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Adaptive Sampling for Sound Propagation.

Chakravarty R Alla Chaitanya, John M Snyder, Keith Godin

    IEEE Transactions on Visualization and Computer Graphics
    |February 15, 2019
    PubMed
    Summary
    This summary is machine-generated.

    This study introduces adaptive acoustic sampling for dynamic sound propagation. It improves realism in virtual environments by intelligently placing sound probes, unlike uniform grids, enhancing audio quality in complex spaces.

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    Area of Science:

    • Computer Graphics
    • Computational Acoustics
    • Real-time Simulation

    Background:

    • Precomputed acoustics rely on discrete probes for dynamic sound rendering.
    • Uniform probe grids are inefficient, requiring high density for complex geometries.
    • Existing methods struggle with accurate sound propagation in narrow or occluded spaces.

    Purpose of the Study:

    • To develop an adaptive acoustic sampling method for improved sound propagation rendering.
    • To enhance the realism of dynamic audio in virtual environments.
    • To overcome limitations of uniform sampling and visibility-based solutions.

    Main Methods:

    • Implemented an offline 3D numerical simulation to precompute sound fields at probe locations.
    • Introduced a novel "local diameter" measure based on stochastic path tracing to guide adaptive probe placement.
    • Developed a runtime interpolator using geodesic paths and radial weights for smooth acoustic effect rendering.

    Main Results:

    • Adaptive sampling effectively varies probe density, optimizing resolution in complex areas like corners and corridors.
    • The method eliminates undersampling in narrow spaces while coarsening in open areas.
    • Achieved smooth acoustic effects respecting scene boundaries for moving sources and listeners, outperforming prior work.

    Conclusions:

    • Adaptive acoustic sampling significantly improves sound propagation quality and efficiency.
    • The novel local diameter measure enables intelligent probe placement for enhanced realism.
    • This approach offers a superior alternative to uniform grids and visibility-based methods for dynamic acoustics.