Absolute calibration of LHAASO WFCTA camera based on LED

Felix Aharonian,Q. An,Axikegu,L. X. Bai,Bai Yibing,Y.W Bao,D. Bastieri,X. J. Bi,Y. J. Bi,H Cai,J. T. Cai,Zhengguo Cao,Zhe Cao,J. F. Chang,Jinfan Chang,B.M. Chen,E. S Chen,J. Chen,Liang Chen,Long Chen,M.J. Chen,M. L. Chen,Q. H. Chen,S. H. Chen,S. Z. Chen,T. L. Chen,X. L. Chen,Yu-Lei Chen,N Cheng,Y D Cheng,S. W. Cui,X. H. Cui,Y D Cui,B. Z. Dai,H. L. Dai,Z. G. Dai,Danzengluobu,D. della Volpe,B. DEttorre-Piazzoli,X. J. Dong,Kai-Kai Duan,Jun-Hui Fan,Y. Z. Fan,Z.X. Fan,J. Fang,Kun Fang,C. F. Feng,L. Feng,S.H. Feng,Y. L. Feng,Y.T. Fu,H. Y. Gan,B. S. Gao,C.D Gao,L. Q. Gao,Q. Gao,W. Gao,M.M. Ge,Li-Sheng Geng,G.H. Gong,Q. B. Gou,M. H. Gu,Fulai Guo,J. G. Guo,X.L. Guo,Y.Q. Guo,Y. Y. Guo,Y. A. Han,H. H. He,H.-N. He,J C He,S. L. He,Xinbo He,Y. He,M. Heller,Y. K. Hor,C. Hou,Huaichuan Hu,Shi-Qi Hu,S. Hu,Xiaofan Hu,D.H. Huang,Huang Qiyan,W-H Huang,X. T. Huang,X. Y. Huang,Z. C. Huang,F. Ji,X. L. Ji,H. Y. Jia,K. Jiang,Z. J. Jiang,Chiming Jin,T. Ke,D. A. Kuleshov,K. Levochkin,B. B. Li,Cong Li,Cheng Li,F. Li,H. B. Li,H.C Li,Hefan Li,J. Q. Li,K.H. Li,Wei Li,Xin Li,Xufang Li,Youping Li,Y Z Li,Zhe Li,Zhuo Li,E. W. Liang,Yun-Feng Liang,Shuibin Lin,Bingxuan Liu,C. X. Liu,D Liu,H. B. Liu,H.D. Liu,J. Liu,J.L. Liu,J. S. Liu,J. Y. Liu,Mao-Yuan Liu,R. Liu,Shujuan Liu,W. Liu,Yunchao Liu,Y.-N. Liu,Z.-X. Liu,W. J. Long,R. Lu,H.-K. Lv,B. Q. Ma,L. L. Ma,X.H. Ma,Jirong Mao,A Masood,Z. Min,Warit Mitthumsiri,T. Montaruli,Y.C. Nan,B.Y. Pang,P. Pattarakijwanich,Z. Y. Pei,M. Qi,Y. Q. Qi,Bing-Qiang Qiao,Jiajun Qin,David Ruffolo,V. Rulev,Alejandro Saiz,Lang Shao,Oleg Shchegolev,Sheng Xiuli,J. Y. Shi,H. C. Song,Yu. V. Stenkin,V. I. Stepanov,Y. Su,Qiangqiang Sun,X. N. Sun,Z.B. Sun,Pak-Hin Thomas Tam,Zebo Tang,Wenwu Tian,B D Wang,Cunguo Wang,H. Wang,Hong-Guang Wang,J. C. Wang,Jian Wang,L. P. Wang,Lu Wang,R. N. Wang,W. Wang,Xiang-Gao Wang,Xuelong Wang,X-Y Wang,Y. D. Wang,Y. D. Wang,Yu-Ming Wang,Y. P. Wang,Z. H. Wang,Zhi-Min Wang,Zhen Wang,Zheng Wang,D. M. Wei,Jun-Jie Wei,Y.-J. Wei,T. Wen,C.-Y. Wu,H. R. Wu,S. Wu,W. X. Wu,X. F. Wu,S.-Q. Xi,J. Xia,J. J. Xia,G.M. Xiang,D.X.Xiao,G. C. Xiao,H B Xiao,G G Xin,Y. L. Xin,Y. M. Xing,Dong Xu,Rong Xu,L Xue,Duo Yan,J Z Yan,C.W. Yang,F.F Yang,J.Y. Yang,Linbin Yang,M. J. Yang,R. Z Yang,S. B. Yang,Yu-Hua Yao,Zhiguo Yao,Y.-M. Ye,L.Q. Yin,N Yin,X.H. You,Z. Y. You,Y.H. Yu,Q Yuan,Houdun Zeng,Tao Zeng,W. Zeng,Z. K. Zeng,M. Zha,X.X. Zhai,Bo Zhang,H. Zhang,H.Y. Zhang,J.L. Zhang,Jingyu Zhang,Lu Zhang,Li Zhang,L. X. Zhang,P. F. Zhang,P.P. Zhang,R. Zhang,S.R. Zhang,S. S. Zhang,X Y Zhang,X. P. Zhang,Yong Zhang,Y. L. Zhang,Yong Zhang,Yi Zhang,Binyu Zhao,J. B. Zhao,L. Zhao,Lei Zhao,S. P. Zhao,F Zheng,Y. Zheng,B. Zhou,Hao Zhou,J.N. Zhou,Ping Zhou,R Zhou,X. X. Zhou,C. G. Zhu,F. R. Zhu,H. Zhu,K. J. Zhu,X. Zuo

Absolute calibration of LHAASO WFCTA camera based on LED

2021

Abstract The main scientific goal of the LHAASO WFCTA experiment is to measure the cosmic ray energy spectra and composition from 10 TeV to 1 EeV. Cherenkov photons in the extensive air shower measured by the SiPM camera of Cherenkov telescopes can be used to reconstruct the cosmic ray energy. The absolute calibration of the camera is a crucial step to achieve the accurate measurement of the cosmic ray energy spectrum. A multi-wavelength cylindrical illuminator based on LEDs is developed and mounted inside the telescope to calibrate and monitor the camera, and the illuminator’s stability is better than 0.5% under the temperature variation from -26 to 26 ° C. A portable probe with a single photoelectron resolution of 21.6% is developed. After calibration by National Institute of Metrology, China (NIM), the probe is taken to the LHAASO site to measure the absolute photon density of the cylindrical illuminator inside the telescope. Based on the illuminator with known photon density, the photon conversion factor of the camera can be calibrated, and the overall calibration uncertainty is less than 2.6%.

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