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@preamble{"\def\acc{[Online; accessed \today]}"}

@misc{template,
    author = "{}", 
    title = "",
    year = "",
    howpublished = "\url{}",
    note = "[Online; accessed 2-January-2019]"
}


@article{Novotny_2020,
	doi = {10.1088/1748-0221/15/07/c07015},
	url = {https://doi.org/10.1088%2F1748-0221%2F15%2F07%2Fc07015},
	year = 2020,
	month = {jul},
	publisher = {{IOP} Publishing},
	volume = {15},
	number = {07},
	pages = {C07015--C07015},
	author = {L. Novotny and J. Cerovsky and P. Dhyani and O. Ficker and M. Havranek and M. Hejtmanek and Z. Janoska and V. Kafka and S. Kulkov and M. Marcisovska and M. Marcisovsky and G. Neue and P. Svihra and V. Svoboda and L. Tomasek and M. Tunkl and V. Vrba},
	title = {Runaway electron diagnostics using silicon strip detector},
	journal = {Journal of Instrumentation},
	abstract = {We present a proof-of-principle measurement of runaway   electrons in a small tokamak using a silicon strip detector.  The   detector was placed inside the diagnostic port of the tokamak vessel   and detected the runaway electron signal directly.  The measured   signal was compared to the signal provided by other tokamak   diagnostics, especially the hard X-ray scintillation detector, which   detects secondary photons created by interaction of accelerated   electrons with tokamak walls (indirect detection of runaway   electrons).  The preliminary results show that when not saturated,   direct detection with a segmented silicon strip detector provides   promising new diagnostic information including spatial and temporal   distribution of the runaway electron beam, and the measurement   results are in good agreement with hard X-ray measurements with a   scintillation detector.}
}

@article{GRYAZNEVICH_2020,
	doi = {10.1088/2058-6272/ab6d4d},
	url = {https://doi.org/10.1088%2F2058-6272%2Fab6d4d},
	year = 2020,
	month = {mar},
	publisher = {{IOP} Publishing},
	volume = {22},
	number = {5},
	pages = {055102},
	author = {M GRYAZNEVICH and J STÖCKEL and G VAN OOST and E DEL BOSCO and V SVOBODA and A MELNIKOV and R KAMENDJE and A MALAQUIAS and G MANK and R MIKLASZEWSKI and   and},
	title = {Contribution of joint experiments on small tokamaks in the framework of {IAEA} coordinated research projects to mainstream fusion research},
	journal = {Plasma Science and Technology},
	abstract = {Joint experiments (JEs) on small tokamaks have been regularly performed between 2005 and 2015 under the framework of the International Atomic Energy Agency (IAEA) coordinated research projects (CRPs). This paper describes the background and the rationale for these experiments, how they were organized and executed, main areas of research covered during these experiments, main results, contributions to mainstream fusion research, and discusses lessons learned and outcomes from these activities. We underline several of the most important scientific outputs and also specific outputs in the education of young scientists and scientists from developing countries and their importance.}
}

@misc{GolemHistory,
    author = "{Jan Mlynář}",
    keywords="{GolemHistory}",
    title = "Golem history",
    year = "2010",
    howpublished = "\url{http://golem.fjfi.cvut.cz/wiki/History/Articles/GolemHistoryHM.pdf}",
    note = "[Online; accessed 2-January-2019]"
}

@misc{GMhandson,
    author = "{The GOLEM Tokamak contributors}",
    title = "Magnetic confinement of high temperature plasma at the GOLEM
tokamak",
    year = "2020",
    howpublished = "\url{http://golem.fjfi.cvut.cz/wiki/Education/GMinstructions/extracts/GeneralHandsOn/docum.pdf}",
    note = "[Online; accessed 2-January-2020]"
}


@INPROCEEDINGS{8876584, 
keywords={8876584,Madeira},
author={O. {Grover} and V. {Svoboda} and J. {Stockel}}, 
booktitle={2019 5th Experiment International Conference (exp.at'19)}, 
title={Remote demonstration of the GOLEM tokamak}, 
url={https://ieeexplore.ieee.org/document/8876584},
year={2019}, 
volume={}, 
number={}, 
pages={239-240}, 
abstract={The GOLEM tokamak serves as an educational device in the field of tokamak physics, technology, diagnostics and operation in the scope of the wider field of thermonuclear fusion. The typical scenario of a remote demonstration of the GOLEM tokamak is described. The new remote control and live status web interface in its mobile-ready form is presented.}, 
keywords={Tokamak devices;Discharges (electric);Remote control;Physics;Real-time systems;Tokamak technology and control;online experimentation;remote participation;education}, 
doi={10.1109/EXPAT.2019.8876584}, 
ISSN={}, 
month={June},}


