Singular Perturbation Margin of INDI-Based Flight Control Systems With Delays

IF 5.7 2区计算机科学 Q1 ENGINEERING, AEROSPACE IEEE Transactions on Aerospace and Electronic Systems Pub Date : 2025-03-13 DOI:10.1109/TAES.2025.3551210

Tito Jehu Ludena Cervantes;Yoonsoo Kim;Byoung Soo Kim

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Abstract

A linear singularly perturbed system (SPS) based on a linear approximation of incremental nonlinear dynamic inversion (INDI) is formulated for a general INDI-based flight control system. This system includes first-order actuator dynamics where its time constant is taken as the singular perturbation parameter. The stability of the SPS is studied, which gives an understanding of the sensitivity of INDI to delays. Two sources of delay are considered, one coming from the state derivative measurement and the other coming from the delayed input signal. It is shown in this article that the upper bound of the singular perturbation parameter serves as a robustness metric of the SPS to the two types of delays. Consequently, a relative singular perturbation margin (

$\text{SPM}_{\text{R}}$

) is proposed as a delay margin. The results are confirmed with two aircraft simulation cases for multiple-input multiple-output and single-input single-output systems. In the latter, the relationship between the

$\text{SPM}_{\text{R}}$

and the phase margin is analyzed.

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具有时滞的基于indii的飞行控制系统奇异摄动裕度

针对一种基于增量非线性动态反演（INDI）的通用飞行控制系统，建立了基于线性逼近增量非线性动态反演（INDI）的线性奇异摄动系统。该系统包含一阶作动器动力学，其时间常数作为奇异摄动参数。研究了系统的稳定性，了解了系统对时滞的敏感性。考虑了两种延迟来源，一种来自状态导数测量，另一种来自延迟输入信号。本文证明了奇异扰动参数的上界可以作为两类时滞的鲁棒性度量。因此，我们提出了一个相对奇异扰动余量（$\text{SPM}_{\text{R}}$）作为延迟余量。通过多输入多输出和单输入单输出两种系统的飞机仿真实例验证了结果。分析了$\text{SPM}_{\text{R}}$与相位裕度的关系。

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

IEEE Transactions on Aerospace and Electronic Systems 工程技术-电信学

CiteScore

7.80

自引率

13.60%

发文量

433

审稿时长

8.7 months

期刊介绍： IEEE Transactions on Aerospace and Electronic Systems focuses on the organization, design, development, integration, and operation of complex systems for space, air, ocean, or ground environment. These systems include, but are not limited to, navigation, avionics, spacecraft, aerospace power, radar, sonar, telemetry, defense, transportation, automated testing, and command and control.