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226 results on '"Ukeiley, Lawrence"'

1. Pressure-Informed Velocity Estimation in a Subsonic Jet

Author

Li, Songqi and Ukeiley, Lawrence

Subjects
Physics - Fluid Dynamics
Abstract

This work aims to estimate time-resolved velocity field that is directly associated with pressure fluctuations in a subsonic round jet. To achieve this goal, synchronous measurements of the velocity field and in-flow pressure fluctuations were performed at Mach number 0.3. Two different experiment campaigns were conducted, the first experimental campaign aims to explore the time-resolved dynamics of the axisymmetric velocity components, and second experiment focuses on the time-resolved, 2D velocity estimates on a streamwise plane. Two different methods were utilized to estimate the input-output relation between velocity and in-flow pressure measurements. A hybrid approach based on the spectral linear stochastic estimation and the proper orthogonal decomposition was applied to setup the model in a linear manner, and a wavelet-based filter was implemented to attenuate the noise level in the cross-correlation functions. In addition, the pressure-velocity relationship was also described by neural network architectures based on the multi-layer perceptron (MLP) and bidirectional long-short-term-memory (LSTM). In both experimental sets, pressure fluctuations inside the flow are found to be connected to the streamwise convection of large-scale coherent structures in the flow. A unique advantage of the bidirectional LSTM method was found among all estimation schemes is also reported in this work. The estimation result represents the space-time dynamics of the acoustic sources in the jet flow field, and it is of great importance to understand the noise generation mechanism., Comment: 39 pages, 25 figures This draft was prepared for the submission to Physical Review Fluids

Published
2021

2. Spectral Analysis Modal Methods (SAMMs) using Non-Time-Resolved PIV

Author

Zhang, Yang, Cattafesta III, Louis N., and Ukeiley, Lawrence

Subjects
Physics - Fluid Dynamics
Abstract

We present spectral analysis modal methods (SAMMs) to perform POD in the frequency domain using non-time-resolved Particle Image Velocity (PIV) data combined with unsteady surface pressure measurements. In particular, time-resolved unsteady surface pressure measurements are synchronized with non-time-resolved planar PIV measurements acquired at 15 Hz in a Mach 0.6 cavity flow. Leveraging the spectral linear stochastic estimation (LSE) method of Tinney et al. (2006), we first estimate the cross correlations between the velocity field and the unsteady pressure sensors via sequential time shifts, followed by a Fast Fourier transform to obtain the pressure-velocity cross spectral density matrix. This leads to a linear multiple-input / multiple-output (MIMO) model that determines the optimal transfer functions between the input cavity wall pressure and the output velocity field. Two variants of SAMMs are developed and applied. The first, termed "SAMM-SPOD", combines the MIMO model with the SPOD algorithm of Towne et al. (2018). The second, called "SAMM-RR'', adds independent sources and uses a sorted eigendecomposition of the input pressure cross-spectral matrix to enable an efficient reduced-rank eigendecomposition of the velocity cross-spectral matrix. In both cases, the resulting rank-1 POD eigenvalues associated with the Rossiter frequencies exhibit very good agreement with those obtained using independent time-resolved PIV measurements. The results demonstrate that SAMMs provide a methodology to perform space-time POD without requiring a high-speed PIV system, while avoiding potential pitfalls associated with traditional time-domain LSE., Comment: 13 pages, 16 figures

Published
2020
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3. Unsteady control of supersonic turbulent cavity flow based on resolvent analysis

Author

Liu, Qiong, Sun, Yiyang, Yeh, Chi-An, Ukeiley, Lawrence S., Cattafesta III, Louis N., and Taira, Kunihiko

Subjects
Physics - Fluid Dynamics
Abstract

We use resolvent analysis to determine an unsteady active control setup to attenuate pressure fluctuations in turbulent supersonic flow over a rectangular cavity with a length-to-depth ratio of 6 at a Mach number of 1.4 and a Reynolds number based on cavity depth of 10,000. Large-eddy simulations (LES) and dynamic modal decomposition (DMD) of the supersonic cavity flow reveal the dominance of two-dimensional Rossiter modes II and IV. These predominantly two-dimensional vortical structures generate high-amplitude unsteadiness over the cavity through trailing-edge impingement and create oblique shock waves by obstructing the freestream. To disrupt the undesired formation of vortical structures, we introduce three-dimensional unsteady forcing along the cavity leading edge to generate streamwise vortical structures. Resolvent analysis with respect to the time-averaged base flow is leveraged to determine the optimal combination of forcing frequency and spanwise wavenumber. Instead of selecting the most amplified resolvent forcing modes, we seek the combination of control parameters that yields sustained amplification of the primary resolvent-based kinetic energy distribution over the entire length of the cavity. The sustained amplification is critical to ensure that the selected forcing input remains effective to prevent the formation of the large spanwise vortices. This resolvent-analysis-based flow control guideline is validated with a number of companion LES of the controlled cavity flows. The optimal control setup is verified to be the most effective in reducing the pressure root-mean-square level up to 52% along the aft and bottom cavity walls compared to the baseline cavity flow. The present flow control guideline derived from resolvent analysis should be applicable to flows that require the actuation input to remain effective over an extended region of interest., Comment: 23 pages, 13 figures