@INPROCEEDINGS{8876482, 
keywords={8876482,Madeira},
author={O. {Grover} and V. {Svoboda} and J. {Stockel}}, 
booktitle={2019 5th Experiment International Conference (exp.at'19)}, 
title={Online experimentation at the GOLEM tokamak}, 
url={https://ieeexplore.ieee.org/document/8876482},
year={2019}, 
volume={}, 
number={}, 
pages={220-225}, 
abstract={The GOLEM tokamak offers students and other interested parties the opportunity to gain "hands-on" experience through online experimentation in the field of plasma physics and controlled thermonuclear fusion in tokamaks. A typical online experiment scenario is outlined. The new web application facilitating safe, easy and efficient online experimentation, including a live, real-time view of the experiment is described in detail. Simple access to the open and extensive database of experimental results is demonstrated. Finally, the wide range of possible experimental topics from past -and applicable to future-online experimentation sessions is reported.}, 
keywords={Tokamak devices;Discharges (electric);Plasma measurements;Rendering (computer graphics);Remote control;Physics;Tokamak technology and control;online experimentation;remote participation;education}, 
doi={10.1109/EXPAT.2019.8876482}, 
ISSN={}, 
month={June},}

@INPROCEEDINGS{8824534, 
keywords={8824534},
author={V. {Linhart} and D. {Bren} and A. {Casolari} and J. {Čeřovský} and M. {Farník} and O. {Ficker} and M. {Hetflejš} and M. {Hron} and J. {Jakůbek} and P. {Kulhánek} and E. {Macúšová} and M. {Marčišovský} and J. {Mlynář} and P. {Švihra} and V. {Svoboda} and J. {Urban} and J. {Varju} and V. {Vrba}}, 
booktitle={2018 IEEE Nuclear Science Symposium and Medical Imaging Conference Proceedings (NSS/MIC)}, 
title={First Measurement of X-rays Generated by Runaway Electrons in Tokamaks Using a TimePix3 Device with 1 mm thick Silicon Sensor}, 
year={2018}, 
volume={}, 
number={}, 
pages={1-9}, 
abstract={An application study of modern pixel semiconductor detectors for characterization of runaway electron events in tokamaks is presented. Characterization techniques utilizing both spectroscopic measurements and monitoring of the intensity of secondary X-rays produced by the runaway electrons were used. Energy spectra of X-rays and time evolutions of their intensity on two tokamaks (Golem and Compass) were measured under different conditions and compared with results of standard runaway diagnostics. The energy spectra measured on both tokamaks have similar exponential shapes but with a significant variation in numbers of events per shot. The time evolutions of the X-ray intensity during several discharges on the tokamak Golem were measured using both the Timepix3 device and scintillation detectors (NaI:Tl and YAP:Ce). On a microsecond time scales, the signal time evolution measured by the TimePix3 device shows patterns in a form of unexpected or periodic-like increases of the intensity. We have also observed significant differences in number of events of the detected X-rays generated by the runaway electrons flying frontward and backward with respect to a limiter of the tokamak Golem. This fact declares that the runaway electrons have relativistic velocities. The experiments on the tokamak Compass provide similar results. Measurements in the immediate vicinity of tokamak Compass were impossible to perform because of a rapid change of the tokamak magnetic field. Measurements performed in the distance of at least 0.5 m from a diagnostic port of the tokamak Compass gave millions of correctly measured events per shot and an unknown number of events affected by pileups. The correctly measured events were used for construction of energy spectra and the time evolutions of the X-ray intensity.}, 
keywords={fusion reactor instrumentation;fusion reactor theory;plasma diagnostics;plasma toroidal confinement;semiconductor counters;solid scintillation detectors;Tokamak devices;modern pixel semiconductor detectors;runaway electron events;spectroscopic measurements;secondary X-rays;runaway electrons;energy spectra;time evolutions;standard runaway diagnostics;X-ray intensity;tokamak Golem;microsecond time scales;signal time evolution;TimePix3 device;tokamak Compass;tokamak magnetic field;silicon sensor;NaI:Tl;Tokamaks;Detectors;X-rays;Semiconductor device measurement;Compass;Standards}, 
doi={10.1109/NSSMIC.2018.8824534}, 
ISSN={}, 
month={Nov},}

@article{Dhyani_2019,
        keywords={Dhyani_2019},
        doi = {10.1088/1748-0221/14/09/c09029},
        url = {https://doi.org/10.1088%2F1748-0221%2F14%2F09%2Fc09029},
        year = 2019,
        month = {sep},
        publisher = {{IOP} Publishing},
        volume = {14},
        number = {09},
        pages = {C09029--C09029},
        author = {P. Dhyani and V. Svoboda and V. Istokskaia and J. Mlyn{\'{a}}{\v{r}} and J. {\v{C}}e{\v{r}}ovsk{\'{y}} and O. Ficker and V. Linhart},
        title = {Study of Runaway Electrons in {GOLEM} Tokamak},
        journal = {Journal of Instrumentation},
        abstract = {High loop voltage and low-density plasma discharges at the   GOLEM tokamak present favorable conditions for the study of the   runaway electrons (RE). A probe is being designed and developed for   the spectral measurement of the RE energy inside the last closed   flux surface of GOLEM tokamak plasma. Design of the probe is based   on simulation results of the FLUKA code that estimates the energy   absorbed by the scintillating crystals and filters of various   densities. In the simulations, graphite, stainless steel and   molybdenum were tested to filter the supra-thermal electrons. Since   having different light yield, YSO   (Y2SiO5:Ce),   NaI(Tl) and plastic (EJ-200) scintillating crystals were chosen for   the simulations.}
}

