Efficient Synthesis of Room Acoustics via Scattering Delay Networks

Sena, Enzo De; Hacıhabiboğlu, Hüseyin; Cvetković, Zoran; Smith, Julius O.

doi:10.1109/taslp.2015.2438547

Cited by 32 publications

(42 citation statements)

References 41 publications

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“…Individual delay lines are expanded into a set of multichannel signals by encoding a mono input signal in the SH domain, as in Eq. (11). A directional energy weighting function is included in the recirculating path to modify the direction-dependent energy decay T 60 (φ, θ ), which can be tuned to resemble the anisotropic energy decay behavior of an existing space.…”

Section: Directional Feedback Delay Networkmentioning

confidence: 99%

“…For multichannel sound reproduction Gerzon [6], as well as Stautner and Puckette [8], presented a method that distributes the decorrelated output of different delay lines to a set of spatially arranged loudspeakers. In [11], De Sena et al introduced a physically informed recirculating delay system, using digital waveguide networks, capable of positioning the output at the location of the first-order early reflections in a virtual shoebox. This design was further expanded to include physically informed second-order reflections [12].…”

Section: Introductionmentioning

confidence: 99%

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Directional Feedback Delay Network

Alary¹,

Politis²,

Schlecht³

et al. 2019

J. Audio Eng. Soc.

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Artificial reverberation algorithms are used to enhance dry audio signals. Delay-based reverberators can produce a realistic effect at a reasonable computational cost. While the recent popularity of spatial audio algorithms is mainly related to the reproduction of the perceived direction of sound sources, there is also a need to spatialize the reverberant sound field. Usually multichannel reverberation algorithms output a series of decorrelated signals yielding an isotropic energy decay. This means that the reverberation time is uniform in all directions. However, the acoustics of physical spaces can exhibit more complex direction-dependent characteristics. This paper proposes a new method to control the directional distribution of energy over time, within a delay-based reverberator, capable of producing a directional impulse response with anisotropic energy decay. We present a method using multichannel delay lines in conjunction with a direction-dependent transform in the spherical harmonic domain to control the direction-dependent decay of the late reverberation. The new reverberator extends the feedback delay network, retaining its time-frequency domain characteristics. The proposed directional feedback delay network reverberator can produce non-uniform direction-dependent decay time, suitable for anisotropic decay reproduction on a loudspeaker array or in binaural playback through the use of ambisonics.

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Section: Directional Feedback Delay Networkmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Directional Feedback Delay Network

Alary¹,

Politis²,

Schlecht³

et al. 2019

J. Audio Eng. Soc.

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show abstract

“…An artificial reverberator that inherits all its parameters from physical characteristics of the room it simulates was recently proposed [12]. This reverberator, termed scattering delay network (SDN), is a modified DWN where the length of the digital waveguides and the topology of the network, as illustrated conceptually in Fig.…”

Section: B Perceptually-motivated Artificial Reverberationmentioning

confidence: 99%

“…Full-blown room auralization systems typically aim to render each and every reflection and diffraction up to a given order for each source [10], [11]. More recent methods achieve remarkable computational savings by rendering accurately only first order reflections, while replacing higher order reflections with their progressively coarser approximations [12]. Further computational savings are possible by eliminating sources whenever they are inaudible, a process referred to as audio source culling.…”

Section: Introductionmentioning

confidence: 99%

Perceptual Spatial Audio Recording, Simulation, and Rendering: An overview of spatial-audio techniques based on psychoacoustics

Hacıhabiboğlu

Sena

Cvetković

et al. 2017

IEEE Signal Process. Mag.

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Abstract-Developments in immersive audio technologies have been evolving in two directions: physicallymotivated and perceptually-motivated systems. Physically motivated techniques aim to reproduce a physically accurate approximation of desired sound fields by employing a very high equipment load and sophisticated computationally intensive algorithms. Perceptually-motivated techniques, on the other hand, aim to render only the perceptually relevant aspects of the sound scene by means of modest computational and equipment load. This article presents an overview of perceptually motivated techniques, with a focus on multichannel audio recording and reproduction, audio source and reflection culling, and artificial reverberators.

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“…The subjects could choose between two conditions-an anechoic condition, where the sound source was placed in free field at the same height as the listener and at a distance of 1.4 m, and a reverberant condition, where the room acoustic response was simulated in real-time using a scattering delay network (SDN) [19]. SDN was chosen to generate the reverberation because of its ability to reproduce faithfully the important physical (e.g., early reflections, reverberation time) and perceptual features (e.g., normalized echo density) while running in real-time.…”

Section: Sound Stimulimentioning

confidence: 99%

Localization Experiments with Reporting by Head Orientation: Statistical Framework and Case Study

Sena¹,

Brookes²,

Naylor³

et al. 2017

J. Audio Eng. Soc.

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This paper is concerned with sound localization experiments in which subjects report the position of an active sound source by turning toward it. A statistical framework for the analysis of the data from this type of experiment is presented together with a case study from a largescale listening experiment. The statistical framework is based on a model that is robust to the presence of front/back confusions and random errors. Closed-form natural estimators are derived, and one-sample and two-sample statistical tests are presented. The framework is used to analyze the data of an auralized experiment undertaken by nearly nine hundred subjects. Results show that responses had a rightward bias and that speech was harder to localize than percussion sounds, which are results consistent with the literature. Results also show that it was harder to localize sound in a simulated room with high ceiling, despite having a higher direct-to-reverberant ratio than other simulated rooms.

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Efficient Synthesis of Room Acoustics via Scattering Delay Networks

Cited by 32 publications

References 41 publications

Directional Feedback Delay Network

Directional Feedback Delay Network

Perceptual Spatial Audio Recording, Simulation, and Rendering: An overview of spatial-audio techniques based on psychoacoustics

Localization Experiments with Reporting by Head Orientation: Statistical Framework and Case Study

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