Published
2020
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4. Resolvent analysis of compressible laminar and turbulent cavity flows

Author

Sun, Yiyang, Liu, Qiong, Cattafesta, Louis N., Ukeiley, Lawrence S., and Taira, Kunihiko

Subjects
Physics - Fluid Dynamics
Abstract

The present work demonstrates the use of resolvent analysis to obtain physical insights for open-cavity flows. Resolvent analysis identifies the flow response to harmonic forcing, given a steady base state, in terms of the response and forcing modes and the amplification gain. The response and forcing modes reveal the spatial structures associated with this amplification process. In this study, we perform resolvent analysis on both laminar and turbulent flows over a rectangular cavity with length-to-depth ratio of $L/D=6$ at a free stream Mach number of $M_\infty=0.6$ in a spanwise periodic setting. Based on the dominant instability of the base state, a discount parameter is introduced to resolvent analysis to examine the harmonic characteristics over a finite-time window. We first uncover the underlying flow physics and interpret findings from laminar flow at $Re_D = 502$. These findings from laminar flow are extended to a more practical cavity flow example at a much higher Reynolds number of $Re_D = 10^4$. The features of response and forcing modes from the laminar and turbulent cavity flows are similar to the spatial structures from the laminar analysis. We further find that the large amplification of energy in flow response is associated with high frequency for turbulent flow, while the flow is more responsive to low frequency excitation in the laminar case. These findings from resolvent analysis provide valuable insights for flow control studies with regard to parameter selection and placement of actuators and sensors.

Published
2019

5. Spanwise effects on instabilities of compressible flow over a long rectangular cavity

Author

Sun, Yiyang, Taira, Kunihiko, Cattafesta, Louis N., and Ukeiley, Lawrence S.

Subjects
Physics - Fluid Dynamics
Abstract

The stability properties of two- (2D) and three-dimensional (3D) compressible flows over a rectangular cavity with length-to-depth ratio of $L/D=6$ is analyzed at a free stream Mach number of $M_\infty=0.6$ and depth-based Reynolds number of $Re_D=502$. In this study, we closely examine the influence of three-dimensionality on the wake-mode that has been reported to exhibit high-amplitude fluctuations from the formation and ejection of large-scale spanwise vortices. Direct numerical simulation (DNS) and bi-global stability analysis are utilized to study the instability characteristics of the wake-mode. Using the bi-global stability analysis with the time-average flow as the base state, we capture the global stability properties of the wake-mode at a spanwise wavenumber of $\beta=0$. To uncover spanwise effects on the 2D wake-mode, 3D DNS are performed with cavity width-to-depth ratio of $W/D=1$ and $2$. We find that the 2D wake-mode is not present in the 3D cavity flow for a wider spanwise setting with $W/D=2$, in which spanwise structures are observed near the rear region of the cavity. These 3D instabilities are further investigated via bi-global stability analysis for spanwise wavelengths of $\lambda/D=0.5-2.0$ to reveal the eigenspectra of the 3D eigenmodes. Based on the findings of 2D and 3D global stability analysis, we conclude that the absence of the wake-mode in 3D rectangular cavity flows is due to the release of kinetic energy from the spanwise vortices to the streamwise vortical structures that develops from the spanwise instabilities., Comment: The final publication is available at https://link.springer.com/article/10.1007%2Fs00162-016-0412-y

Published
2018
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6. Effects of sidewalls and leading-edge blowing on flows over long rectangular cavities

Author

Sun, Yiyang, Liu, Qiong, Cattafesta, Louis N., Ukeiley, Lawrence S., and Taira, Kunihiko