@Article{JOFESvoboda2019,
keywords={JOFESvoboda2019},
author="Svoboda, Vojtech and Zhekova, Maya and Dimitrova, Miglena and Marinova, Plamena and Podoln{\'i}k, Ales and Stockel, Jan",
title="Operational Domain in Hydrogen Plasmas on the GOLEM Tokamak",
journal="Journal of Fusion Energy",
year="2019",
month="Mar",
day="20",
abstract="A series of discharges in hydrogen were performed in two experimental sessions. The vessel was not conditioned before the first session, while inductive heating of the vessel and cleaning glow discharge were applied before the second session. Experimental results from both sessions are compared, and optimum operational conditions for the majority of key plasma parameters are determined. It is found that plasma performance with a properly conditioned vessel is significantly better, as expected. In particular, a noticeable increase of discharge duration, and of the electron temperature is observed.",
issn="1572-9591",
doi="https://doi.org/10.1007/s10894-019-00215-7"
%url="https://doi.org/10.1007/s10894-019-00215-7"
}


@CONFERENCE{DhyaniEPS19,
keywords={DhyaniEPS19},
author={Dhyani, P., Svoboda, V., Istokskaia, V., Mlynář, J., Čeřovský, J., Ficker, O., Linhart, V.},
title={Design and development of probe for the measurements of runaway electrons inside the golem tokamak plasma edge},
journal={46th EPS Conference on Plasma Physics, EPS 2019},
year={2019},
volume={2019-July},
pages={P1.1016},
url={http://ocs.ciemat.es/EPS2019PAP/pdf/P1.1016.pdf},
document_type={Conference Paper},
source={Scopus},
 howpublished={\url{http://ocs.ciemat.es/EPS2019PAP/pdf/P1.1016.pdf}},
  ISBN={979-10-96389-11-7},
  Volume = {{43C}},
  abstract={},
  series = {Europhysics conference abstracts},
}

@CONFERENCE{MachaEPS19,
keywords={MachaEPS19},
author={Kulkov, S., Mácha, P., Istokskkaia, V., Kropáčková, D., Papoušek, F., Adámek, J., Čeřovský, J., Ficker, O., Grover, O., Jiráková, K., Stöckel, J., Svoboda, V.},
title={Tokamak GOLEM for fusion education - chapter 10},
journal={46th EPS Conference on Plasma Physics, EPS 2019},
year={2019},
volume={2019-July},
pages={P1.1068},
url={http://ocs.ciemat.es/EPS2019PAP/pdf/P1.1068.pdf},
document_type={Conference Paper},
source={Scopus},
 howpublished={\url{http://ocs.ciemat.es/EPS2019PAP/pdf/P1.1068.pdf}},
  ISBN={979-10-96389-11-7},
  Volume = {{43C}},
  abstract={},
  series = {Europhysics conference abstracts},
}


@CONFERENCE{Istokskaia2018261,
author={Istokskaia, V. and Shkut, M. and Cerovsky, J. and Farnik, M. and Grover, O. and Hudec, L. and Macha, P. and Krbec, J. and Svoboda, V. and Stockel, J. and Adamek, J.},
title={Tokamak GOLEM for fusion education - Chapter 9},
journal={45th EPS Conference on Plasma Physics, EPS 2018},
year={2018},
volume={2018-July},
pages={261-264},
note={cited By 0},
url={https://www.scopus.com/inward/record.uri?eid=2-s2.0-85057830567&partnerID=40&md5=a2c1fb87e3fca2414a7ff6fd7d995ffd},
document_type={Conference Paper},
source={Scopus},
}

