Three-dimensional analysis of Deep Space Network antenna coverage

O. Kegege, M. Fuentes, N. Meyer, A. Sil
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引用次数: 5

Abstract

There is a need to understand NASA's Deep Space Network (DSN) coverage gaps and any limitations to provide redundant communication coverage for future deep space missions, especially for manned missions to Moon and Mars. The DSN antennas are required to provide continuous communication coverage for deep space flights, interplanetary missions, and deep space scientific observations. The DSN consists of ground antennas located at three sites: Goldstone in USA, Canberra in Australia, and Madrid in Spain. These locations are not separated by the exactly 120 degrees and some DSN antennas are located in the bowl-shaped mountainous terrain to shield against radiofrequency interference resulting in a coverage gap in the southern hemisphere for the current DSN architecture. To analyze the extent of this gap and other coverage limitations, simulations of the DSN architecture were performed. In addition to the physical properties of the DSN assets, the simulation incorporated communication forward link calculations and azimuth/elevation masks that constrain the effects of terrain for each DSN antenna. Analysis of the simulation data was performed to create coverage profiles with the receiver settings at a deep space altitudes ranging from 2 million to 10 million km and a spherical grid resolution of 0.25 degrees with respect to longitude and latitude. With the results of these simulations, two- and three-dimensional representations of the area without communication coverage and area with coverage were developed, showing the size and shape of the communication coverage gap projected in space. Also, the significance of this communication coverage gap is analyzed from the simulation data.
深空网络天线覆盖的三维分析
有必要了解NASA的深空网络(DSN)覆盖差距和任何限制,为未来的深空任务,特别是载人登月和火星任务提供冗余通信覆盖。深空网络天线需要为深空飞行、行星际任务和深空科学观测提供连续的通信覆盖。深空网络由三个地点的地面天线组成:美国的戈德斯通、澳大利亚的堪培拉和西班牙的马德里。这些位置并没有被精确的120度分隔,一些深空网络天线位于碗形的山区地形中,以屏蔽射频干扰,从而导致当前深空网络架构在南半球的覆盖差距。为了分析这种差距的程度和其他覆盖限制,对DSN架构进行了模拟。除了DSN资产的物理属性外,模拟还包含通信前向链路计算和方位角/仰角掩模,这些掩模约束了每个DSN天线的地形影响。对模拟数据进行分析,以创建深空高度为200万至1000万公里、球面网格分辨率为经纬度0.25度的接收机覆盖剖面。根据模拟结果,建立了无通信覆盖区域和有通信覆盖区域的二维和三维表示,显示了在空间上投影的通信覆盖差距的大小和形状。并从仿真数据分析了这种通信覆盖差距的意义。
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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