Subjects
Physics - Fluid Dynamics
Abstract

The present work investigates sidewall effects on the characteristics of three-dimensional (3D) compressible flows over a rectangular cavity with aspect ratios of $L/D=6$ and $W/D=2$ at $Re_D=10^4$ using large eddy simulations (LES). For the spanwise-periodic cavity flow, large pressure fluctuations are present in the shear layer and on the cavity aft wall due to spanwise vortex roll-ups and flow impingement. For the finite-span cavity with sidewalls, pressure fluctuations are reduced due to interference to the vortex roll-ups from the sidewalls. Flow oscillations are also reduced by increasing the Mach number from 0.6 to 1.4. Furthermore, secondary flow inside the cavity enhances kinetic energy transport in the spanwise direction. Moreover, 3D slotted jets are placed along the cavity leading edge with the objective of reducing flow oscillations. Steady blowing into the boundary layer is considered with momentum coefficient $C_\mu=0.0584$ and $0.0194$ for $M_\infty=0.6$ and $1.4$ cases, respectively. The three-dimensionality introduced to the flow by the jets inhibits large coherent roll-ups of the spanwise vortices in the shear layer, yielding $9-40\%$ reductions in rms pressure and rms velocity for both spanwise-periodic and finite-span cavities.

Published
2018

7. Modal Analysis of Fluid Flows: An Overview

Author

Taira, Kunihiko, Brunton, Steven L., Dawson, Scott T. M., Rowley, Clarence W., Colonius, Tim, McKeon, Beverley J., Schmidt, Oliver T., Gordeyev, Stanislav, Theofilis, Vassilios, and Ukeiley, Lawrence S.

Subjects
Physics - Fluid Dynamics
Abstract

Simple aerodynamic configurations under even modest conditions can exhibit complex flows with a wide range of temporal and spatial features. It has become common practice in the analysis of these flows to look for and extract physically important features, or modes, as a first step in the analysis. This step typically starts with a modal decomposition of an experimental or numerical dataset of the flow field, or of an operator relevant to the system. We describe herein some of the dominant techniques for accomplishing these modal decompositions and analyses that have seen a surge of activity in recent decades. For a non-expert, keeping track of recent developments can be daunting, and the intent of this document is to provide an introduction to modal analysis that is accessible to the larger fluid dynamics community. In particular, we present a brief overview of several of the well-established techniques and clearly lay the framework of these methods using familiar linear algebra. The modal analysis techniques covered in this paper include the proper orthogonal decomposition (POD), balanced proper orthogonal decomposition (Balanced POD), dynamic mode decomposition (DMD), Koopman analysis, global linear stability analysis, and resolvent analysis., Comment: 43 pages, 17 figures

Published
2017

12. Dynamic Surface Pressure Based Estimation for Flow Control

Author

Ukeiley, Lawrence, Murray, Nathan, Song, Qi, Cattafesta, Louis, Gladwell, G. L. M., editor, Moreau, R., editor, Engelbrecht, J., editor, Freund, L. B., editor, Kluwick, A., editor, Moffatt, H. K., editor, Olhoff, N., editor, Tsutomu, K., editor, van Campen, D., editor, Zheng, Z., editor, Morrison, J. F., editor, Birch, D. M., editor, and Lavoie, P., editor

Published
2008
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14. Diagnostic Techniques to Elucidate the Aerodynamic Performance of Acoustic Liners

Author

June, Jason, Bertolucci, Brandon, Ukeiley, Lawrence, Cattafesta, Louis N., III, and Sheplak, Mark

Subjects
Fluid Mechanics And Thermodynamics
Abstract

In support of Topic A.2.8 of NASA NRA NNH10ZEA001N, the University of Florida (UF) has investigated the use of flow field optical diagnostic and micromachined sensor-based techniques for assessing the wall shear stress on an acoustic liner. Stereoscopic particle image velocimetry (sPIV) was used to study the velocity field over a liner in the Grazing Flow Impedance Duct (GFID). The results indicate that the use of a control volume based method to determine the wall shear stress is prone to significant error. The skin friction over the liner as measured using velocity curve fitting techniques was shown to be locally reduced behind an orifice, relative to the hard wall case in a streamwise plane centered on the orifice. The capacitive wall shear stress sensor exhibited a linear response for a range of shear stresses over a hard wall. PIV over the liner is consistent with lifting of the near wall turbulent structure as it passes over an orifice, followed by a region of low wall shear stress.

