Lobe Balancing Design Method to Create Frozen Sonic Booms Using Aircraft Components

Jung, Timothy P.; Starkey, Ryan P.; Argrow, Brian

doi:10.2514/1.c031709

Cited by 8 publications

(3 citation statements)

References 35 publications

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“…For this reason, the sonic boom generated by objects flying at hypersonic velocity at high altitude was the subject of specific studies [40][41][42][43][44][45][46][47][48][49]. The recent orientations concern the minimization of the sonic boom perceived at ground level by suitable aircraft geometry and flight trajectory on the one hand [50][51][52][53][54], the generalization of the computational fluid dynamics (CFD) to replace the analytical models on the other hand [55][56][57][58][59][60]. For a long time limited to the calculation of the aerodynamic field close to the supersonic object, the CFD now tends to increase its spatial range, thanks to the use of adaptive meshes, for instance.…”

Section: Introductionmentioning

confidence: 99%

Ballistic Wave from Projectiles and Vehicles of Simple Geometry

2018

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Section: Introductionmentioning

confidence: 99%

Ballistic Wave from Projectiles and Vehicles of Simple Geometry

2018

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“…These sonic boom types are essentially modified N-waves. Another option to reduce the annoyance of the sonic boom to humans is to generate a multishock signature (Figure 7d) by means of a lobe-balancing method [116,117]. Lobes are created using lift, by trimming lifting surfaces to obtain a frozen, shock balanced F-function, like the one showed in Figure 8, at different flight conditions.…”

Section: Minimization Theory and Techniquesmentioning

confidence: 99%

Review of Sonic Boom Prediction and Reduction Methods for Next Generation of Supersonic Aircraft

Bonavolontà,

Lawson,

Riaz

2023

Aerospace

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The reduction of sonic boom levels is the main challenge but also the key factor to start a new era of supersonic commercial flights. Since 1970, a FAA regulation has banned supersonic flights overland for unacceptable sonic booms at the ground, and many research studies have been carried out from that date to understand sonic boom generation, propagation and effects, both on the environment and communities. Minimization techniques have also been developed with the attempt to reduce sonic boom annoyance to acceptable levels. In the last 20 years, the advances in both knowledge and technologies, and companies and institutions’ significant investments have again raised the interest in the development of new methods and tools for the design of low boom supersonic aircraft. The exploration of unconventional configurations and exotic solutions and systems seems to be needed to effectively reduce sonic boom and allow supersonic flight everywhere. This review provides a description of all aspects of the sonic boom phenomenon related to the design of the next generation of supersonic aircraft. In particular, a critical review of the prediction and minimization methods found in the literature, aimed at identifying their strengths, limitations and gaps, is made, along with a complete overview of disruptive unconventional aircraft configurations and exotic active/passive solutions to boom level reduction. The aim of the work is to give a clear statement of state-of-the-art sonic boom prediction methods and possible reduction solutions to be explored for the design of next low-boom supersonic aircraft.

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“…Therefore, the sonic boom reduction is essential for developing the supersonic airplane and the numerous studies of the sonic boom have been conducted. [1][2][3] It is difficult to predict the propagation mechanism of the sonic boom from the near-field around the airplane to the ground because of the multi-scale nature of the phenomena involving both the near-field and the far-field. Hence, the sonic boom prediction is conducted as follows.…”

Section: Introductionmentioning

confidence: 99%

Full-Field Sonic Boom Simulation in Real Atmosphere

Yamashita

Suzuki

2014

32nd AIAA Applied Aerodynamics Conference

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As the sonic boom prediction method, the usefulness of the full-field simulation, in which the whole flow field including both the zone around a supersonic body and that on the ground is analyzed as a single computational domain, is assessed in this paper. The three dimensional Euler analyses including the gravity term have been numerically conducted to take into account the variation of the atmospheric properties with the altitude. The solutionadaptive structured grids are constructed by advancing the computational domain sector by sector for the grid lines to be aligned with the shock wave surfaces. The computations are made to reproduce the D-SEND#1 flight test by Japan Aerospace Exploration Agency (JAXA). The computational results are validated by comparing with the results of the waveform parameter method and the flight test data taken from the D-SEND database provided by JAXA. The maximum pressure rises of the present full-field simulations agree well with those of the waveform parameter method and the flight test data. Consequently, the present full-field simulations seem promising to analyze the natures of the sonic boom propagation in the realistic atmosphere model. Nomenclature E, F, G = flux vector at x, y, z coordinate E t = total energy g = acceleration of gravity h = altitude L LBM = length of body of Low Boom Model L NWM = length of body of N-Wave Model p = pressure p ∞ = atmospheric pressure Q = vector of conservative variables r = radial coordinate R = gas constant s 1 -s 5 = component in corrective term S C = corrective term for gravity term S G = gravity term t = time T 0 = atmospheric temperature at ground T ∞ = atmospheric temperature u, v, w = velocity in x, y, z direction x = streamwise coordinate y = vertical coordinate z = horizontal coordinate β = atmospheric temperature lapse rate Δr = distance in r direction θ = rotational coordinate ρ = density ρ ∞ = atmospheric density 1 Graduate Student, Department of Advanced Energy, 5-1-5 Kashiwanoha, yamashita@daedalus.k.u-tokyo.ac.jp, Student Member AIAA. 2 Professor, Department of Advanced Energy, 5-1-5 Kashiwanoha, kjsuzuki@k.u-tokyo.ac.jp, Senior Member AIAA. Downloaded by MONASH UNIVERSITY on August 1, 2015 | http://arc.aiaa.org |

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Lobe Balancing Design Method to Create Frozen Sonic Booms Using Aircraft Components

Cited by 8 publications

References 35 publications

Ballistic Wave from Projectiles and Vehicles of Simple Geometry

Ballistic Wave from Projectiles and Vehicles of Simple Geometry

Review of Sonic Boom Prediction and Reduction Methods for Next Generation of Supersonic Aircraft

Full-Field Sonic Boom Simulation in Real Atmosphere

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