推进
飞行操纵面
非线性系统
控制理论(社会学)
偏转(物理)
工程类
翼
控制工程
Lift(数据挖掘)
航空航天工程
计算机科学
控制(管理)
空气动力学
光学
物理
数据挖掘
人工智能
量子力学
作者
Xichen Shi,Kyunam Kim,Salar Rahili,Soon‐Jo Chung
标识
DOI:10.1109/cdc.2018.8619578
摘要
Hybrid vertical take-off and landing vehicles (VTOL) with lift production from wings and distributed propulsive system present unique control challenges. Existing methods tend to stitch and switch different controllers specially designed for fixed-wing aircraft or multicopters. In this paper, we present a unified framework for designing controllers for such winged VTOL vehicles that are commonly found in recent flying car models. The proposed method is broken down into nonlinear control of both position and attitude with forces and moments as inputs, and real-time control allocation that integrates distributed propulsive actuation with conventional control surface deflection. We also present a strategy that avoids saturation of distributed propulsion control inputs. The effectiveness of the proposed framework is demonstrated through simulation and closed-loop flight experiment with our winged VTOL flying car prototype.
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