학술논문
Design and Testing of the Front-End Electronics of WCDA in LHAASO
Document Type
Periodical
Author
Aharonian, F.; An, Q.; Axikegu, .; Bai, L.X.; Bai, Y.X.; Bao, Y.W.; Bastieri, D.; Bi, X.J.; Bi, Y.J.; Cai, H.; Cai, J.T.; Cao, Z.; Chang, J.; Chang, J.F.; Chang, X.C.; Chen, B.M.; Chen, J.; Chen, L.; Chen, M.J.; Chen, M.L.; Chen, Q.H.; Chen, S.H.; Chen, S.Z.; Chen, T.L.; Chen, X.L.; Chen, Y.; Cheng, N.; Cheng, Y.D.; Cui, S.W.; Cui, X.H.; Cui, Y.D.; Dai, B.Z.; Dai, H.L.; Dai, Z.G.; Danzengluobu, .; Dong, R.S.; Dong, X.J.; Fan, J.H.; Fan, Y.Z.; Fan, Z.X.; Fang, J.; Fang, K.; Feng, C.F.; Feng, L.; Feng, S.H.; Feng, Y.L.; Gao, B.; Gao, C.D.; Gao, Q.; Gao, W.; Ge, M.M.; Geng, L.S.; Gong, G.H.; Gou, Q.B.; Gu, J.L.; Gu, M.H.; Guo, J.G.; Guo, X.L.; Guo, Y.Q.; Guo, Y.Y.; Han, Y.A.; He, H.H.; He, H.N.; He, J.C.; He, S.L.; He, X.B.; He, Y.; He, Z.Q.; Heller, M.; Hor, Y.K.; Hou, C.; Hou, X.; Hu, H.B.; Hu, S.; Hu, S.C.; Hu, X.J.; Huang, D.H.; Huang, Q.L.; Huang, W.H.; Huang, X.T.; Huang, Z.C.; Ji, F.; Ji, X.L.; Jia, H.Y.; Jiang, K.; Jiang, Z.J.; Jin, C.; Kuleshov, D.; Levochkin, K.; Li, B.B.; Li, C.; Li, F.; Li, H.B.; Li, H.C.; Li, H.Y.; Li, J.; Li, K.; Li, W.L.; Li, X.; Li, X.R.; Li, Y.; Li, Y.Z.; Li, Z.; Liang, E.W.; Liang, Y.F.; Lin, S.J.; Liu, B.; Liu, C.; Liu, D.; Liu, H.; Liu, H.D.; Liu, J.; Liu, J.L.; Liu, J.S.; Liu, J.Y.; Liu, M.Y.; Liu, R.Y.; Liu, S.M.; Liu, W.; Liu, Y.N.; Liu, Z.X.; Long, W.J.; Lu, R.; Lv, H.K.; Ma, B.Q.; Ma, L.L.; Ma, X.H.; Mao, J.R.; Masood, A.; Mitthumsiri, W.; Montaruli, T.; Nan, Y.C.; Pang, B.Y.; Pattarakijwanich, P.; Pei, Z.Y.; Piazzoli, B.D.; Qi, M.Y.; Qin, J.J.; Ruffolo, D.; Rulev, V.; Saiz, A.; Shao, L.; Shchegolev, O.; Sheng, X.D.; Shi, J.R.; Song, C.X.; Song, H.C.; Stenkin, Y.V.; Stepanov, V.; Sun, Q.N.; Sun, X.N.; Sun, Z.B.; Tam, P.H.T.; Tang, Z.B.; Tian, W.W.; della Volpe, D.; Wang, B.D.; Wang, C.; Wang, H.; Wang, H.G.; Wang, J.C.; Wang, J.S.; Wang, L.P.; Wang, L.Y.; Wang, R.N.; Wang, W.; Wang, X.G.; Wang, X.J.; Wang, X.Y.; Wang, Y.D.; Wang, Y.J.; Wang, Y.P.; Wang, Z.; Wang, Z.H.; Wang, Z.X.; Wei, D.M.; Wei, J.J.; Wei, Y.J.; Wen, T.; Wu, C.Y.; Wu, H.R.; Wu, S.; Wu, W.X.; Wu, X.F.; Xi, S.Q.; Xia, J.; Xia, J.J.; Xiang, G.M.; Xiao, G.; Xiao, H.B.; Xin, G.G.; Xin, Y.L.; Xing, Y.; Xu, D.L.; Xu, R.X.; Xue, L.; Yan, D.H.; Yan, X.B.; Yang, C.W.; Yang, F.F.; Yang, J.Y.; Yang, L.L.; Yang, M.J.; Yang, R.Z.; Yang, S.B.; Yao, Y.H.; Yao, Z.G.; Ye, Y.M.; Yin, L.Q.; Yin, N.; You, X.H.; You, Z.Y.; Yu, Y.H.; Yuan, Q.; Zeng, H.D.; Zeng, T.X.; Zeng, W.; Zeng, Z.K.; Zha, M.; Zhai, X.X.; Zhang, B.B.; Zhang, H.M.; Zhang, H.Y.; Zhang, J.L.; Zhang, J.W.; Zhang, L.; Zhang, L.X.; Zhang, P.F.; Zhang, P.P.; Zhang, R.; Zhang, S.R.; Zhang, S.S.; Zhang, X.; Zhang, X.P.; Zhang, Y.; Zhang, Y.F.; Zhang, Y.L.; Zhao, B.; Zhao, J.; Zhao, L.; Zhao, L.Z.; Zhao, S.P.; Zheng, F.; Zheng, Y.; Zhou, B.; Zhou, H.; Zhou, J.N.; Zhou, P.; Zhou, R.; Zhou, S.Z.; Zhou, X.X.; Zhu, C.G.; Zhu, F.R.; Zhu, H.; Zhu, K.J.; Zuo, X.
Source
IEEE Transactions on Nuclear Science IEEE Trans. Nucl. Sci. Nuclear Science, IEEE Transactions on. 68(8):2257-2267 Aug, 2021
Subject
Language
ISSN
0018-9499
1558-1578
1558-1578
Abstract
Water Cherenkov detector array (WCDA) is one of the key parts of the Large High Altitude Air Shower Observatory (LHAASO), the construction of which was completed by the end of 2020. The WCDA covers a 78 000-m 2 area and there exist 3120 large size photomultiplier tubes (PMTs) in three ponds: 8-in PMTs are used in WCDA pond No. 1 and 20-in PMTs are used in ponds No. 2 and No. 3. The front-end electronics (FEE) system based on multigain measurement technique is designed to achieve both high-precision time and charge measurements over a large dynamic range from single photon electron (S.P.E.) to 4000 P.E. (for water pond No. 1)/1800 P.E. (for water ponds No. 2 and No. 3). To achieve a high-quality clock distribution and phase alignment as well as mixed transmission of data, clock, and commands in one fiber over a long distance, an enhanced white rabbit (WR) technique is used. Testing of all the 350 FEE modules for the WCDA is presented in this article. Test results indicate that the charge resolution is better than 20% at S.P.E. and 1% at 1800/4000 P.E. and the time resolution is better than 300 ps root mean square (rms), which successfully meets the application requirement. All the FEE modules have been fabricated and installed for the LHAASO WCDA from 2018 to 2020, and the initial commissioning operation indicates that the FEEs function well.