Extended-State-Observer-Based Angular Acceleration Estimation for Supersonic Aircraft Lateral–Directional Control

Lyu, Huitao; Zheng, Yi; Chen, Yongliang; Zhao, Ting; Gong, Zheng; Liu, Xueqiang; Qin, Bo; Chen, Kun

doi:10.3390/app13116598

Cited by 1 publication

(4 citation statements)

References 42 publications

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“…Lyu et al [30] proposed a new framework for supersonic roll maneuver control that combines INDI and extended state observer (ESO). ESO reduces command oscillations and improves the servo's working life.…”

Section: Implicit Ndi Indimentioning

confidence: 99%

“…The pitch angle rate loop is responsible for controlling the pitch angular rates, as the main control objectives. It is controlled using INDI+ESO [30]. The overall control structure is shown in Figure 7.…”

Section: Pitch Angle Rate Controlmentioning

confidence: 99%

“…The gain in the control law can be determined by adjusting parameters, which requires sufficient experimentation and iteration. We chose to fine tune based on previous relevant research [30] and determined that the gains r K , e K , and h K are 7, 70, and 0.11, . θ can be regarded as the desired change rate of the pitch angle.…”

Section: Pitch Angle Rate Controlmentioning

confidence: 99%

“…The gain in the control law can be determined by adjusting parameters, which requires sufficient experimentation and iteration. We chose to fine tune based on previous relevant research [30] and determined that the gains For the control assignment section, how the pitch rate command The control structure consists of four key components: reference model, error controller, ESO, and control allocation.…”

Section: Pitch Angle Rate Controlmentioning

confidence: 99%

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Control Design for Soft Transition for Landing Preparation of Light Compound-Wing Unmanned Aerial Vehicles Based on Incremental Nonlinear Dynamic Inversion

Ye,

Chen,

Cai

et al. 2023

Applied Sciences

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This paper proposes a soft switching mode for electric vertical takeoff and landing (eVTOL) compound-wing unmanned aerial vehicles (UAVs) to achieve a smooth transition between modes. The proposed mode pre-compensates the lift loss with the rotary wing during the deceleration stage before UAV landing. The control law adopted in this paper consists of implicit nonlinear dynamic inversion (NDI) and incremental nonlinear dynamic inversion (INDI). The outer loop (attitude angle loop) control law is based on implicit NDI, while the inner loop (attitude angle rate loop) controller is based on INDI. An extended state observer (ESO) is employed to estimate the angular acceleration. This paper innovates by proposing a soft switching strategy that improves the robustness, safety, and smoothness of the transition for the compound-wing UAV, and applying advanced control law to mode transition design. For the future application of eVTOL aircraft in UAM scenarios, this paper evaluates the smoothness of transition and passenger comfort using normal overload as a physical quantity. The Monte Carlo (MC) simulation results demonstrate that the proposed mode can reduce the peak normal overload by about 89%.

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Section: Implicit Ndi Indimentioning

confidence: 99%

Section: Pitch Angle Rate Controlmentioning

confidence: 99%

Section: Pitch Angle Rate Controlmentioning

confidence: 99%

“…The gain in the control law can be determined by adjusting parameters, which requires sufficient experimentation and iteration. We chose to fine tune based on previous relevant research [30] and determined that the gains For the control assignment section, how the pitch rate command The control structure consists of four key components: reference model, error controller, ESO, and control allocation.…”

Section: Pitch Angle Rate Controlmentioning

confidence: 99%

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