Estimation of aperture of the Tunka-Rex radio array for cosmic-ray air-shower measurements

V. Lenok, P. Bezyazeekov, N. Budnev, O. Fedorov, O. Gress, O. Grishin, A. Haungs, T. Huege, Y. Kazarina, M. Kleifges, E. Korosteleva, D. Kostunin, L. Kuzmichev, N. Lubsandorzhiev, S. Malakhov, T. Marshalkina, R. Monkhoev, E. Osipova, A. Pakhorukov, L. Pankov, V. Prosin, F. Schroder, D. Shipilov, A. Zagorodnikov
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引用次数: 4

Abstract

The recent progress in the radio detection technique for air showers paves the path to future cosmic-ray radio detectors. Digital radio arrays allow for a measurement of the air-shower energy and depth of its maximum with a resolution comparable to those of the leading optical detection methods. One of the remaining challenges regarding cosmic-ray radio instrumentation is an accurate estimation of their efficiency and aperture. We present a probabilistic model to address this challenge. We use the model to estimate the efficiency and aperture of the Tunka-Rex radio array. The basis of the model is a parametrization of the radio footprint and a probabilistic treatment of the detection process on both the antenna and array levels. In this way, we can estimate the detection efficiency for air showers as function of their arrival direction, energy, and impact point on the ground. In addition, the transparent internal relationships between the different stages of the air-shower detection process in our probabilistic approach enable to estimate the uncertainty of the efficiency and, consequently, of the aperture of radio arrays. The detail of the model and its application to the Tunka-Rex data will be presented in the contribution.
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Tunka-Rex射电阵列用于宇宙射线气簇测量的孔径估计
最近在空气簇射电探测技术上的进展为未来的宇宙射线射电探测器铺平了道路。数字无线电阵列允许测量风淋能量和最大深度,其分辨率可与领先的光学检测方法相媲美。关于宇宙射线无线电仪器仍然存在的挑战之一是准确估计它们的效率和孔径。我们提出了一个概率模型来解决这一挑战。利用该模型对Tunka-Rex射电阵列的效率和孔径进行了估计。该模型的基础是无线电足迹的参数化和天线和阵列水平上探测过程的概率处理。这样,我们就可以估计出空气阵雨的探测效率是其到达方向、能量和地面撞击点的函数。此外,在我们的概率方法中,风淋探测过程的不同阶段之间的透明内部关系使我们能够估计效率的不确定性,从而估计无线电阵列孔径的不确定性。该模型的细节及其在Tunka-Rex数据中的应用将在报告中介绍。
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