Published
2017

16. Acoustics and Forces from an Isolated Rotor System

Author

Goldschmidt, James, primary, Tingle, Henry, additional, Ifgu, Peter G., additional, Miller, Steven A., additional, Ukeiley, Lawrence S., additional, Goldman, Ben, additional, Droandi, Giovanni, additional, and Lee, Kyuho, additional

Published
2022
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19. Aeroacoustic and aerodynamic interaction effects between electric vertical takeoff and landing rotors

Author

Gustavo Resende Coelho, James D Goldschmidt, Henry J. Tingle, Peter G. Ifju, Ukeiley Lawrence, Ben Goldman, Maicon Secchi, and Steven A. Miller

Subjects
Acoustics and Ultrasonics, Arts and Humanities (miscellaneous)
Abstract

Electric vertical take-off and landing (eVTOL) aircraft are characterized by their unconventional wing and electric rotor configurations, which involve both side-by-side and tandem rotor configurations. These configurations create unique aerodynamic and acoustic flow-fields. We numerically investigate the interaction effects between rotor pairs as well as their individual and combined acoustic radiation. We examine horizontal and vertical spacing, rotor tilt angles, and forward flight effects. Performance is characterized by thrust coefficient, blade passage frequency (BPF) sound pressure level (SPL), and overall sound pressure level (OASPL). This study is performed with a mid-fidelity aerodynamic solver, Dust, which is used to predict the aerodynamic flow-field. The tonal acoustic pressure at observer positions is predicted via the Farassat F-1A solution of the Ffowcs Williams and Hawkings equation utilizing the aerodynamic flow-field. The configurations studied show strong aerodynamic interaction effects in thrust, as well as out-of-plane acoustic radiation from the aft rotor. Base predictions of thrust and noise are validated via experimental measurement. As rotor separation decreases, we observe that aft rotor thrust decreases and BPF SPL increases. The most forward rotor, however, is marginally impacted by the interactions. [This research is supported by Archer Aviation Inc.]

Published
2022

26. Suppression of cavity loads using leading-edge blowing

Author

Arunajatesan, Srinivasan, Kannepalli, Chandrasekhar, Sinha, Neeraj, Sheehan, Michael, Alvi, Farrukh, Shumway, George, and Ukeiley, Lawrence

Subjects
Strains and stresses -- Measurement, Strains and stresses -- Models, Stress relaxation (Materials) -- Measurement, Stress relaxation (Materials) -- Models, Stress relieving (Materials) -- Measurement, Stress relieving (Materials) -- Models, Jets -- Measurement, Aerospace and defense industries, Business
Abstract

We present hybrid Reynolds-averaged Navier--Stokes/large eddy simulation-based analysis of the suppression of fluctuating pressure loads on the walls of a complex nonrectangular cavity using leading-edge mass blowing. The unique aspect of the concepts discussed here is the very low mass flow rates used to achieve significant suppression. The simulation results are used to gain insight into the mechanism governing the effectiveness of these jets. The jets are applied to an L/D = 5.6 cavity at supersonic conditions of Mach 1.5. The simulation results show excellent agreement with experiments demonstrating an overall reduction in fluctuating pressure levels on the order of 50% with the control concepts. The primary mechanism of reduction is the break up of the spanwise coherence in the shear layer into smaller vortical structures thus reducing the shear layer flapping and leading to a smaller imprint on the wall pressures.

Published
2009

29. Control of pressure loads in geometrically complex cavities

Author

Ukeiley, Lawrence, Sheehan, Michael, Coiffet, Francois, Alvi, Farrukh, Arunajatesan, Srinivasan, and Jansen, Bernard

Subjects
Aerospace and defense industries, Business, Science and technology
Abstract

The need to reduce the fluctuating surface pressure loads in realistic three-dimensional cavity configurations is clear for many applications. In this paper, we describe the results of an experimental study that examined the properties of flow over a highly three-dimensional cavity, which included angled side walls and a sloped floor. The unsteady pressure measurements revealed that the primary spectral properties, such as the frequencies of the cavity tones, are very similar to those of simpler, rectangular cavities. The study also explored the effects of different active fluidic injection methods, at the cavity leading edge, on the unsteady loads generated in the cavity. Specifically, the two active suppression concepts examined were microjets and rectangular slots at the leading edge. Both concepts showed significant reductions in the fluctuating surface pressures, upwards of 50% on the cavity aft wall, with very modest amounts of mass flowing through the injectors. When appropriately scaled for full-scale applications, the actuator mass flux required falls well within the practical range for most aircraft. Different angles for the fluidic injection were also examined and maximum reductions were observed when injection was perpendicular to the approaching freestream flow. Additionally, the best blowing configurations were found when the injectors did not fully span the leading edge of the cavity. The reductions observed in the fluctuating surface pressure levels resulted from decreases in both the broadband and resonant features of the surface pressures. By conducting these experiments at two different facilities and over a range of freestream dynamic pressures and temperatures, this study also demonstrated that appropriate sealing of the spectral features can be achieved. This allows for the expansion of the results presented here to larger (and different) scale studies and ultimately to full-scale applications.

