自由空间光学 (FSO) 卫星网络性能分析:传输功率、延迟和中断概率

IF 5.3 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Jintao Liang;Aizaz U. Chaudhry;Eylem Erdogan;Halim Yanikomeroglu;Gunes Karabulut Kurt;Peng Hu;Khaled Ahmed;Stephane Martel
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引用次数: 0

摘要

在自由空间光学卫星网络(FSOSN)中,卫星可以有不同的激光卫星间链路(LISL)连接范围。随着 LISL 范围的增大,在源站和目的地地面站之间的最短路径上所需的卫星数量会减少,因此最短路径上的 LISL 数量也会减少。更大的 LISL 范围可减少路径的网络延迟,但也会导致路径上卫星的传输功率增加。因此,应该研究卫星传输功率和网络延迟之间的这种权衡,在这项工作中,我们利用星链 1 阶段第 3 版(即星链 1 阶段的最新版本)和柯伊伯外壳 2(即柯伊伯最大的外壳)星座,针对不同的 LISL 范围和不同的洲际连接,在 FSOSN 中研究了这一问题。我们使用适当的系统模型计算平均卫星传输功率(即最短路径上所有卫星传输功率的平均值)和网络延迟(即最短路径的端到端延迟)。结果显示,随着 LISL 范围的增加,平均网络延迟(即所有时隙的网络延迟平均值)减小,平均卫星传输功率(即所有时隙的平均卫星传输功率平均值)增大。对于使用 Starlink 第一阶段第三版星座的 FSOSN 中的多伦多-悉尼洲际连接,当 LISL 范围约为 2,900 公里时,平均网络延迟和平均卫星传输功率的交点分别约为 135 毫秒和 380 毫瓦。对于该洲际连接中使用柯伊伯壳 2 星座的 FSOSN,该 LISL 范围约为 3,800 千米,两个参数分别约为 120 毫秒和 700 毫瓦。对于多伦多-伊斯坦布尔和多伦多-伦敦洲际连接,交叉点的 LISL 范围有所不同,从 2,600 公里到 3,400 公里不等。此外,我们还分析了大气衰减和湍流导致的光上行/下行链路中断概率性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Free-Space Optical (FSO) Satellite Networks Performance Analysis: Transmission Power, Latency, and Outage Probability
In free-space optical satellite networks (FSOSNs), satellites can have different laser inter-satellite link (LISL) ranges for connectivity. As the LISL range increases, the number of satellites from among all the satellites in the constellation that will be needed on the shortest path between a source and a destination ground station decrease, and thereby the number of the LISLs on the shortest path decreases. Greater LISL ranges can reduce network latency of the path but can also result in an increase in transmission power for satellites on the path. Consequently, this tradeoff between satellite transmission power and network latency should be investigated, and in this work we examine it in FSOSNs drawing on the Starlink Phase 1 Version 3 (i.e., the latest version of Starlink's Phase 1) and Kuiper Shell 2 (i.e., Kuiper's biggest shell) constellations for different LISL ranges and different inter-continental connections. We use appropriate system models for calculating the average satellite transmission power (i.e., the average of the transmission power of all satellites on the shortest path) and network latency (i.e., the end-to-end latency of the shortest path). The results show that the mean network latency (i.e., the mean of network latency over all time slots) decreases and mean average satellite transmission power (i.e., the mean of average satellite transmission power over all time slots) increases with an increase in LISL range. For the Toronto–Sydney inter-continental connection in an FSOSN with Starlink's Phase 1 Version 3 constellation, when the LISL range is approximately 2,900 km, the mean network latency and mean average satellite transmission power intersect are approximately 135 ms and 380 mW, respectively. For an FSOSN with the Kuiper Shell 2 constellation in this inter-continental connection, this LISL range is around 3,800 km, and the two parameters are approximately 120 ms and 700 mW, respectively. For the Toronto–Istanbul and Toronto–London inter-continental connections, the LISL ranges at the intersection are different and vary from 2,600 km to 3,400 km. Furthermore, we analyze outage probability performance of optical uplink/downlink due to atmosphere attenuation and turbulence.
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来源期刊
CiteScore
9.60
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