@article{SVIHRA2018,
title = "Runaway electrons diagnostics using segmented semiconductor detectors",
journal = "Fusion Engineering and Design",
year = "2018",
issn = "0920-3796",
doi = "https://doi.org/10.1016/j.fusengdes.2018.12.054",
author = "Peter Svihra and David Bren and Andrea Casolari and Jaroslav Cerovsky and Pravesh Dhyani and Michal Farnik and Ondrej Ficker and Miroslav Havranek and Martin Hejtmanek and Zdenko Janoska and Vladimir Kafka and Petr Kulhanek and Vladimir Linhart and Eva Macusova and Maria Marcisovska and Michal Marcisovsky and Jan Mlynar and Gordon Neue and Lukas Novotny and Vojtech Svoboda and Lukas Tomasek and Jakub Urban and Pavel Vancura and Jozef Varju and Vaclav Vrba and Vladimir Weinzettl",
keywords = "Semiconductor detectors, Runaway electrons, Tokamaks",
abstract = "A novel application of strip and pixel silicon radiation detectors for study and characterization of run-away electron events in tokamaks is presented. Main goal was to monitor runaway electrons both directly and indirectly. The strip detector was placed inside the tokamak vacuum chamber in order to monitor the run-away electrons directly. Whereas the pixel detector was placed outside the tokamak chamber behind a pin hole for monitoring the run-away electrons indirectly via radiation produce by interaction of the electrons with the plasma facing material. Results obtained using the silicon detectors are compared with already existing diagnostic methods consisting of scintillation devices detecting X-rays and photo-neutrons, providing the same results in the observable comparisons. Tests with the pixel detector proved that the pinhole camera is able to extract spatial information of interaction point (a place where the runaway electrons hit on the facing material) and the strip detectors indicate presence of additional signal from throughout the discharge. The performed experiments are innovative, illustrating possible development of new and easy to use diagnostic method."
}

@mastersthesis{KocmanMT,
Author = {{Kocman, J.}},
Title = {Řízení polohy plazmatického prstence na tokamaku GOLEM},
Year = {Master thesis 2015},
howpublished={{http://golem.fjfi.cvut.cz/wiki/Library/GOLEM/MastThesis/15KocmanJindrich.pdf}},
keywords = "mathesis"
}


@misc{PluharBP,
Author = {{Pluhar, O.}},
Title = {Interactive model of tokamak GOLEM},
Year = {Bachelor project 2011},
howpublished={{http://golem.fjfi.cvut.cz/wiki/Library/GOLEM/BachThesis/11PluharOndrej.pdf}},
keywords = "bachproj"
}


@misc{MatenaMT,
Author = {{Matěna, L.}},
Title = {Microwave interferometry on the tokamaku GOLEM},
Year = {Master thesis 2015},
howpublished={{http://golem.fjfi.cvut.cz/wiki/Library/GOLEM/MastThesis/15MatenaLukas.pdf}},
keywords = "mathesis"
}

@misc{LeitlMT,
Author = {{Leitl, B.}},
Title = {Tomografická rekonstrukce profilu vyzařování plazmatu na tokamaku GOLEM},
Year = {Master thesis 2019},
howpublished={{http://golem.fjfi.cvut.cz/wiki/Library/GOLEM/MastThesis/19LeitlBorek.pdf}},
keywords = "mathesis"
}

@InProceedings{EPSLeuven2016,
  author = 	 {Duban, R., Ficker, O., Grover, O., Jiraková, K., Leitl, B., Okonechniková, T., Stockel, J., Svoboda, V., Vondrasek, G.},
  title = 	 {{Tokamak GOLEM for fusion education - chapter 7 }},
  booktitle =    {Europhysics Conference Abstracts. 43th EPS Conference on Plasma Physics (online: \url{http://ocs.ciemat.es/EPS2016PAP/html/contrib.html})},
  year = 	 {2016},
  howpublished={\url{hhttp://ocs.ciemat.es/EPS2016PAP/pdf/P5.009.pdf}},
  ISBN={2-914771-99-1},
  Volume = {{40A}},
  abstract={},
  series = {europhysics conference abstracts},
}

@ARTICLE{Svoboda2016,
author={Svoboda, V. and Dvornova, A and Dejarnac, R  and Prochazka, M and Zaprianov, S and Akhmethanov, R and Bogdanova, M and Dimitrova, M and Dimitrov, Z  and Grover, O  and Hlavata, L  and Ivanov, K  and Kruglov, K  and Marinova, P  and Masherov, P  and Mogulkin, A  and Mlynar, J  and Stockel, J and Volynets, A },
title={Remote operation of the GOLEM tokamak with hydrogen and helium plasmas},
journal={Journal of Physics: Conference Series},
year={2016},
volume={768},
number={1},
doi={10.1088/1742-6596/768/1/012002},
art_number={012002},
note={},
url={https://www.scopus.com/inward/record.uri?eid=2-s2.0-84996848706&doi=10.1088%2f1742-6596%2f768%2f1%2f012002&partnerID=40&md5=e2758016f6bdd51be8c02e6f972a374e},
affiliation={Faculty of Nuclear Physics and Physical Engineering, CTU, Prague, Czech Republic; Moscow Engineering Physics Institute (MePhi), Moscow, Russian Federation; Institute of Plasma Physics, AS CR, Za Slovankou 3, Prague, Czech Republic; Faculty of Chemistry, Brno University of Technology, Brno, Czech Republic; St. Kliment Ohridski University of Sofia, Bulgaria; Acad. E. Djakov Institute of Electronics, Bulgarian Academy of Sciences, Sofia, Bulgaria; Research Institute of Applied Mechanics and Electrodynamics, Moscow Aviation Institute (National Research University), Moscow, Russian Federation; Faculty of Physics, M.V.Lomonosov Moscow State University, Moscow, Russian Federation},
abstract={The GOLEM tokamak was operated remotely via Internet connection during the 6th International Workshop and Summer School on Plasma Physics. Performances of hydrogen and helium discharges are compared in this paper. It is found, at similar vacuum conditions, that helium discharges are shorter but the breakdown of the working gas can be quite easily achieved at almost the same loop voltage. The plasma current in helium discharges is slightly lower than in the case of hydrogen. Turbulent fluctuations of the floating potential measured by means of an array of Langmuir probes reveal a noticeably different character in the two discharges. © Published under licence by IOP Publishing Ltd.},
document_type={Conference Paper},
source={Scopus},
}