Published
2008

31. Spatial correlations in a transonic jet

Author

Ukeiley, Lawrence, Tinney, Charles E., Mann, Richa, and Glauser, Mark

Subjects
Aerospace engineering -- Research, Jet planes -- Design and construction, Turbulence -- Measurement, Aerospace and defense industries, Business
Abstract

Particle image velocimetry measurements of an unheated Mach 0.85 jet are used to examine its various turbulence properties. The data are presented from two separate experiments; one with the light sheet orientated in the streamwise direction (r-x plane) and one with the light sheet perpendicular to the flow direction (r-[theta] plane). The instrument's characteristics allow for the calculation and subsequent analysis of the two-point spatial correlations which are known to be relevant to the source terms in acoustics analogies where sound production is concerned. An examination of the spatial correlations demonstrates the averaged spatial evolution of the jet's large-scale turbulent structures throughout the noise producing region. In particular, the (r-x) spatial dependence of the axial and azimuthal normal stresses manifest a oblique structure in the mixing layer regions of the flow, whereas the radial normal stresses evolve more uniformly toward the end of the potential core. Quadrupole source terms relevant to the sound production mechanisms are also calculated from which their spatial distributions are analyzed with zero time delay. The analysis of these source terms at x/D = 4 show how the peak energy for the shear-noise component resides on the high-speed side of the shear layer around r/D = 0.33, whereas the self-noise terms peak along the lip-line at r/D = 0.5, and are most energetic for the streamwise and azimuthal components of the velocity. To fully evaluate the quadrupole sources of noise, the space-time correlations of the full three-dimensional turbulent flowfield are required which are currently not available from experiments.

Published
2007

33. Suppression of pressure loads in cavity flows

Author

Ukeiley, Lawrence S., Ponton, Michael K., Seiner, John M., and Jansen, Bernard

Subjects
Aerospace engineering, Aerospace and defense industries, Business
Abstract

The need to suppress dynamic-pressure loads in open cavities represents an important problem in many aeronautical applications. Many studies have been conducted using passive and active control techniques at the leading and trailing edges of cavities that have shown some success at reducing the dynamic-pressure levels in simulated weapons bays. In this work a leading-edge fence along with a cylindrical rod, suspended in the approaching boundary layer parallel to the leading edge of the cavity, was examined. The overall pressure levels along with the spectral distribution of the surface pressure in the cavity have been shown to be altered in a favorable manner by both of these devices. Suppressing the dynamic-pressure levels in the cavity was also found to alter the correlation between sensors along the floor cavity. Although it was found that both leading-edge devices lift the shear layer away from the cavity, the manner in which it is lifted appears to play an important role in the level of surface-pressure suppression.

Published
2004

36. Correction: Modal Analysis of Fluid Flows: An Overview

Author

Taira, Kunihiko, primary, Brunton, Steven L., additional, Dawson, Scott T. M., additional, Rowley, Clarence W., additional, Colonius, Tim, additional, McKeon, Beverley J., additional, Schmidt, Oliver T., additional, Gordeyev, Stanislav, additional, Theofilis, Vassilios, additional, and Ukeiley, Lawrence S., additional

Published
2020
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44. Active Control of Open Cavities

Author

UKeiley, Lawrence

Subjects
Aerodynamics
Abstract

Open loop edge blowing was demonstrated as an effective method for reducing the broad band and tonal components of the fluctuating surface pressure in open cavities. Closed loop has been successfully applied to low Mach number open cavities. Need to push actuators that are viable for closed loop control in bandwidth and output. Need a better understanding of the effects of control on the flow through detailed measurements so better actuation strategies can be developed.

Published
2010

50. Aeroacoustic Data for a High Reynolds Number Axisymmetric Subsonic Jet

Author

Ponton, Michael K, Ukeiley, Lawrence S, and Lee, Sang W

Subjects
Acoustics
Abstract

The near field fluctuating pressure and aerodynamic mean flow characteristics of a cold subsonic jet issuing from a contoured convergent nozzle are presented. The data are presented for nozzle exit Mach numbers of 0.30, 0.60, and 0.85 at a constant jet stagnation temperature of 104 F. The fluctuating pressure measurements were acquired via linear and semi-circular microphone arrays and the presented results include plots of narrowband spectra, contour maps, streamwise/azimuthal spatial correlations for zero time delay, and cross-spectra of the azimuthal correlations. A pitot probe was used to characterize the mean flow velocity by assuming the subsonic flow to be pressure-balanced with the ambient field into which it exhausts. Presented are mean flow profiles and the momentum thickness of the free shear layer as a function of streamwise position.

Published
1999

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