Deep space debris—Detection of potentially hazardous asteroids and objects from the southern hemisphere

Frontiers in Space Technologies Pub Date : 2023-05-23 DOI:10.3389/frspt.2023.1162915

E. Kruzins, L. Benner, R. Boyce, Melrose Brown, D. Coward, Sam Darwell, P. Edwards, Lauren Elizabeth-Glina, J. Giorgini, S. Horiuchi, Andrew Lambert, J. Lazio, G. Calves, J. Moore, E. Peters, C. Phillips, J. Stevens, A. Verveer

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引用次数: 1

Abstract

Space debris are composed of both natural and human made objects, some in near Earth orbits while others are passing through deep space. Asteroids may represent one form of near Earth and deep space debris. In this article we report on a set of asteroid observations from the southern hemisphere. We indicate that Apollo and Aten class asteroids represent another form of deep space debris of a potentially hazardous nature to orbiting spacecraft and/or Earth based locations. We also show some of the operational challenges, types of facilities and the importance of geographic diversity, that is, necessary for detecting, observing and characterising asteroids, especially PHA’s. For many years, space agencies and institutions have observed and monitored near Earth asteroids and objects (NEO’s) using high gain radio frequency antennas and optical telescopes in the northern hemisphere (GSSR, Arecibo, Catalina, Pan-STARRS, Atlas and Linear) 1) However a regular operational system to monitor the southern skies does not have the same level of maturity and is where a percentage of asteroids and various human made objects are not detected until they pass into northern skies. To fill that gap the Southern Hemisphere Asteroid Radar Program (SHARP) 2) located in Australia uses available antenna time on either a 70 or 34 m beam waveguide antenna located at the Canberra Deep Space Communication Complex (CDSCC) to transmit a Doppler compensated continuous radio wave at 2.114 GHz (14.2 cm) and 7.15945 GHz (4.2 cm) toward the NEO and receive its echoes at the 64 m Parkes or 6 m × 22 m Australia Telescope Compact Array (ATCA) antennas at Narrabri in Australia. This mode of NEO observation is termed a deep space bistatic radar. The southern hemisphere program has also recently been joined by the 12 m University of Tasmania antennas at Hobart (Tasmania) and Katherine (Northern Territory). Combining SHARPS bistatic radar with small optical apertures located at the University of New South Wales (UNSW) and University of Western Australia (UWA) allows combined optical/RF NEO detections. Whilst sub-metre class optical instruments have contributed independently to asteroid detection over decades, the use of coordinated small 0.3–0.5 m instruments synchronized to large asteroid radars offers an observational flexibility and adaptability when larger optical systems 3) are dedicated to other forms of professional optical astronomy. Since 2015, SHARP has illuminated and tracked over 30 NEO’s ranging in diameter from 7 to 5000 m at ranges of 0.1–18 lunar distances (LD) from Australia.

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深空碎片——探测来自南半球的潜在危险小行星和物体

太空碎片由自然和人类制造的物体组成，一些在近地轨道上，而另一些正在穿越深空。小行星可能是近地和深空碎片的一种形式。在这篇文章中，我们报告了一组来自南半球的小行星观测结果。我们指出，阿波罗和阿顿类小行星代表了另一种形式的深空碎片，对轨道航天器和/或地球基地具有潜在的危险性质。我们还展示了一些操作挑战，设施类型和地理多样性的重要性，即探测，观测和表征小行星，特别是PHA的必要条件。多年来，空间机构和机构使用北半球的高增益射频天线和光学望远镜(GSSR, Arecibo, Catalina, Pan-STARRS, Atlas和Linear)观察和监测近地小行星和物体(NEO’s) 1)然而，监测南方天空的常规操作系统不具有相同的成熟水平，并且在那里，一定比例的小行星和各种人造物体直到它们进入北方天空才被探测到。填补这一差距南半球小行星雷达程序(大幅)2)位于澳大利亚使用天线可用时间在70或34米波束波导天线位于堪培拉深空通信复杂(CDSCC)传输多普勒补偿连续在2.114 GHz无线电波(14.2厘米)和7.15945 GHz向NEO(4.2厘米)和接收其回声Parkes或6 m×22 64澳大利亚新南威尔斯Narrabri镇紧凑的数组(ATCA)天线望远镜在澳大利亚。这种近地天体观测模式被称为深空双基地雷达。最近，塔斯马尼亚大学在霍巴特(塔斯马尼亚州)和凯瑟琳(北领地)的12米天线也加入了南半球项目。将位于新南威尔士大学(UNSW)和西澳大利亚大学(UWA)的SHARPS双基地雷达与小光学孔径相结合，可以组合光学/RF NEO探测。几十年来，亚米级光学仪器一直在独立地为小行星探测做出贡献，当大型光学系统用于其他形式的专业光学天文学时，使用协调的0.3-0.5米小型仪器与大型小行星雷达同步，提供了观测的灵活性和适应性。自2015年以来，夏普已经在距离澳大利亚0.1-18个月球距离(LD)的范围内照亮并跟踪了30多个直径从7到5000米不等的近地天体。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Frontiers in Space Technologies

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