Influence of Loudspeaker Configurations and Orientations on Sound Localization

Yao, Shu-Nung

doi:10.24425/aoa.2022.140732

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Tytuł artykułu

Influence of Loudspeaker Configurations and Orientations on Sound Localization

Autorzy

Yao Shu-Nung

Treść / Zawartość

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Yao_Influence of Loudspeaker_AA_47_1_2022.pdf

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DOI

10.24425/aoa.2022.140732

Warianty tytułu

Języki publikacji

Abstrakty

As the virtual reality (VR) market is growing at a fast pace, numerous users and producers are emerging with the hope to navigate VR towards mainstream adoption. Although most solutions focus on providing high- resolution and high-quality videos, the acoustics in VR is as important as visual cues for maintaining consistency with the natural world. We therefore investigate one of the most important audio solutions for VR applications: ambisonics. Several VR producers such as Google, HTC, and Facebook support the ambisonic audio format. Binaural ambisonics builds a virtual loudspeaker array over a VR headset, providing immersive sound. The configuration of the virtual loudspeaker influences the listening perception, as has been widely discussed in the literature. However, few studies have investigated the influence of the orientation of the virtual loudspeaker array. That is, the same loudspeaker arrays with different orientations can produce different spatial effects. This paper introduces a VR audio technique with optimal design and proposes a dual-mode audio solution. Both an objective measurement and a subjective listening test show that the proposed solution effectively enhances spatial audio quality.

Słowa kluczowe

audio quality ambisonics immersive sound loudspeaker array spatial effect virtual reality

Wydawca

Instytut Podstawowych Problemów Techniki PAN
Komitet Akustyki PAN
Polskie Towarzystwo Akustyczne

Czasopismo

Archives of Acoustics

Rocznik

2022

Tom

Vol. 47, No. 1

Strony

57--70

Opis fizyczny

Bibliogr. 26 poz., fot., rys., wykr.

Twórcy

autor

Yao Shu-Nung

snyao@gm.ntpu.edu.tw

Department of Electrical Engineering, National Taipei University No. 151, University Rd., Sanxia Dist., New Taipei City 237303, Taiwan

Bibliografia

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11. Kleczkowski P., Krol A., Malecki P. (2015), Reproduction of phantom sources improves with separation of direct and reflected sounds, Archives of Acoustics, 40(4): 575-584, doi: 10.1515/aoa-2015-0057.
12. Matsumura T., Iwanaga N., Kobayashi W., Onoye T., Shirakawa I. (2005), Embedded 3D sound movement system based on feature extraction of headrelated transfer function, IEEE Transactions on Consumer Electronics, 51(1): 262-267, doi: 10.1109/TCE. 2005.1405730.
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14. Monro G. (2000), In-phase corrections for ambisonics, Proceedings of International Computer Music Conference, http://hdl.handle.net/2027/spo.bbp2372. 2000.194.
15. Ozga A. (2017), Scientific ideas included in the concepts of bioacoustics, acoustic ecology, ecoacoustics, soundscape ecology and vibroacoustics, Archives of Acoustics, 42(3): 415-421, doi: 10.1515/aoa-2017-0043.
16. Rumsey F. (2001), Spatial Audio, Jordan Hill, Oxford: Focal Press.
17. Sato S. (2014), MATLAB program for calculating the parameters of the autocorrelation and interaural cross-correlation functions based on Ando’s auditory-brain model, Proceedings of Audio Engineering Society 137th Convention, http://www.aes.org/elib/browse.cfm?elib=17504.
18. Satongar D., Dunn C., Lam Y., Li F. (2013), Localisation performance of higher-order Ambisonics for off-centre listening, White Paper, WHP254, https://www.bbc.co.uk/rd/publications/whitepaper254.
19. Scaini D., Arteaga D. (2014), Decoding of higher order ambisonics to irregular periphonic loudspeaker arrays, Proceedings of Audio Engineering Society 55th Convention, http://www.aes.org/e-lib/browse.cfm?elib =17364.
20. Wersényi G. (2009), Effect of emulated head-tracking for reducing localization errors in virtual audio simulation, IEEE Transactions on Audio, Speech, and Language Processing, 17(2): 247-252, doi: 10.1109/TASL. 2008.2006720.
21. Yao S.-N. (2014), Driver filter design for software-implemented loudspeaker crossovers, Archives of Acoustics, 39(4): 591-597, doi: 10.2478/aoa-2014-0063.
22. Yao S.-N. (2017), Headphone-based immersive audio for virtual reality headsets, IEEE Transactions on Consumer Electronics, 63(3): 300-308, doi: 10.1109/ TCE.2017.014951.
23. Yao S.-N. (2018), Equalization in ambisonics, Applied Acoustics, 139: 129-139, doi: 10.1016/j.apacoust. 2018.04.027.
24. Yao S.-N., Chen L.J. (2013), HRTF adjustments with audio quality assessments, Archives of Acoustics, 38(1): 55-62, doi: 10.2478/aoa-2013-0007.
25. Yao S.-N., Collins T., Jančovič P. (2015), Timbral and spatial fidelity improvement in ambisonics, Applied Acoustics, 93: 1-8, doi: 10.1016/j.apacoust. 2015.01.005.
26. Yao S.-N., Collins T., Liang C. (2017), Head-related transfer function selection using neural networks, Archives of Acoustics, 42(3): 365-373, doi: 10.1515/ aoa-2017-0038.

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Bibliografia

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