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Airborne Bistatic Radar Trajectory Optimization for Ground Geolocation Accuracy Maximization

机译：空气摇滚雷达轨迹轨迹轨道轨迹优化最大化

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Target detection geolocation accuracy for monostatic radars is a function of the distance to the target and sensor parameters. For bistatic radars, detection estimation errors are dependent on not only the total distance to the target but also on the platform geometry. In this paper, we present a general approach to optimize platform trajectories in order to maximize detection geolocation accuracy. By utilizing the bistatic Cramer-Rao bound, a lower bound on the estimation errors is determined. Control-limited differential dynamic programming is then used to minimize the estimation errors along a trajectory with a defined time horizon. The optimization implications of different transmitter and receiver cooperation modes are discussed.

机译：用于单体雷达的目标检测地理位置精度是与目标和传感器参数的距离的函数。对于双晶雷达，检测估计误差不仅取决于目标的总距离，还取决于目标几何形状。在本文中，我们提出了一种优化平台轨迹的一般方法，以便最大化检测地理位置精度。通过利用Bistatic Cramer-Rao绑定，确定估计误差的下限。然后，控制有限的差分动态编程将沿着具有定义时间范围的轨迹最小化估计误差。讨论了不同发射机和接收器协作模式的优化意义。

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《Radar Conference》|2017年|1185-1815 p. :|共6页
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作者
Marsal A. Bruna; Kristin F. Bing; Mark Minges;
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中图分类 TN95-532;
关键词
trajectory optimization; bistatic radar; airborne radar; Cramer-Rao lower bound; differential dynamic programming;

机译：轨迹优化;双射雷达;机载雷达;Cramer-Rao下限;差动动态规划;

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1. Exploiting Doppler Blind Zone Information for Ground Moving Target Tracking with Bistatic Airborne Radar [J] . Mertens Michael, Koch Wolfgang, Kirubarajan Thia IEEE Transactions on Aerospace and Electronic Systems . 2014,第1期

机译：利用多普勒盲区信息进行双基地机载雷达的地面运动目标跟踪
2. Ground and airborne target detection with bistatic adaptivespace-based radar [J] . Fante R. IEEE Aerospace and Electronic Systems Magazine . 1999,第10期

机译：双基地自适应天基雷达的地面和空中目标检测
3. Ground and airborne target detection with bistatic adaptive space-based radar [J] . Fante R. IEEE Aerospace and Electronic Systems Magazine . 1999,第10期

机译：双基地自适应天基雷达的地面和空中目标检测
4. Airborne Bistatic Radar Trajectory Optimization for Ground Geolocation Accuracy Maximization [C] . Marsal A. Bruna, Kristin F. Bing, Mark Minges IEEE Radar Conference . 2017

机译：空气摇滚雷达轨迹轨迹轨道轨迹优化最大化
5. An application of space-time adaptive processing to airborne and spaceborne monostatic and bistatic radar systems. [D] . Czernik, Richard James. 2010

机译：时空自适应处理在机载和机载单基地和双基地雷达系统中的应用。
6. Statistical Analysis of Bistatic Radar Ground Clutter for Different German Rural Environments [O] . Michael Kohler, Daniel W. O’Hagan, Matthias Weiss, 2020

机译：德国不同农村环境的双基地雷达地杂波统计分析
7. Mitigation of Ground Clutter in Airborne Bistatic Radar Systems [O] . Jacob Klintberg, Tomas McKelvey, Patrik Dammert 2020

机译：空气传播雷达系统地面杂波的减轻
8. Lunar orbit rendezvous reference trajectory data package. analysis of apollo orbit determination accuracy with random errors in ground based radar and onboard optical observations. volume 4 - the lunar parking orbit [R] . 1968

机译：月球轨道交会参考轨迹数据包。基于地面雷达和船载光学观测的随机误差分析阿波罗轨道确定精度。第4卷 - 月球停车轨道

Airborne Bistatic Radar Trajectory Optimization for Ground Geolocation Accuracy Maximization

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