Airborne ground moving target indication using non-side-looking antennas

Proceedings of the 1998 IEEE Radar Conference, RADARCON'98. Challenges in Radar Systems and Solutions (Cat. No.98CH36197) Pub Date : 1998-05-11 DOI:10.1109/NRC.1998.678013

T. Nohara, P. Weber, A. Premji, T. Bhattacharya

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引用次数: 15

Abstract

It is well known that detection of moving targets using an airborne radar is complicated by platform-induced spectral spreading of clutter returns. As a result, conventional pulse Doppler radars require a target to have a minimum detectable velocity (MDV) to be clear of mainbeam (and sidelobe) clutter. Extensive research into side-looking, multi-channel (i.e. multi-aperture) radars employing space-time adaptive processing (STAP) and displaced phase centre antenna (DPCA) processing techniques has been conducted, in order to reduce the requirement on MDV for airborne early warning (AEW) radar applications. GMTI (ground moving target indication) radars like JSTARS also employ similar techniques to detect slow ground moving targets such as tanks and jeeps. Most of the literature deals with side-looking airborne radars (SLAR), which is the case when the aperture phase centres lie along a line parallel to the flight path. This paper considers the design and performance of GMTI radars for the general, non-SLAR case, where the array is oriented away from the side, the extreme case being a forward-looking airborne radar (FLAR). A non-SLAR GMTI radar is attractive because it is applicable to mechanically rotated antenna arrays, often used for wide-angle surveillance; and, as a result, can be considered as an upgrade to existing surveillance radars.

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使用非侧视天线的机载地面移动目标指示

众所周知，利用机载雷达探测运动目标是复杂的平台诱导的频谱扩展的杂波回波。因此，传统的脉冲多普勒雷达要求目标具有最小可探测速度(MDV)，以清除主波束(和旁瓣)杂波。为了减少机载预警(AEW)雷达应用对MDV的要求，对采用时空自适应处理(STAP)和位移相位中心天线(DPCA)处理技术的侧视多通道(即多孔径)雷达进行了广泛的研究。GMTI(地面移动目标指示)雷达像JSTARS也采用类似的技术来探测缓慢的地面移动目标，如坦克和吉普车。大多数文献涉及侧视机载雷达(SLAR)，这是孔径相位中心沿平行于飞行路径的一条线的情况。本文考虑了GMTI雷达在一般非slar情况下的设计和性能，其中阵列是远离侧面的，极端情况是前视机载雷达(FLAR)。非slar GMTI雷达很有吸引力，因为它适用于机械旋转的天线阵列，通常用于广角监视;因此，它可以被认为是对现有监视雷达的升级。

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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来源期刊

Proceedings of the 1998 IEEE Radar Conference, RADARCON'98. Challenges in Radar Systems and Solutions (Cat. No.98CH36197)

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