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Camera of the first TAIGA-IACT : Construction and calibration. / TAIGA Collaboration.

в: Proceedings of Science, Том Part F135186, 01.01.2017.

Результаты исследований: Научные публикации в периодических изданиях › статья по материалам конференции › Рецензирование

Harvard

TAIGA Collaboration 2017, 'Camera of the first TAIGA-IACT: Construction and calibration', Proceedings of Science, Том. Part F135186.

APA

TAIGA Collaboration (2017). Camera of the first TAIGA-IACT: Construction and calibration. Proceedings of Science, Part F135186.

Vancouver

TAIGA Collaboration. Camera of the first TAIGA-IACT: Construction and calibration. Proceedings of Science. 2017 янв. 1;Part F135186.

Author

TAIGA Collaboration. / Camera of the first TAIGA-IACT : Construction and calibration. в: Proceedings of Science. 2017 ; Том Part F135186.

BibTeX

@article{f59a079ac6054290b9b191c995720f5a,

title = "Camera of the first TAIGA-IACT: Construction and calibration",

abstract = "The first imaging atmospheric Cherenkov telescope as a part of the TAIGA (Tunka Advanced Instrument for cosmic rays and Gamma Astronomy) detector was put into commission in the Tunka valley in December 2016. The reflector of the telescope follows the Davis-Cotton design. It is composed of 34 glassmirror tiles, each of 60 cm diameter, and has a diameter of 4.3 m. The focal length is 4.75 m. The imaging camera includes 560 photomultiplier-based pixels, providing a FoV of ∼10×10 degrees. The imaging camera is made by using a modular principle and includes trigger, data acquisition and processing systems based on MAROC3 chips. The slow control system monitors the count rate and the PMT anode currents as well as controls the high voltage. For monitoring performance of the camera a dedicated calibration system based on nanosecond pulsed LED light source was developed.",

author = "{the TAIGA Collaboration} and N. Lubsandorzhiev and I. Astapov and P. Bezyazeekov and V. Boreyko and A. Borodin and M. Brueckner and N. Budnev and A. Chiavassa and A. Dyachok and O. Fedorov and A. Gafarov and A. Garmash and N. Gorbunov and V. Grebenyuk and O. Gress and T. Gress and O. Grishin and A. Grinyuk and D. Horns and A. Igoshin and A. Ivanova and N. Kalmykov and Y. Kazarina and V. Kindin and P. Kirilenko and S. Kiryuhin and R. Kokoulin and K. Kompaniets and E. Korosteleva and V. Kozhin and E. Kravchenko and M. Kunnas and L. Kuzmichev and Yu Lemeshev and V. Lenok and B. Lubsandorzhiev and R. Mirgazov and R. Mirzoyan and R. Monkhoev and R. Nachtigall and E. Osipova and A. Pakhorukov and M. Panasyuk and L. Pankov and A. Petrukhin and V. Poleschuk and E. Popescu and E. Popova and A. Porelli and A. Sokolov",

note = "Publisher Copyright: {\textcopyright} Copyright owned by the author(s) under the terms of the Creative Commons. {\textcopyright} Copyright owned by the author(s) under the terms of the Creative Commons Attribution-Non Commercial-No Derivatives 4.0 International License (CC BY-NC-ND 4.0).",

year = "2017",

month = jan,

day = "1",

language = "English",

volume = "Part F135186",

journal = "Proceedings of Science",

issn = "1824-8039",

publisher = "Sissa Medialab Srl",

}

RIS

TY - JOUR

T1 - Camera of the first TAIGA-IACT

T2 - Construction and calibration

AU - the TAIGA Collaboration

AU - Lubsandorzhiev, N.

AU - Astapov, I.

AU - Bezyazeekov, P.

AU - Boreyko, V.

AU - Borodin, A.

AU - Brueckner, M.

AU - Budnev, N.

AU - Chiavassa, A.

AU - Dyachok, A.

AU - Fedorov, O.

AU - Gafarov, A.

AU - Garmash, A.

AU - Gorbunov, N.

AU - Grebenyuk, V.

AU - Gress, O.

AU - Gress, T.

AU - Grishin, O.

AU - Grinyuk, A.

AU - Horns, D.

AU - Igoshin, A.

AU - Ivanova, A.

AU - Kalmykov, N.

AU - Kazarina, Y.

AU - Kindin, V.

AU - Kirilenko, P.

AU - Kiryuhin, S.

AU - Kokoulin, R.

AU - Kompaniets, K.

AU - Korosteleva, E.

AU - Kozhin, V.

AU - Kravchenko, E.

AU - Kunnas, M.

AU - Kuzmichev, L.

AU - Lemeshev, Yu

AU - Lenok, V.

AU - Lubsandorzhiev, B.

AU - Mirgazov, R.

AU - Mirzoyan, R.

AU - Monkhoev, R.

AU - Nachtigall, R.

AU - Osipova, E.

AU - Pakhorukov, A.

AU - Panasyuk, M.

AU - Pankov, L.

AU - Petrukhin, A.

AU - Poleschuk, V.

AU - Popescu, E.

AU - Popova, E.

AU - Porelli, A.

AU - Sokolov, A.

N1 - Publisher Copyright: © Copyright owned by the author(s) under the terms of the Creative Commons. © Copyright owned by the author(s) under the terms of the Creative Commons Attribution-Non Commercial-No Derivatives 4.0 International License (CC BY-NC-ND 4.0).

PY - 2017/1/1

Y1 - 2017/1/1

N2 - The first imaging atmospheric Cherenkov telescope as a part of the TAIGA (Tunka Advanced Instrument for cosmic rays and Gamma Astronomy) detector was put into commission in the Tunka valley in December 2016. The reflector of the telescope follows the Davis-Cotton design. It is composed of 34 glassmirror tiles, each of 60 cm diameter, and has a diameter of 4.3 m. The focal length is 4.75 m. The imaging camera includes 560 photomultiplier-based pixels, providing a FoV of ∼10×10 degrees. The imaging camera is made by using a modular principle and includes trigger, data acquisition and processing systems based on MAROC3 chips. The slow control system monitors the count rate and the PMT anode currents as well as controls the high voltage. For monitoring performance of the camera a dedicated calibration system based on nanosecond pulsed LED light source was developed.

AB - The first imaging atmospheric Cherenkov telescope as a part of the TAIGA (Tunka Advanced Instrument for cosmic rays and Gamma Astronomy) detector was put into commission in the Tunka valley in December 2016. The reflector of the telescope follows the Davis-Cotton design. It is composed of 34 glassmirror tiles, each of 60 cm diameter, and has a diameter of 4.3 m. The focal length is 4.75 m. The imaging camera includes 560 photomultiplier-based pixels, providing a FoV of ∼10×10 degrees. The imaging camera is made by using a modular principle and includes trigger, data acquisition and processing systems based on MAROC3 chips. The slow control system monitors the count rate and the PMT anode currents as well as controls the high voltage. For monitoring performance of the camera a dedicated calibration system based on nanosecond pulsed LED light source was developed.

UR - http://www.scopus.com/inward/record.url?scp=85046058522&partnerID=8YFLogxK

M3 - Conference article

VL - Part F135186

JO - Proceedings of Science

JF - Proceedings of Science

SN - 1824-8039

ER -

ID: 12562509