The method for RT-32 radio telescope error matrix construction in automatic mode. Automatic assesment of tracking errors

1Vlasenko, VP, 1Mamarev, VM, 1Ozhynsky, VV, 2Ulyanov, OM, 2Zakharenko, VV, 3Palamar, MI, 3Chaikovskyi, AV, 4Fryz, SP
1National Center of Space Facilities Control and Test, Kyiv, Ukraine
2Institute of Radio Astronomy of the National Academy of Science of Ukraine, Kharkiv, Ukraine
3Ternopil Ivan Pului National Technical University, Ternopil, Ukraine
4Zhytomyr Military institute named by Serhii Korolov, Zhytomyr, Ukraine
Space Sci. & Technol. 2021, 27 ;(6):053-064
https://doi.org/10.15407/knit2021.06.053
Язык публикации: Ukrainian
Аннотация: 
On March 15th, 2021, scientists of the National Space Facilities Control and Tests Center and the Radio Astronomical Institute of the National Academy of Sciences of Ukraine carried out preliminary observations with the Ukrainian new generation radio telescope RT-32 (Zolochiv, Lviv region). The extragalactic radiation of radio galaxy 3C84 (Perseus-A), masers from the galactic molecular cloud W3, radio emission of methanol maser from the galactic radio source G188.946 + 0.886 were observed and successfully recorded. Observations were performed as training in the framework of preparation for the launch of a joint Ukrainian-Latvian radio astronomy project lzp-2020/2-0121.
        The results of the observations confirmed the world level of RT-32 radio telescope characteristics, the efficiency of the primary error matrix and revealed several shortcomings in the functioning of the tracking system. It was found that the primary tracking error matrix has insufficient discreteness and contains errors of the first and second types.
           In the article, we present a method of automatic construction of the radio telescope error matrix according to the data of a radiometric receiver and receivers-recorders. The method of construction provides automatic processing of the obtained radiometric data. The results of verification of the developed method using the reference radio sources of different types and the elements of tracking errors’ matrix by the elevation and azimuth obtained when using it are presented. The results obtained with the proposed method were included in the radio telescope control system and allowed us to increase the aiming accuracy of the RT-32 radio telescope.
Keywords: radio telescope, tracking error matrix, antenna system, radio sources.
Ключевые слова: antenna system, radio sources, radio telescope, tracking error matrix
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