@inproceedings{Svoboda15:235954,
	author = {Svoboda, V. and Ficker, O. and Dimitrova, M. and Grover, O. and Kocman, J. and Krbec, J. and L{\" o}ffelmann, V. and Mat{\v e}na, L. and St{\" o}ckel, J., and Vondr{\' a}{\v s}ek, G.},
	title = {Tokamak GOLEM for fusion education - chapter 6},
	booktitle = {42nd European Physical Society Conference on Plasma Physics},
	address = {Mulhouse, FR},
	year = {2015},
	isbn = {2-914771-98-3},
	language = {English},
	url = {http://ocs.ciemat.es/EPS2015PAP/pdf/P2.164.pdf}
}

@article{Grover2016,
title = "Remote operation of the {GOLEM} tokamak for Fusion Education ",
journal = "Fusion Engineering and Design ",
volume = "112",
number = "",
pages = "1038-1044",
year = "2016",
note = "",
issn = "0920-3796",
doi = "http://dx.doi.org/10.1016/j.fusengdes.2016.05.009",
author = "O. Grover and J. Kocman and M. Odstrcil and T. Odstrcil and M. Matusu and J. Stockel and V. Svoboda and G. Vondrasek and J. Zara",
keywords = "Tokamak technology",
keywords = "Remote participation",
keywords = "Education",
keywords = "Nuclear fusion ",
abstract = "Abstract Practically oriented education in the field of thermonuclear fusion is highly requested. However, the high complexity of appropriate experiments makes it difficult to develop and maintain laboratories where students can take part in hands-on experiments in this field of study. One possible solution is to establish centres with specific high temperature plasma experiments where students can visit such a laboratory and perform their experiments in-situ. With the advancements of \{IT\} technologies it naturally follows to make a step forward and connect these with necessary plasma physics technologies and thus allow to access even sophisticated experiments remotely. Tokamak {GOLEM} is a small, modest device with its infrastructure linked to web technologies allowing students to set-up necessary discharge parameters, submit them into a queue and within minutes obtain the results in the form of a discharge homepage. "
}



@article{0029-5515-55-10-104019,
  author={M. Gryaznevich and G. Van Oost and J. Stöckel and R. Kamendje and B.N. Kuteev and A. Melnikov and T. Popov and V. Svoboda and The
IAEA CRP Teams},
  title={Contribution to fusion research from IAEA coordinated research projects and joint experiments},
  journal={Nuclear Fusion},
  volume={55},
  number={10},
  pages={104019},
  year={2015},
  doi = {https://doi.org/10.1088/0029-5515/55/10/104019}
  abstract={The paper presents objectives and activities of IAEA Coordinated Research ProjectsConceptual development of steady-state compact fusion neutron sourcesandUtilisation of a network of small magnetic confinement fusion devices for mainstream fusion research’. The background and main projects of the CRP on FNS are described in detail, as this is a new activity at IAEA. Recent activities of the second CRP, which continues activities of previous CRPs, are overviewed.}
}

