Adaptive waveform design for multi-sector array isolation

J. Kurdzo, R. Palmer, B. Cheong, M. Weber
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引用次数: 2

Abstract

Multi-sector arrays have been used for decades, including applications on ships, aircraft, vehicles, and ground-based platforms. In most of these applications, however, spatial isolation generated through the use of strategic sector placement has provided sufficient overall isolation between each sector. The United States has recently been exploring the potential for a multi-function phased array radar (MPAR) network that would provide surveillance, tracking, and detection capabilities for the nation's weather, terminal weather, and national airspace missions. Several studies have assumed a multi-sector approach on a single platform. With the goal of allowing each sector to independently operate, concerns regarding isolation between the sectors have introduced the desire to gain additional isolation through waveform design. Recent advances in frequency-modulated pulse compression techniques have afforded the ability to maximize sensitivity and sidelobe performance within a given time-bandwidth specification; however, waveform design has the potential to bring numerous other spectral efficiency advancements to the MPAR mission. A generalization of recent waveform design techniques into a multi-sector waveform group is presented. Simulations of a four-sector waveform group are carried out and optimized for minimal interference. The ability to achieve high waveform-based isolation is combined with varying spatial isolations and slight frequency offsets to drastically reduce overall spectrum usage for a multi-sector array.
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多扇区阵列隔离的自适应波形设计
多扇区阵列已经使用了几十年,包括在船舶、飞机、车辆和地面平台上的应用。然而,在大多数这些应用中,通过使用战略性扇区布局产生的空间隔离已经在每个扇区之间提供了充分的总体隔离。美国最近一直在探索多功能相控阵雷达(MPAR)网络的潜力,该网络将为国家天气、终端天气和国家空域任务提供监视、跟踪和探测能力。一些研究假设在单一平台上采用多部门方法。为了使每个扇区能够独立运行,考虑到扇区之间的隔离,人们希望通过波形设计获得额外的隔离。调频脉冲压缩技术的最新进展提供了在给定的时间带宽规格内最大化灵敏度和旁瓣性能的能力;然而,波形设计有可能为MPAR任务带来许多其他频谱效率的进步。将最新的波形设计技术推广到多扇区波形组。对四扇形波形组进行了仿真,并进行了最小干扰优化。实现高波形隔离的能力与不同的空间隔离和轻微的频率偏移相结合,大大减少了多扇区阵列的总体频谱使用。
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