There is a need to provide high-resolution video imagery to the sensor operators of current and future gunships while supporting missions above an area of interest. Sensor operators need to see beyond the visual range of the main platform, peer through weather, and monitor multiple geo-separated or dispersing targets. The Lite Machines Tiger Moth UA V is designed to fill this need. The objective of the work presented herein was to improve the inner loop control laws of the Tiger Moth UA V through control system modeling, optimization and flight tests. Laboratory tests were conducted to identify aircraft sensor and servo dynamics. A bare-airframe hover/low-speed dynamics model was developed from piloted frequency sweeps. The identified components and dynamics model were combined with a Simulink~? representation of the control laws to form a validated analysis model which was used in CONDUIT~? to optimize the attitude loop feedback gains. Flight tests with the optimized gains showed improved performance. Finally, the improvements were demonstrated to the U. S. Air Force in untethered flight tests conducted at Camp Atterbury, Indiana, in December of 2011.
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机译:有必要为当前和未来的教练的传感器运营商提供高分辨率的视频图像,同时支持在感兴趣区域之上的任务。传感器运营商需要超越主平台的视觉范围,同行通过天气,并监控多个地理分离或分散目标。 Lite Machines Tiger Moth UA V旨在填补这种需求。本文提供的工作的目的是通过控制系统建模,优化和飞行测试来改善Tiger Moth UA V的内环控制规律。进行实验室测试以识别飞机传感器和伺服动力学。裸机悬停/低速动力学模型是从导向的频率扫描开发的。所识别的组件和动力学模型与Simulink组合〜?控制法律表达,以形成导管中使用的验证分析模型〜?优化姿态循环反馈收益。使用优化的收益进行飞行测试表现出改善的性能。最后,在2011年12月,在印第安纳州阿特尔特伯里营地进行的未计入飞行试验中,对美国的飞行试验进行了改进。
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