@article{Markovic2015,
title = "Development of 3D ferromagnetic model of tokamak core with strong toroidal asymmetry ",
journal = "Fusion Engineering and Design ",
volume = "96-97",
number = "",
pages = "302-305",
year = "2015",
note = "",
issn = "0920-3796",
doi = "http://dx.doi.org/10.1016/j.fusengdes.2015.03.041",
url = {http://www.sciencedirect.com/science/article/pii/S0920379615002100},
author = "T. Markovic and M. Gryaznevich and I. Duran and V. Svoboda and R. Panek",
keywords = "Tokamak",
keywords = "Ferromagnetic core",
keywords = "Integral method",
keywords = "Model of ferromagnet",
keywords = "Tokamak {GOLEM} ",
abstract = "Abstract Fully 3D model of strongly asymmetric tokamak core, based on boundary integral method approach (i.e. characterization of ferromagnet by its surface) is presented. The model is benchmarked on measurements on tokamak GOLEM, as well as compared to 2D axisymmetric core equivalent for this tokamak, presented in previous work. Linearized model well describes quantitative characteristics of \{BR\} field, generated by poloidal field coils located close to core central column, and distorted by ferromagnet. A discrepancy is seen between linearized form of model for \{BR\} field generated by coils under the transformer limbs and the measurements. Future work will thus include implementation of the non-linearity effects in order to further investigate this issue. "
}
@article{Svoboda2015,
title = "Remote operation of the vertical plasma stabilization @ the {GOLEM} tokamak for the plasma physics education ",
journal = "Fusion Engineering and Design ",
volume = "96-97",
number = "",
pages = "974-979",
year = "2015",
note = "",
issn = "0920-3796",
doi = "http://dx.doi.org/10.1016/j.fusengdes.2015.06.044",
url = "http://www.sciencedirect.com/science/article/pii/S0920379615300740",
author = "V. Svoboda and J. Kocman and O. Grover and J. Krbec and J. Stockel",
keywords = "Tokamak technology",
keywords = "Remote participation",
keywords = "Plasma stabilization",
keywords = "Education",
keywords = "Nuclear fusion ",
abstract = "Abstract The {GOLEM} tokamak at the Czech Technical University has been established as an educational tokamak device for domestic and foreign students. Remote participation in the scope of several laboratory practices, plasma physics schools and workshops has been successfully performed from abroad. A new enhancement allowing understandable remote control of vertical plasma position in two modes (i) predefined and (ii) feedback control is presented. It allows to drive the current in the stabilization coils in any time-dependent scenario, which can include as a parameter the actual plasma position measured by magnetic diagnostics. Arbitrary movement of the plasma column in a vertical direction, stabilization of the plasma column in the center of the tokamak vessel as well as prolongation/shortening of plasma life according to the remotely defined request are demonstrated. "
}





@InProceedings{EPSBerlin2014,
  author = 	 {O. Ficker, O. Grover , J. Kocman, J. Krbec, V. Loffelmann, T. Markovic , M. Matusu, J. Stockel, V. Svoboda, J. Veverka, G. Vondrasek},
  title = 	 {{Tokamak GOLEM for fusion education - chapter 5 }},
  booktitle =    {Europhysics Conference Abstracts. 41th EPS Conference on Plasma Physics (online: \url{http://ocs.ciemat.es/EPS2014PAP/pdf/P4.141.pdf})},
  year = 	 {2014},
  howpublished={\url{http://ocs.ciemat.es/EPS2014PAP/pdf/P4.141.pdf}},
  ISBN={2-914771-90-8},
  Volume = {{38F}},
  abstract={Tokamak GOLEM is one of the oldest tokamaks in the world, currently located at the Faculty of Nuclear Sciences and Physical Engineering, CTU in Prague. It serves as an educational device and all experiments and development are done by students themselves under professional supervision. The contribution covers the major improvements made over the last year.
},
}


@article{:/content/aip/journal/rsi/83/10/10.1063/1.4731003,
   author = "Odstrcil, T. and Odstrcil, M. and Grover, O. and Svoboda, V. and Duran, I. and Mlynar, J.",
   title = "Low cost alternative of high speed visible light camera for tokamak experimentsa)",
   journal = "Review of Scientific Instruments",
   year = "2012",
   volume = "83",
   number = "10", 
   eid = "10E505",
   pages = "-",
   url = "http://scitation.aip.org/content/aip/journal/rsi/83/10/10.1063/1.4731003",
   doi = "http://dx.doi.org/10.1063/1.4731003" 
}


@InProceedings{EPSHelsinky2013,
  author = 	 {Hernandez-Arriaga, D. and  Brotankova, J. and Grover, O. and Kocman, J. and Markovic, T. and Odstrcil, M. and Odstrcil, T. and Ruzickova, T. and Stockel, J. and Svoboda, V. and Vondrasek, G.},
  title = 	 {{Tokamak GOLEM for fusion education - chapter 4 }},
  booktitle =    {Europhysics Conference Abstracts. 40th EPS Conference on Plasma Physics (online: \url{http://ocs.ciemat.es/EPS2013PAP/pdf/P2.410.pdf})},
  year = 	 {2013},
  howpublished={\url{http://ocs.ciemat.es/epsicpp2012pap/pdf/P2.059.pdf}},
  isbn = {978-1-63266-310-8},
  Volume = {{}},
  abstract={},
}

