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RAS PhysicsАкустический журнал Acoustical Physics

  • ISSN (Print) 0320-7919
  • ISSN (Online) 3034-5006

On the possibility of three-dimensional localization of noise sources generated by the flow around aircraft planform elements using sequential asynchronous measurements by a microphone array

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PII
S30345006S0320791925030099-1
DOI
10.7868/S3034500625030099
Publication type
Article
Status
Published
Authors
O. P. Bychkov
  • Affiliation: Central Aerohydrodynamic Institute (TsAGI), Moscow Research Complex
M. A. Demyanov
  • Affiliation: Central Aerohydrodynamic Institute (TsAGI), Moscow Research Complex
Volume/ Edition
Volume 71 / Issue number 3
Pages
416-429
Abstract
The paper presents the results of applying a previously developed method for three-dimensional localization of acoustic sources using asynchronous measurements from a multi-microphone array in different positions, adapted for dipole-type sources typical of the noise generated by the flow around aircraft planform elements. The work consists of two parts. The first part presents the verification of the developed method using test dipole sources as an example. Sources with different orientations of the dipole moment relative to the faces of the microphone array are considered. Based on the obtained localization results for test sources, the features and limitations of the method are demonstrated. In the second part, the application of the method to experimental data obtained during the flow around a wing model with deployed high-lift devices and a cylinder simulating a landing gear strut, which has a complex structure of dipole sources with varying amplitudes and directivities, is described. An analysis of the obtained volumetric localization maps in various frequency bands is carried out by comparing them with test cases, demonstrating the feasibility of localizing the studied sources.
Keywords
фазированная антенна 3D бимформинг несинхронные измерения шум обтекания элементов планера
Date of publication
08.12.2025
Year of publication
2025
Number of purchasers
0
Views
17

References

  1. 1. Michel U. History of acoustic beamforming // 1st Berlin Beamforming Conference. 2006.
  2. 2. Christensen J.J., Hald J. Beamforming — technical review no.1. Brüel & Kjaer, Technical Review 1–2004, 2004.
  3. 3. Johnson D.H., Dudgeon D.E. Array Signal Processing, Concepts and Techniques, P T R Prentice Hall, Englewood Cliffs, 1993.
  4. 4. Dolph C.L. A current distribution of broadside arrays which optimizes the relationship between beam width and sidelobe level // Inst. Radio Eng. 1946. Т. 34. С. 335–348.
  5. 5. Бардышев В.И. Горизонтальная приемная случайная антенная решетка, согласованная с гидроакустическим волноводом // Акуст. журн. 2012. Т. 58. № 5. С. 610–613.
  6. 6. Yardibi T., Bahr C., Zawodny N.S., Liu F., Cattafesta III L.N., and Lik J. Uncertainty Analysis of the Standard Delay-and-Sum Beamformer and Array Calibration // AIAA 2009-3120.
  7. 7. Глебова Г.М., Аверьянов А.В., Кузнецов Г.Н. Экспериментальное исследование характеристик направленности векторно-скалярной антенны // Акуст. журн. 2011. Т. 57. № 5. С. 681–694.
  8. 8. Клячкин В.И. Статистический анализ векторно-фазовых характеристик акустических полей и алгоритмы их регистрации // Акуст. журн. 2004. Т. 50. № 4. С. 516–523.
  9. 9. Белова Н.И., Кузнецов Г.Н. Сравнение однонаправленного приема сигналов в волноводе с использованием линейных векторно-скалярных и комбинированных антенн // Акуст. журн. 2013. Т. 59. № 2. С. 255–267.
  10. 10. Белова Н.И., Кузнецов Г.Н., Степанов А.Н. Экспериментальное исследование интерференционной и фазовой структуры потока мощности от локальных источников в мелком море // Акуст. журн. 2016. Т. 62. № 3. С. 318–329.
  11. 11. Михайлов С.Г. Пеленгование векторно-скалярным приемником в поле анизотропной помехи // Акуст. журн. 2020. Т. 66. № 2. С. 170–180.
  12. 12. Yang Y., Chu Z., Shen L., Xu Z. Functional delay and sum beamforming for three-dimensional acoustic source identification with solid spherical arrays // J. Sound Vib. 2016. V. 373. P. 340–359.
  13. 13. Sarradj E. Three-dimensional acoustic source mapping with different beamforming steering vector formulations // Advances in Acoustics and Vibration. 2012. 292695.
  14. 14. Yu L., Guo Q., Chu N., Wang R. Achieving 3D Beamforming by Non-Synchronous Microphone Array Measurements // Sensors. 2020. V. 20. 7308.
  15. 15. Porteous R., Prime Z., Doolan C., Moreau D., Valeau V. Three-dimensional beamforming of dipolar aeroacoustic sources // J. Sound Vibr. 2015. V. 355. P. 117–134.
  16. 16. Бычков О.П., Демьянов М.А. Обобщение стандартного алгоритма “бимформинг” для идентификации акустических источников с помощью несинхронных измерений микрофонной решеткой // Акуст. журн. 2022. Т. 68. № 2. С. 162–172.
  17. 17. Curle N. The Influence of Solid Boundaries on Aerodynamic Sound // Proc. Roy. Soc. London. Ser. A 231. No. 1187. P. 505.
  18. 18. Бычков О.П., Демьянов М.А., Фараносов Г.А. Локализация дипольных источников шума плоскими микрофонными решетками // Акуст. журн. 2019. Т. 65. № 5. С. 675–687.
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