An acoustically-tuned spectral proper orthogonal decomposition

Abstract

A new method to construct efficient reduced-order models for far-field radiation from a turbulent round jet over a wide band of frequencies and directivity angles is proposed here. It leverages the property of the free-space Green’s function, often employed in the solution to the Lighthill's equation, in extracting the acoustic component from the Lighthill's equivalent near-field sources. The methodology is referred to here as the “Lighthill Spectral Proper Orthogonal Decomposition” or LSPOD. The process yields sharply low-rank LSPOD modes that recovers up to 95% of the acoustic fluctuations energy with just five modes for St ≲ 1. The LSPOD mode shapes resemble acoustic waves emanating from the jet’s breakdown location, very different to the wavepacket shapes of typical near-field fluctuations-based SPOD modes. Remarkably, the leading LSPOD mode alone reconstructs the far-field spectra at the peak radiation angle of ϕ = 30° to within 1 dB accuracy across all frequencies considered here. In fact, the OASPL results show that eight LSPOD modes are able to consistently recover the radiated sound pressure at all observer angles, even at sideline and upstream angles, within a single decibel error.

Keywords

Aeroacoustics jet noise SPOD Green's function reduced-order models

Get full access to this article

View all access options for this article.

References

Crighton

. Basic principles of aerodynamic noise generation. Prog. Aero. Sci. 1975; 16: 31–96.

Kovasznay

LSG

. Turbulence in supersonic flow. J Aero Sci 1953; 20(10): 657–674.

Lighthill

. On sound generated aerodynamically: I. General theory. Proc R Soc A A 1952; 211: 564–587.

Lighthill

. On sound generated aerodynamically: II. Turbulence as a source of sound. Proc R Soc A A 1954; 222: 1–32.

Muthichur

Vempati

Hemchandra

, et al. Reduced-order models of aeroacoustic sources for sound radiated in twin subsonic jets. J. Fluid Mech. 2023; 972: A33.

Kline

Reynolds

Schraub

, et al. The structure of turbulent boundary layers. J. Fluid Mech. 1967; 30(4): 741–773.

Bradshaw

Ferriss

Johnson

. Turbulence in the noise-producing region of a circular jet. J. Fluid Mech. 1964; 19(4): 591–624.

Mollo-Christensen

. Jet noise and shear flow instability seen from an experimenter’s viewpoint. J. Appl. Mech. 1967; 34(1): 1–7.

Brown

Roshko

. On density effects and large structures in turbulent mixing layers. J. Fluid Mech. 1974; 64: 775–781.

10.

Crighton

Gaster

. Stability of slowly diverging jet flow. J. Fluid Mech. 1976; 77: 397–413.

11.

Lumley

. The structure of inhomogeneous turbulent flows. In: Atmospheric turbulence and radio wave propagation. Defense Technical Information Center, 1967, pp. 166–178.

12.

Lumley

. Stochastic tools in turbulence. Elsevier, 2012.

13.

Holmes

. Turbulence, coherent structures, dynamical systems and symmetry. Cambridge University Press, 2012.

14.

Chu

. On the energy transfer to small disturbances in fluid flow (part I). Acta Mech 1965; 1(3): 215–234.

15.

Rowley

Colonius

Murray

. Dynamical models for control of cavity oscillations. AIAA Paper, 2001, vol 2001–2126.

16.

Freund

Colonius

. Turbulence and sound-field pod analysis of a turbulent jet. Int. J. Aeroacoustics. 2009; 8(4): 337–354.

17.

Doak

. Momentum potential theory of energy flux carried by momentum fluctuations. J. Sound Vib. 1989; 131(1): 67–90.

18.

Unnikrishnan

Cavalieri

AVG

Gaitonde

. Acoustically informed statistics for wave-packet models. AIAA J 2019; 57(6): 2421–2434.

19.

Pickering

Towne

Jordan

, et al. Resolvent-based modeling of turbulent jet noise. J. Acoust. Soc. Am. 2021; 150(4): 2421–2433.

20.

Bugeat

Karban

Agarwal

Lesshafft

Jordan

. Acoustic resolvent analysis of turbulent jets. Theor. Comput. Fluid Dyn. 2024; 38(5): 687–706.

21.

Towne

Schmidt

Colonius

. Spectral proper orthogonal decomposition and its relationship to dynamic mode decomposition and resolvent analysis. J. Fluid Mech. 2018; 847: 821–867.

22.

Ffowcs-Williams

Hawkings

. Sound generation by turbulence and surfaces in arbitrary motion. Phil. Trans. Roy. Soc. Lond. 1969; 264: 321–342.

23.

Mathew

Lechner

Foysi

, et al. An explicit filtering method for large eddy simulation of compressible flows. Phys. Fluids. 2003; 15(8): 2279–2289.

24.

Datta

Mathew

Hemchandra

. The explicit filtering method for large eddy simulations of a turbulent premixed flame. Combust. Flame. 2022; 237: 111862.

25.

Stromberg

McLaughlin

Troutt

. Flow field and acoustic properties of a Mach number 0.9 jet at a low Reynolds number. J. Sound Vib. 1980; 72: 159–176.

26.

Freund

. Noise sources in a low-Reynolds-number turbulent jet at Mach 0.9. J. Fluid Mech. 2001; 438: 277–305.

27.

Schmidt

Towne

Rigas

Colonius

Bres

. Spectral analysis of jet turbulence. J. Fluid Mech. 2018; 855: 953–982.

28.

Panda

Seasholtz

. Experimental investigation of density fluctuations in high-speed jets and correlation with generated noise. J Fluid Mech. 2002; 450: 97–130.

29.

Tam

CKW

. On the noise of a nearly ideally expanded supersonic jet. J. Fluid Mech. 1972; 51(1): 69–95.

30.

Nekkanti

Schmidt

. Frequency–time analysis, low-rank reconstruction and denoising of turbulent flows using SPOD. J. Fluid Mech. 2021; 926: A26.