@article{Markovic2013835,
title = "Evaluation of applicability of 2D iron core model for two-limb configuration of {GOLEM} tokamak ",
journal = "Fusion Engineering and Design ",
volume = "88",
number = "6-8",
pages = "835 - 838",
year = "2013",
zmb_note = "Proceedings of the 27th Symposium On Fusion Technology (SOFT-27); Liege, Belgium, September 24-28, 2012 ",
issn = "0920-3796",
doi = "http://dx.doi.org/10.1016/j.fusengdes.2013.02.142",
url = "http://www.sciencedirect.com/science/article/pii/S0920379613002573",
author = "T. Markovic and M. Gryaznevich and I. Duran and V. Svoboda and G. Vondrasek",
keywords = "Tokamak",
keywords = "Ferromagnetic core",
keywords = "Integral method",
keywords = "Tokamak \{GOLEM\} ",
abstract = "This paper presents evaluation of applicability of 2D iron core model for highly non-axisymmetric two limb configuration of \{GOLEM\} tokamak (former CASTOR). Presented results explain the long-term discrepancy between measured magnitudes of external poloidal field and those calculated by air-core approach on this tokamak. The model has been applied to two poloidal planes at different toroidal angles in the vacuum vessel region and has shown that close to central column of the transformer, it is possible to correct for 3D effects by variation of chosen dimensions of axisymmetric iron core model. Satisfactory agreement of the 2D model results with the measured distribution of \{BR\} field component was achieved. "
}




@article{Gryaznevich2013,
title = "Progress in application of high temperature superconductor in tokamak magnets ",
journal = "Fusion Engineering and Design ",
volume = "88",
number = "9-10",
pages = "1593 - 1596",
year = "2013",
issn = "0920-3796",
doi = "http://dx.doi.org/10.1016/j.fusengdes.2013.01.101",
url = "http://www.sciencedirect.com/science/article/pii/S0920379613001117",
author = "M. Gryaznevich and V. Svoboda and J. Stockel and A. Sykes and N. Sykes and D. Kingham and G. Hammond and P. Apte and T.N. Todd and S. Ball and S. Chappell and Z. Melhem and I. Duran and K. Kovarik and O. Grover and T. Markovic and M. Odstrcil and T. Odstrcil and A. Sindlery and G. Vondrasek and J. Kocman and M.K. Lilley and P. de Grouchy and H.-T. Kim",
keywords = "Tokamaks",
keywords = "\{HTS\}",
keywords = "Magnets ",
abstract = "It has long been known that high temperature superconductors (HTS) could have an important role to play in the future of tokamak fusion research. Here we report on first results of the use of HTS in a tokamak magnet and on the progress in design and construction of the first fully-HTS tokamak.",                                                                                                                                         
zmb_note = "Proceedings of the 27th Symposium On Fusion Technology (SOFT-27); Liege, Belgium, September 24-28, 2012 "
}      


@InProceedings{EPSStockholm2012,
  author = 	 {V. Svoboda and  I. Duran and O. Grover and M. Gryaznevich and J. Kocman and K. Kovarik  and T. Markovic  and M Odstrcil and T. Odstrcil and J. Stockel },
  title = 	 {{ Recent results from GOLEM tokamak. 'Indeed, you can teach an old dog some new tricks. }},
  booktitle =    {Europhysics Conference Abstracts. 39th EPS Conference on Plasma Physics (online: \url{http://ocs.ciemat.es/epsicpp2012pap/pdf/P2.059.pdf})},
  year = 	 {2012},
  howpublished={\url{http://ocs.ciemat.es/epsicpp2012pap/pdf/P2.059.pdf}},
  ISBN={},
  Volume = {{36F}},
  abstract={},
}

@InProceedings{EPSStockholm2012HTS,
  author = 	 {Ball, S. and Duran, I. and  Grover, O. and Gryaznevich, M. and Kocman, J. and Kovarik, K. and Markovic, T. and Odstrcil, M. and Odstrcil, T. and Ruzickova, T. and Stockel, J. and Svoboda  V. and Vondrasek, G.},
  title = 	 {{First results from tests of high temperature superconductor magnets on tokamak}},
  booktitle =    {Europhysics Conference Abstracts. 39th EPS Conference on Plasma Physics (online: \url{http://ocs.ciemat.es/epsicpp2012pap/pdf/P2.052.pdf})},
  year = 	 {2012},
  howpublished={\url{http://ocs.ciemat.es/epsicpp2012pap/pdf/P2.052.pdf}},
  ISBN={},
  Volume = {{36F}},
  abstract={},
}


