A Simulation Framework for Aircraft Take-Off Considering Ground Effect Aerodynamics in Conceptual Design

Salem, Karim Abu; Palaia, Giuseppe; Chiarelli, Mario Rosario; Bianchi, Mario

doi:10.3390/aerospace10050459

Cited by 7 publications

(3 citation statements)

References 69 publications

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“…The miniaturization and reduction in cost of the relevant control components in aircraft, as well as the development and progress of computer and sensing and measurement technologies, have improved the stability of flight control systems and greatly facilitated the development of quadrotors [1]. The high operability, strong mobility and flexibility of quadrotors allow them to meet the specific needs of many projects, generally used in military, industrial and other fields [2,3]. A quadrotor system is multivariable, nonlinear and strongly coupled, and quadrotors will also be disturbed by the surrounding environment during flight [4].…”

Section: Introductionmentioning

confidence: 99%

Robust Approximate Optimal Trajectory Tracking Control for Quadrotors

Li,

Yang,

Yan

et al. 2024

Aerospace

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This paper uses the adaptive dynamic programming (ADP) method to achieve optimal trajectory tracking control for quadrotors. Relying on an established mathematical model of a quadrotor, the approximate optimal trajectory tracking control, which consists of the steady-state control input and the approximate optimal feedback control input, is designed for a nominal system. Considering the compound disturbances in position and attitude dynamic models, disturbance observers are introduced. The estimated values are used to design robust compensation inputs to suppress the effect of the compound disturbances for good trajectory tracking performance. Theoretically, the Lyapunov theorem demonstrates the stability of a closed-loop system. The robustness and effectiveness of the proposed controller are confirmed by the simulation results.

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Section: Introductionmentioning

confidence: 99%

Robust Approximate Optimal Trajectory Tracking Control for Quadrotors

Li,

Yang,

Yan

et al. 2024

Aerospace

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“…These encompass the increased use of computers at every stage of product design, various modeling, computation, optimization, and artificial intelligence (AI) techniques, as well as significant breakthroughs in materials science, including high-precision and additive manufacturing methods, options for electrification of flow machines together with the use of unconventional fuels. Svorcan et al [52], Abu Salem et al [53], and Peciak et al [54] explored various methods for flow control (passive and active control, both in low-and high-speed flows) to improve efficiency, aerodynamic quality, boundary layer stabilization, and aircraft control.…”

Section: Introductionmentioning

confidence: 99%

Solving Innovative Problems of Thrust Vector Control Based on Euler's Scientific Legacy

Sazonov,

Mokhov,

Gryaznova

et al. 2023

Civ Eng J

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This study aims to develop an interdisciplinary approach to solving innovative thrust vector control problems. The methodology involves the development of a working hypothesis about the ejection process when using a controlled nozzle to deflect the thrust vector (velocity vector) in any direction within a complete geometric sphere. When developing the working hypothesis, a multilateral analysis of individual facts and scientific and technical information is performed using tools in the "big data" area, assessing opportunities to apply the "Foresight" methodology for predicting the development of fluidics. The authors propose new mathematical models to describe the thrust vector in the distribution of the mass flow rate of the fluid medium between flow channels. Patents for inventions support the novelty of scientific results that reveal new opportunities for more active development of fluidics as applied to simple and complex jet systems with low and extremely high energy density in flows. The proposed methodology rests on a modern computer base and is a logical continuation and development of well-known Euler’s works. The computer simulation of multiflow jet devices mainly focuses on power engineering, production, and processing of hydrocarbons. Some results of this research work, including patented design developments and calculation methods, also apply to developing robotics, unmanned vehicles, and programable jet systems. The authors attribute further development of the interdisciplinary approach for solving inventive problems to the use of different AI options. Doi: 10.28991/CEJ-2023-09-11-017 Full Text: PDF

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“…Smith et al [23] applied panel methods for optimising wing planforms by minimizing the induced drag and then extended the approach to incorporate non-planar variations in the design space and coupled it with XFOIL for viscous drag computation [14]. Recently, Salem et al [24] employed a VLM method to include ground effect aerodynamics in the assessment of take-off considerations within the conceptual design of box-wing aircraft. When coupled with the method of images, aerodynamic characteristics in ground effect can be rapidly computed using the low-fidelity simulation tools.…”

Section: Introductionmentioning

confidence: 99%

Investigating Planar and Nonplanar Wing Planform Optimisation for Ground Effect Aircraft

Jesudasan,

Hanifi,

Mariani

2023

Aerospace

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Wing-in-Ground (WIG) effect aircraft are gaining attention for their potential in reducing environmental impact. However, optimising wing planforms based solely on aerodynamics might improve performance while compromising static height stability of WIG aircraft. This study investigates the effects of planar and nonplanar wing planform optimisation for regional transport ground effect aircraft. Three distinct multiobjective wing planform optimisations are explored: planar wing optimisation, nonplanar wing optimisation, and nonplanar wingtip optimisation. These optimisations assess the impact on both aerodynamic efficiency and static height stability characteristics of a wing planform in ground effect, at three different flying altitudes. In extreme ground effect, the Pareto set includes wings with negative spanwise camber, enhancing both cushion sensation and aerodynamic efficiency by effectively utilizing ground effect, thus proving advantageous over planar wing configurations.

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A Simulation Framework for Aircraft Take-Off Considering Ground Effect Aerodynamics in Conceptual Design

Cited by 7 publications

References 69 publications

Robust Approximate Optimal Trajectory Tracking Control for Quadrotors

Robust Approximate Optimal Trajectory Tracking Control for Quadrotors

Solving Innovative Problems of Thrust Vector Control Based on Euler's Scientific Legacy

Investigating Planar and Nonplanar Wing Planform Optimisation for Ground Effect Aircraft

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