Investigation of multi-lobed fighter jet noise sources using acoustical holography and partial field decomposition methods

Wall, Alan T.; Gee, Kent L.; Neilsen, Tracianne B.; Harker, Blaine M.; McInerny, Sally Anne; McKinley, Richard L.; James, Michael M.; Ridge, Blue

doi:10.2514/6.2015-2379

Cited by 13 publications

(17 citation statements)

References 41 publications

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“…At afterburner and military engine conditions, data was taken at a sampling rate of 48 and 96 kHz, respectively. A significantly better understanding of the turbulent mixing noise in the geometric near field of a high-power military jet aircraft has resulted from the previous analysis of the data, using holography 35 and partial coherence decomposition 36 , correlation and coherence analysis 37 , multiple beamforming methods 38 , similarity spectra analysis 39 and equivalent source modeling 40 . Attached to the top of the 90 microphone array was a custom three-dimensional intensity probe [see Fig.…”

Section: Methodsmentioning

confidence: 99%

“…source mechanisms 36 . In addition, an intensity-based equivalent source model using two analytical, mutually incoherent steered line array sources has produced features consistent with these measurements, with greater success than the use of a single steered line array 31 .…”

Section: Vector Intensity Mapsmentioning

confidence: 99%

“…This effect is most pronounced at military engine conditions, where the estimated source region covering z = 6-7.5 m at 200 Hz shifts upstream to z = 3.5-5.5 at 250 Hz, the next third-octave band. As noted above, the nature of this transition region and the possibility of two discrete source mechanisms are currently being explored 36,39,48 .…”

Section: Ray-tracingmentioning

confidence: 99%

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Source characterization of full-scale jet noise using acoustic intensity

Stout¹,

Gee²,

Neilsen³

et al. 2015

noise cont engng j

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Vector acoustic intensity provides both the direction and magnitude of energy flow at the probe location and is, hence, more informative than acoustic pressure measurements. However, this important quantity has seen little application previously in aeroacoustics. In the present work, an intensity probe, consisting of four microphones, captured the radiated field to the sideline and aft of a tethered, full-scale military jet aircraft as one engine was operated at multiple engine conditions. Data from each probe location provide a frequency-dependent map of the sound flow near the aircraft. The vector acoustic intensity is estimated using a recently developed processing technique that extends the upperfrequency limit of the traditional cross-spectrum-based calculations. The dominant intensity vectors are traced back to the jet centerline as a method of approximating the extent and location of the source region as a function of frequency. As expected for jet mixing noise sources, the resulting source region estimates contract and move upstream with increasing frequency. A comparison of estimated source regions and intensity directionalities between military and afterburner engine conditions reveals important distinctions in the sound fields.

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Section: Methodsmentioning

confidence: 99%

Section: Vector Intensity Mapsmentioning

confidence: 99%

Section: Ray-tracingmentioning

confidence: 99%

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Source characterization of full-scale jet noise using acoustic intensity

Stout¹,

Gee²,

Neilsen³

et al. 2015

noise cont engng j

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“…For example, the target of a previous investigation was to separate the incoherent contributions of two jet radiation lobes, so the two VRs were simply located in the far field near the center of each lobe. 24 In the current work, contributions to the field from isolated source components (based on their spatial coherence in the near field) are desired. The OLVR procedure used here relies on the subprocesses of back propagation toward the source through the use of NAH, a PFD method based on a singular value decomposition (SVD-based PFD), 27 the MUSIC algorithm, 19,23 and the Gauss elimination technique (Cholesky decomposition) that is integral to a second PFD algorithm called partial coherence decomposition (PCD).…”

Section: Olvr Methodologymentioning

confidence: 99%

“…In order to obtain physically meaningful spatial distributions of PFs along the length of a jet axis, and account for partially coherent sources, the VRs selected here are optimized to have high MUSIC powers and low mutual coherence and to be spatially ordered. It should be noted that a different VR selection process with a different goal (i.e., the isolation of two partially independent radiation features) was implemented in a previous study, 24 emphasizing the fact that PFD is a nonunique process and the desired information dictates the method.…”

Section: Introductionmentioning

confidence: 99%

Partial-field decomposition analysis of full-scale supersonic jet noise using optimized-location virtual references

Wall

Gee

Leete

et al. 2018

The Journal of the Acoustical Society of America

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Supersonic jet noise reduction efforts benefit from targeted source feature extraction and high-resolution acoustic imaging. Another useful tool for feature extraction is partial field decomposition of sources into independent contributors. Since such decomposition processes are nonunique, care must be taken in the physical interpretation of decomposed partially coherent aeroacoustic fields. The optimized-location virtual reference method (OLVR) is a partial field decomposition designed to extract physically meaningful source and field information through the strategic placement of virtual references within a reconstructed field. The OLVR method is applied here to obtain spatially distinct and ordered partial sources at multiple frequencies of a full-scale, high-performance supersonic jet engine operating at 100% engine power. Partial sources are shown to mimic behaviors of the total source distributions including monotonic growth and decay. Because of finite spatial coherence, multiple partial sources are used to reproduce far-field radiation away from the main lobe, and the number of required sources increases with increasing frequency. An analytical multiwavepacket model is fitted to the partial sources to demonstrate how OLVR partial fields can be leveraged to produce reduced-order models.

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Obtaining acoustic intensity from multisource statistically optimized near-field acoustical holography

Stout

Wall

Gee

et al. 2018

The Journal of the Acoustical Society of America

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Multisource statistically optimized near-field acoustical holography (M-SONAH) improves the field reconstruction process by directly incorporating into the pressure propagator types of wavefunctions that correspond most closely to the source geometries of interest [A. T. Wall et al., J. Acoust. Soc. Am. 137, 963–975 (2015)]. The M-SONAH method has previously been used to localize acoustic sources in a full-scale jet engine plume above a rigid reflecting plane by adding a second set of cylindrical wavefunctions corresponding to the image source [A. T. Wall et al. J. Acoust. Soc. Am. 139, 1938–1950 (2016)]. Here, M-SONAH theory is extended to obtain the vector particle velocity and, by extension, the acoustic intensity. Discussed are two examples that relate to the full-scale jet noise-with-image-plane reconstruction problem: (1) a Gaussian line source with image and (2) a jet-like wavepacket and image, with hologram geometry identical to that of the full-scale experiment. The results from both examples reveal intensity errors less than 3 dB and 10 degrees within the top 20 dB of the reconstruction region. The results also suggest that intensity reconstruction magnitudes less than those obtained at the measurement aperture edges should be discarded. [Work supported by ONR.]

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Investigation of multi-lobed fighter jet noise sources using acoustical holography and partial field decomposition methods

Cited by 13 publications

References 41 publications

Source characterization of full-scale jet noise using acoustic intensity

Source characterization of full-scale jet noise using acoustic intensity

Partial-field decomposition analysis of full-scale supersonic jet noise using optimized-location virtual references

Obtaining acoustic intensity from multisource statistically optimized near-field acoustical holography

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