@InProceedings{EPSStrasbourg2011,
  author = 	 {E. Bromova and I. Duran and O. Grover and J. Kocman and T. Markovic and M. Odstrcil and T. Odstrcil and O. Pluhar and J. Stockel and V. Svoboda and A. Sindlery and G. Vondrasek and J. Zara},
  title = 	 {{The GOLEM Tokamak for Fusion Education }},
  booktitle =    {Europhysics Conference Abstracts. 38th EPS Conference on Plasma Physics (online: \url{http://ocs.ciemat.es/EPS2011PAP/pdf/P1.021.pdf})},
  year = 	 {2011},
  howpublished={\url{http://ocs.ciemat.es/EPS2011PAP/pdf/P1.021.pdf}},
  ISBN={2-914771-68-1},
  Volume = {{35G}},
  abstract={The GOLEM tokamak, (formerly CASTOR), became an educational device for domestic as well as for foreign students via remote participation/handling. It operates routinely for nearly two years at modest range of parameters and with a limited set of diagnostics. Wide range of tasks with varying levels of complexity covering tokamak physics, technology and operation can be studied by the future fusion specialists. Currently the diagnostics enrichment is strategic for the education usability of the device. Students participate in large extent on additional standard diagnostics methods development, including density measurement via microwave interferometry, plasma position (including tomography) studies  using a set of Mirnov coils, two fast cameras and two linear arrays of bolometers. Moreover stabilization of the plasma position with an equilibrium magnetic field  generated in the vertical magnetic field coils and plasma spectroscopy issues are under consideration.},
}



@InProceedings{EPSDublin2010,
  author = 	 {V. Svoboda and J. Mlyn\'a\v r and G. Pokol and D. R\'efy and J. St\" ockel and G. Vondr\'a\v sek},
  title = 	 {{Former Tokamak CASTOR becomes remotely controllable GOLEM at the Czech Technical University in Prague }},
  booktitle =    {Europhysics Conference Abstracts. 37th EPS Conference on Plasma Physics (online: \url{http://ocs.ciemat.es/EPS2010PAP/pdf/P2.111.pdf})},
  year = 	 {2010},
  howpublished={\url{http://ocs.ciemat.es/EPS2010PAP/pdf/P2.111.pdf}},
  ISBN={2-914771-62-2},
  Volume = {{34A}},
  abstract={},
}

@inproceedings{Svoboda13:211785,
	author = {Svoboda, V. and Odstr{\v c}il, M. and Odstr{\v c}il, T., and Grover, O.},
	title = {Blind spectral unmixing and ion lines clustering of low resolution spectra based on non-negative matrix decomposition”},
	booktitle = {8th Workshop on Fusion Data Processing, Validation and Analysis},
	address = {Ghent},
	year = {2013},
	language = {English},
	url = {http://www.validation8.ugent.be/abstracts/Odstrcil_Tomas.pdf}
}


@inproceedings{Svoboda11:186333,
   author = {Svoboda, V. and St{\" o}ckel, J.},
   title = {{Tokamak GOLEM Remotely for Worldwide Fusion Education}},
   booktitle = {{Proceedings: SEFI - PTEE 2011}},
   publisher = {Hochschule Mannheim - University Of Applied Sciences},
   address = {Mannheim},
   year = {2011},
   pages = {--},
   ISBN = {978-3-931569-18-1},
   language = {English},
   URL = {http://sefi11.hs-mannheim.de/index.php?option=com_content\&view=article\&id=27\&Itemid=27}
}









@article{FusenEngDes11,
Author = {Svoboda, V. and Huang, B. and Mlynar, J. and Pokol, G.I. and Stockel, J. and Vondrasek, G},
Title = {{Multi-mode Remote Participation on the GOLEM Tokamak}},
Journal = {{Fusion Engineering and Design}},
Year = {{2011}},
Volume = {{86}},
Number = {{6-8}},
Pages = {{1310-1314}},
Month = {{}},
Abstract = {{The GOLEM tokamak (formerly CASTOR) at Czech Technical University is demonstrated as an educational tokamak device for domestic and foreign students. Remote participation of several foreign universities (in Hungary, Belgium, Poland and Costa Rica) has been successfully performed.  A unique feature of the GOLEM device is functionality which enables complete remote participation and control, solely through Internet access.  Basic remote control is possible either in online mode via WWW/SSH interface or offline mode using batch processing code.  Discharge parameters are set in each case to configure the tokamak for a plasma discharge.  Using the X11 protocol it is possible to control in an advanced mode many technological aspects of the tokamak operation, including: i) vacuum pump initialization, ii) chamber baking, iii) charging of power supplies, iv) plasma discharge scenario, v) data acquisition system.}},
DOI = {{10.1016/j.fusengdes.2011.02.069}},
ISSN = {{0920-3796}},
howpublished={http://dx.doi.org/10.1016/j.fusengdes.2011.02.069},
Unique-ID = {{}},
}



@Misc{iternews,
author={{ITER news}},
title ={{Launch of the world's first global tokamak experiment}},
howpublished={http://www.iter.org/newsline/156/512},
year={2010},
online={2010},}



@MISC{GOLEM2007,
  author = {{Tokamak GOLEM contributors}},
  title = {{Tokamak GOLEM at the Czech Technical University in Prague}},
  howpublished = {http://golem.fjfi.cvut.cz},
  year = {2007},
  online = {2010}
}

@MISC{GTE2010,
  author = {B. Huang and V. Nikolaeva},
  title = {{Global Tokamak Experiment}},
  howpublished = {http://tokamakglobal.com/},
  year = {2010},
  online = {2010}
}