Amplitude and frequency modulation in wall turbulence
Amplitude and frequency modulation in wall turbulence
In this study we examine the impact of the strength of the large-scale motions on the amplitude and frequency of the small scales in high-Reynolds-number turbulent boundary layers. Time series of hot-wire data are decomposed into large- and small-scale components, and the impact of the large scale on the amplitude and frequency of the small scales is considered. The amplitude modulation effect is examined by conditionally averaging the small-scale intensity () for various values of the large-scale fluctuation (). It is shown that increases with increasing value of in the near-wall region, whereas, farther away from the wall, decreases with increasing . The rate of increase in small-scale intensity with the strength of the large-scale signal is neither symmetric (about ) nor linear. The extent of the frequency modulation is examined by counting the number of occurrences of local maxima or minima in the small-scale signal. It is shown that the frequency modulation effect is confined to the near-wall region and its extent diminishes rapidly beyond . A phase lag between the large- and small-scale fluctuations, in terms of amplitude modulation, has also been identified, which is in agreement with previous studies. The phase lag between large- and small-scale fluctuations for frequency modulation is comparable to that of amplitude modulation in the near-wall region. The combined effect of both amplitude and frequency modulation is also examined by computing conditional spectra of the small-scale signal conditioned on the large scales. In the near-wall region, the results indicate that the peak value of pre-multiplied spectra increases with increasing value of , indicating amplitude modulation, while the frequency at which this peak occurs also increases with increasing value of , revealing frequency modulation. The overall trends observed from the conditional spectra are consistent with the results obtained through statistical analyses. Finally, a physical mechanism that can capture most of the above observations is also presented.
turbulent boundary layers
61-91
Ganapathisubramani, B.
5e69099f-2f39-4fdd-8a85-3ac906827052
Hutchins, N.
28046228-1b0a-45ab-97ff-dfec82afe47d
Monty, J.P.
b73588eb-5749-46f9-8efb-b2e52924c27e
Chung, D.
2e971c4e-3b1b-4bfd-b2c2-f58b5ecb58a4
Marusic, I.
59f585da-d4ab-4dbf-8a74-421f5fb90e6a
December 2012
Ganapathisubramani, B.
5e69099f-2f39-4fdd-8a85-3ac906827052
Hutchins, N.
28046228-1b0a-45ab-97ff-dfec82afe47d
Monty, J.P.
b73588eb-5749-46f9-8efb-b2e52924c27e
Chung, D.
2e971c4e-3b1b-4bfd-b2c2-f58b5ecb58a4
Marusic, I.
59f585da-d4ab-4dbf-8a74-421f5fb90e6a
Ganapathisubramani, B., Hutchins, N., Monty, J.P., Chung, D. and Marusic, I.
(2012)
Amplitude and frequency modulation in wall turbulence.
Journal of Fluid Mechanics, 712, .
(doi:10.1017/jfm.2012.398).
Abstract
In this study we examine the impact of the strength of the large-scale motions on the amplitude and frequency of the small scales in high-Reynolds-number turbulent boundary layers. Time series of hot-wire data are decomposed into large- and small-scale components, and the impact of the large scale on the amplitude and frequency of the small scales is considered. The amplitude modulation effect is examined by conditionally averaging the small-scale intensity () for various values of the large-scale fluctuation (). It is shown that increases with increasing value of in the near-wall region, whereas, farther away from the wall, decreases with increasing . The rate of increase in small-scale intensity with the strength of the large-scale signal is neither symmetric (about ) nor linear. The extent of the frequency modulation is examined by counting the number of occurrences of local maxima or minima in the small-scale signal. It is shown that the frequency modulation effect is confined to the near-wall region and its extent diminishes rapidly beyond . A phase lag between the large- and small-scale fluctuations, in terms of amplitude modulation, has also been identified, which is in agreement with previous studies. The phase lag between large- and small-scale fluctuations for frequency modulation is comparable to that of amplitude modulation in the near-wall region. The combined effect of both amplitude and frequency modulation is also examined by computing conditional spectra of the small-scale signal conditioned on the large scales. In the near-wall region, the results indicate that the peak value of pre-multiplied spectra increases with increasing value of , indicating amplitude modulation, while the frequency at which this peak occurs also increases with increasing value of , revealing frequency modulation. The overall trends observed from the conditional spectra are consistent with the results obtained through statistical analyses. Finally, a physical mechanism that can capture most of the above observations is also presented.
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e-pub ahead of print date: 27 September 2012
Published date: December 2012
Keywords:
turbulent boundary layers
Organisations:
Aerodynamics & Flight Mechanics Group
Identifiers
Local EPrints ID: 354994
URI: http://eprints.soton.ac.uk/id/eprint/354994
ISSN: 0022-1120
PURE UUID: 485b4655-0480-41dd-80d6-f325e3e43794
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Date deposited: 12 Aug 2013 10:45
Last modified: 15 Mar 2024 03:37
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Contributors
Author:
N. Hutchins
Author:
J.P. Monty
Author:
D. Chung
Author:
I. Marusic
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