Canonical Stochastic Realization of Turbulent Sound Sources via Forced Linear Advection-Diffusion-Dissipation Equation

Ewert, Roland

doi:10.2514/6.2016-2965

Cited by 7 publications

(3 citation statements)

References 30 publications

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“…The G-L equation in linear form constitutes a linear advection-diffusion-dissipation system. A similar methodology was used in the by Ewert (2016) for source modelling. The acoustic interaction between the wavepacket and the flap is modelled by placing a semi-infinite half plane near the wavepacket and using a tailored Green's function which accounts for the scattering due to the plane.…”

Section: Linear Model For Installation Noisementioning

confidence: 99%

Modeling closed-loop control of installation noise using Ginzburg-Landau equation

Karban¹,

Martini²,

Jordan³

2023

Preprint

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Installation noise is a dominant source associated with aircraft jet engines. Recent studies show that linear wavepacket models can be employed for prediction of installation noise, which suggests that linear control strategies can also be adopted for mitigation of it. We present here a simple model to test different control approaches and highlight the potential restrictions on a successful noise control in an actual jet. The model contains all the essential elements for a realistic representation of the actual control problem: a stochastic wavepacket is obtained via a linear Ginzburg-Landau model; the effect of the wing trailing edge is accounted for by introducing a semi-infinite half plane near the wavepacket; and the actuation is achieved by placing a dipolar point source at the trailing edge, which models a piezoelectric actuator. An optimal causal resolvent-based control method is compared against the classical wave-cancellation method. The effect of the causality constraint on the control performance is tested by placing the sensor at different positions. We demonstrate that when the sensor is not positioned sufficiently upstream of the trailing edge, which can be the case for the actual control problem due to geometric restrictions, causality reduces the control performance. We also show that this limitation can be moderated using the optimal causal control together with modelling of the forcing.

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Section: Linear Model For Installation Noisementioning

confidence: 99%

Modeling closed-loop control of installation noise using Ginzburg-Landau equation

Karban¹,

Martini²,

Jordan³

2023

Preprint

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“…Their random variates are generated from an Ornstein-Uhlenbeck process involving a time scale τ B , refer to the discussion in Ref. 34 The particles are advected in a mean-flow, i.e.ẋ p = v 0 . The particle seeding and distribution is realized so that a constant particle density is obtained and maintained throughout each simulation.…”

Section: B Stochastic Forcing With Frpmmentioning

confidence: 99%

“…Also shown in the plot are results of a theoretical backscatter variance scaling function derived from Canonical Modeling theory. 34 The theoretical backscatter scaling is derived as…”

Section: Scaling Of the Forcing-spectrum Functionmentioning

confidence: 99%

Simulation of Cold Jet Installation Noise using a Stochastic Backscatter Model

Ewert

Neifeld

Boenke

2017

23rd AIAA/CEAS Aeroacoustics Conference

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This work presents first results obtained with partly scale resolving simulation for two different installation noise problems involving a cold jet interacting with a wing. Similar to very large-eddy simulation (VLES), the resolvable very large scales of turbulent fluctuations are directly calculated and the dissipation of the non-resolved scales is accounted for by a subfilter scale stress model. In addition, stochastic forcing in space and time is applied to model turbulent backscatter. The paper presents and discusses the rationale to explicitly realize turbulent backscatter along with details of the proposed stochastic backscatter model and its calibration. As a novel approach, the entire subfilter forcing function is modeled by means of an eddy-relaxation source term that provides a combined model for forcing and dissipation. The relaxation parameter defines the amount of correlation of the subfilter forcing with resolved quantities. Its proper calibration is achieved using decaying homogeneous isotropic turbulence. Furthermore, characteristics of the backscatter forcing are analyzed from synthetic turbulence data. The first jet-wing interaction problem studied is based on a generic static jet interacting with a non-inclined rectangular wing. The second problem deals with a dual-stream nozzle installed at a high-lift wing with deployed flap and slat in wind tunnel flow under approach conditions. For both problems installation noise from the airframe yields higher peak levels than the jet-noise contribution alone. For the first problem, relative to the corresponding jet spectrum a low-frequency narrow-band contribution is observed that can be attributed to coherent jet structures interacting with the airfoil trailing edge. Very good agreement with measured spectra is obtained. For the second problem a broadband airframe installation contribution to the overall spectrum is predicted with peak frequency above the jet contribution.

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Modeling Closed-Loop Control of Installed Jet Noise Using Ginzburg-Landau Equation

Karban,

Martini,

Jordan

2023

Flow Turbulence Combust

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Canonical Stochastic Realization of Turbulent Sound Sources via Forced Linear Advection-Diffusion-Dissipation Equation

Cited by 7 publications

References 30 publications

Modeling closed-loop control of installation noise using Ginzburg-Landau equation

Modeling closed-loop control of installation noise using Ginzburg-Landau equation

Simulation of Cold Jet Installation Noise using a Stochastic Backscatter Model

Modeling Closed-Loop Control of Installed Jet Noise Using Ginzburg-Landau Equation

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