Optimization of Receiver Optics for Radio Astronomy

作者

  • Kim Ho Yeap Faculty of Engineering and Green Technology Universiti Tunku Abdul Rahman, Jalan Universiti, Bandar Barat, 31900 Kampar, Perak. Malaysia
  • Mey Chern Loh Faculty of Engineering and Green Technology Universiti Tunku Abdul Rahman, Jalan Universiti, Bandar Barat, 31900 Kampar, Perak. Malaysia
  • Peh Chiong Teh Faculty of Engineering and Green Technology Universiti Tunku Abdul Rahman, Jalan Universiti, Bandar Barat, 31900 Kampar, Perak. Malaysia
  • Veerendra Dakulagi Department of Computer Science and Engineering (Data Science) Guru Nanak Dev Engineering College, Bidar, Mailoor Road, Bidar 585403, Karnataka, India

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https://doi.org/10.13052/2024.ACES.J.391109

关键词:

Aperture efficiency, beam efficiency, feed optics, radio telescope, spillover efficiency

摘要

In a radio telescope, the sub-reflector is illuminated by a complex feed system, consisting of a feed horn and a pair of optics focusing elements which are usually a pair of mirrors. Although rigorous analysis of this system can be performed using Method of Moments (MoM) or physical optics (POs), design optimization using these methods may not be viable, since it requires lengthy computational time. In this paper, we describe an efficient optimization technique for the optics design which applies the quadratic on a pedestal distribution to compute the taper and aperture efficiencies. In our method, multimode Gaussian optics is employed to calculate the electromagnetic waves which scatter through the optical system. The edge taper associated with the optimum aperture efficiency is first identified. By setting the parameters of this edge taper and also the distance between mirror 2 and the antenna focus as the iteration targets, a root-searching routine is then applied to determine the distances of the optical paths between the mirrors and the feed. When an optimized feed design is established, the antenna performance indicators, such as the beam efficiency, co- and cross-polarization levels, and aperture efficiencies, are calculated using PO. In this way, we combine the accuracy of the quadratic function in determining the antenna efficiencies and the computational efficiency of Gaussian optics to optimize the design of the system with the rigor of PO to validate the final parameters of the antenna. The design procedure for the Atacama Large Millimeter/Submillimeter Array (ALMA) interferometric radio telescope’s feed optics system is used as an illustrative example. The results show that the co-polar beam efficiencies achieved with the proposed method are higher than those of the original method used for the ALMA feed optics system, while the cross-polar beam efficiencies are lower. This suggests a substantial improvement offered by the newapproach.

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Kim Ho Yeap received his Bachelor of Engineering (Honors) from Universiti Teknologi Petronas, Master of Science from Universiti Kebangsaan Malaysia, and Ph.D. from Universiti Tunku Abdul Rahman. He is currently an associate professor in Universiti Tunku Abdul Rahman.

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Mey Chern Loh received both her Bachelor of Engineering (Honors) and Master of Engineering Science from Universiti Tunku Abdul Rahman. She is currently pursuing her doctorate degree in the same university.

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Peh Chiong Teh received his Bachelor of Engineering (Honors) from University of Manchester Institute of Science and Technology and Ph.D. from University of Southampton. He is currently an associate professor in Universiti Tunku Abdul Rahman.

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Veerendra Dakulagi earned his B.E. in electronics and communication engineering (E&CE) and MTech in power electronics from Visvesvaraya Technological University, Belagavi, India, in 2007 and 2011, respectively. He earned his Ph.D. degree in array signal processing from the same university in 2018. He is currently a professor in Guru Nanak Dev Engineering College, Bidar, India.

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已出版

2024-11-30

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[1]
K. H. . Yeap, M. C. . Loh, P. C. . Teh, 和 V. . Dakulagi, 《Optimization of Receiver Optics for Radio Astronomy》, ACES Journal, 卷 39, 期 11, 页 1012–1018, 11月 2024.

2024: Vol 39 Iss 11

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