Simulation study of wake encounters with straight and deformed vortices

Vechtel, Dennis

doi:10.1017/aer.2016.14

Cited by 13 publications

(12 citation statements)

References 17 publications

(32 reference statements)

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“…In fact, these results confirmed the outcomes of investigation obtained by the authors when using other types of soft-computing approaches also focused on almost the same type of critical inputs. On the other hand, researchers worldwide [22], [23] focusing on the study of vortex encounters by simulating their dynamics in order to define vortex encounter hazards, are urgently seeking answers to redefine safety measures, such as separation schemes. The expectation is to allow air traffic to increase airport capacities by revising the existing schemes while not compromising safety.…”

Section: Discussionmentioning

confidence: 99%

Airplane Vortex Encounters Identification Using Multilayer Feed-Forward Neural Networks

Bouslama¹,

Al-Mahadin²

2019

IJMLC

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The encounter of vortices generated by a leading aircraft during takeoff or landing can be a source of hazard to a following aircraft. In spite of airport efforts to keep safe separation distances between aircrafts, a number of them encounter severe vortices each year. It has been challenging to accurately identify those encounters by manual approaches. To mitigate the impact of vortex encounters on an aircraft, it is important that more reliable identification techniques be developed. This research is a contribution towards the automatic identification of vortex encounters using artificial neural networks. Multilayer feedforward neural networks are trained using the back-propagation learning algorithm to classify flight events into either vortex encounters or other events. Using salient inputs such as aircraft roll angle, normal acceleration and lateral acceleration, the neural networks are able to achieve an overall average identification rate of about 88%. These results confirm the authors' earlier assumption on using a reduced set of critical inputs to properly classify aircraft vortex encounters.

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Section: Discussionmentioning

confidence: 99%

Airplane Vortex Encounters Identification Using Multilayer Feed-Forward Neural Networks

Bouslama¹,

Al-Mahadin²

2019

IJMLC

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“…This method was deemed feasible by Barrows [23], verified against wind tunnel tests by de Bruin [24], and further validated using real flight test data by Fischenberg [25] and Jategaonkar [26]. The method was applied in various studies in the past [27][28][29][30][31][32] and is accepted to provide vortex induced forces and moments of acceptable accuracy.…”

Section: B Implementation Of Vortex Flow Fields In the Aircraft Simumentioning

confidence: 98%

How Plate Lines Influence the Hazard Perception of Pilots During Wake Encounters

Vechtel

Stephan

Holzäpfel

2020

Journal of Aircraft

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Wake vortex encounter reports as well as simulations show a significantly higher encounter risk in ground proximity. This is caused by the special behavior of wake vortices in ground effect. Nevertheless, hazardous wake encounters with adverse consequences are rarely reported in reality. In order to gain more insight in the mechanisms of wake encounters close to ground a realistic flow field around an aircraft of the HEAVY category is initialized using a high fidelity Reynolds-averaged Navier-Stokes solution. The further development of the vortical wake during final approach until touchdown is investigated by large-eddy-simulation until final decay. The resulting flow fields are used for a hazard analysis of wake encounters close to the ground. Encounter simulations are performed with a simulation model of the DLR research aircraft A320 ATRA with autopilot engaged. Different wind conditions and vortex ages are considered as well as the effect of a so-called plate line. Recent studies showed increased vortex decay in case that a series of plates is positioned in front of the runway threshold. Whether such a plate line also lowers the encounter risk or its severity is analyzed in this study. Nomenclature  C = rolling moment coefficient [-] RCR = roll control ratio [-] t = time [s] V/S = vertical speed [ft/min] x,y,z = Cartesian co-ordinates [m] Φ = bank angle [deg] Θ = pitch angle [deg]

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“…Simulations have been used to examine the influence of vortex curvature on encounter severity ( [80], [81], [82], [83], [84]). As noted by Crow [11], wakes deform as a result of the long-wave Crow instability, which in turn is driven by the ambient turbulence and in later stages by the temperature stratification [83].…”

Section: Vortex Encountersmentioning

confidence: 99%

A review of recent wake vortex research for increasing airport capacity

Hallock

Holzäpfel

2018

Progress in Aerospace Sciences

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This paper is a brief review of recent wake vortex research as it affects the operational problem of spacing aircraft to increase airport capacity and throughput. The paper addresses the questions of what do we know about wake vortices and what don't we know about wake vortices. The introduction of Heavy jets in the late 1960s stimulated the study of wake vortices for safety reasons and the use of pulsed lidars and the maturity of computational fluid dynamics in the last three decades have led to extensive data collection and analyses which are now resulting in the development and implementation of systems to safely decrease separations in the terminal environment. Although much has been learned about wake vortices and their behavior, there is still more to be learned about the phenomena of aircraft wake vortices.

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Simulation study of wake encounters with straight and deformed vortices

Cited by 13 publications

References 17 publications

Airplane Vortex Encounters Identification Using Multilayer Feed-Forward Neural Networks

Airplane Vortex Encounters Identification Using Multilayer Feed-Forward Neural Networks

How Plate Lines Influence the Hazard Perception of Pilots During Wake Encounters

A review of recent wake vortex research for increasing airport capacity

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