their recent achievements during well attended oral sessions. Wilga is a very good digest of Ph.D. works carried out at technical universities in electronics and photonics, as well as information sciences throughout Poland and some neighboring countries. Publishing patronage over Wilga keep Elektronika technical journal by SEP, IJET and Proceedings of SPIE. The latter world editorial series publishes annually more than 200 papers from Wilga. Wilga 2018 was the XLII edition of this meeting. The following topical tracks were distinguished: photonics, electronics, information technologies and system research. The article is a digest of some chosen works presented during Wilga 2018 symposium. WILGA 2017 works were published in Proc. SPIE Vol.10445. WILGA 2018 works were published in Proc. SPIE vol.10808.

Słowa kluczowe

EN

photonic systems; electron technology; material engineering; electronics; photonics; optoelectronics; lasers; telecommunications; informatics; electronic systems; large research experiments; young researcher meetings; WILGA Symposium; Wilga

• Wydawca: Polish Academy of Sciences, Committee of Electronics and Telecommunication
• Czasopismo: International Journal of Electronics and Telecommunications
• Rocznik: 2018
• Tom: Vol. 64, No. 3
• Strony: 397--405
• Opis fizyczny: Bibliogr. 26 poz.

Twórcy

autor

Romaniuk R. S.

• Institute of Electronic Systems, Warsaw University of Technology, Poland

Bibliografia

• [1] J.W.Modelski, R.S.Romaniuk, Committee of Electronics and Telecommunications, Polish Academy of Sciences, Structure – Activities – Perspectives, International Journal of Electronics and Telecommunications, vol.61, no.1, 2015, pp. 49-56.
• [2] R.S.Romaniuk, Introduction, Proc. SPIE, vol. 10808, 2018, art.no.1080801, pp.xxvii-xxxvi.
• [3] R.S.Romaniuk, Photonics applications and web engineering – Wilga 2018, Proc. SPIE, vol.10808, 2018, art.no.1080802.
• [4] R.S.Romaniuk, WILGA Symposium on Photonics Applications, Photonics Letters of Poland, vol.1, no.2, 2009, pp.46-48.
• [5] R.S.Romaniuk, Wilga photonics and web engineering 2010, Photonics Letters of Poland 2 (2), 2010, pp.55-57.
• [6] R.S.Romaniuk, Electronic and Photonic Systems WILGA 2014, International Journal of Electronics and Telecommunications, vol.60, no.3, 2014, pp.271-276.
• [7] R.S.Romaniuk, Photonics and web engineering – WILGA Summer 2016, Proc.SPIE, vol. 10031, 2016, art.no.1003103.
• [8] R.S.Romaniuk, Photonics applications and web engineering – WILGA 2017, Proc. SPIE, vol.10445, 2017, art.no.1044501.
• [9] R.S.Romaniuk, Multicore optical fibres, Revue Roumaine de Physique 32(1-2), 1987, pp.99-112.
• [10] R.S.Romaniuk, J.Dorosz, Measurement techniques of tailored optical fibers, Proc.SPIE, vol.5064, 2003, pp.210-221.
• [11] A.Dybko, W.Wróblewski, J.Maciejewski, et al., Fiber optic probe for monitoring of drinking water, Proc.SPIE, vol.3105, 1997, pp.361-366.
• [12] R.S.Romaniuk, Optical fiber transmission with wavelength multiplexing - Faster or denser?, Proc.SPIE, vol. 5484, 2004, pp.19-28.
• [13] R.S.Romaniuk, Modal structure design in refractive capillary optical fibres, Photonics Letters of Poland, 2010, 2 (1), pp.22-24.
• [14] R.S.Romaniuk, Geometry design in refractive capillary optical fibers, Photonics Letters of Poland, 2 (2), 2010, pp.64-66.
• [15] R.S.Romaniuk, Manufacturing and characterization of ring-index optical fibers, Optica Applicata, vol.31, no.2, 2001, pp. 425-444.
• [16] R.S.Romaniuk, J.Dorosz, W.Wójcik, P.Mergo, R.Buczyński, Optical fiber technology in Poland – four decades of development 1975-2015, Proc.SPIE 9816, 2015, art.no.981603.
• [17] A.Burd, M.Ćwiok, H.Czyrkowski, et al., Pi of the sky – automated search for fast optical transients over the whole sky, Astronimische Nachrichten, 325 (6-8), 2004, pp.674.
• [18] T.Czarski, R.Romaniuk, K.Pozniak, S.Simrock, Cavity control system advanced modeling and simulations for TESLA linear accelerator and free electron laser, Proc.SPIE, vol.5484, 2004, pp.69-87.
• [19] T.Czarski, K.Poźniak, R.Romaniuk, S.Simrock, TESLA cavity modelling and digital implementation, Proc.SPIE, vol.5484, 2004, pp.111-129.
• [20] K.T.Pozniak, T.Czarski, R.S.Romaniuk, Functional analysis of DSP blocks in FPGA chips for application in TESLA LLRF system, Proc. SPIE vol. 5484, 2004, pp.130-138.
• [21] W.M.Zabolotny, P.Roszkowski, K.Kierzkowski, et al., Distributed embedded PC based control and data acquisition system for TESLA cavity controller and simulator, Proc.SPIE, vol.5448, 2004, pp.171-179.
• [22] K.T.Pozniak, T.Czarski, R.S.Romaniuk, FPGA based cavity simulator and controller for TESLA Test Facility, Proc.SPIE, vol.5775, 2005, pp.9-21.
• [23] P.Pucyk, T.Jeżyński, W.Koprek, et al., DOOCS server and client application for FPGA based TESLA cavity controller and simulator, Proc.SPIE, vol.5775, 2005, pp.52-60.
• [24] S.Chatrchyan, V.Khachatryan, A.M.Sirunyan, et al., Performance and operation of the CMS electromagnetic calorimeter, JINST 5 (3), 2010, T03010.
• [25] T.Czarski, K.Poźniak, R.Romaniuk, TESLA cavity modelling and digital implementation with FPGA technology solution for control system development, Proc. SPIE, vol. 5484, 2004, pp.111-129.
• [26] R.S.Romaniuk, K.T.Poźniak, Metrological aspects of accelerator technology and high energy physics experiments, Meas. Sci.Technol. vol.18, no.8, August 2007, pp.E01-02.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).