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Comparative%20Visualization%20for%20Wave-based%20and%20Geometric%20Acoustics

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Title: Comparative%20Visualization%20for%20Wave-based%20and%20Geometric%20Acoustics


1
Comparative Visualization for Wave-based and
Geometric Acoustics
  • Eduard Deines1, Martin Bertram3, Jan Mohring4,
    Jevgenij Jegorovs4, Frank Michel1, Hans Hagen2,
    and Gregory M. Nielson5

1IRTG Kaiserslautern 2University of
Kaiserslautern 3DFKI Kaiserslautern
4ITWM Kaiserslautern 5Arizona State University
2
Overview
  • Motivation
  • Acoustic Simulation
  • Modified Phonon Tracing
  • FEM-based solver
  • Comparison approach
  • Interference pattern visualization
  • Gain visualization

3
Motivation
  • Shortcomings of geometric and wave-based methods
  • Combination of both approaches
  • Numerical and visual comparison

4
Previous Work
  • Phonon tracing, based on sound particles
  • Computation of energy decomposition for each
    phonon (phonon emission)
  • Construction of response filters for each
    listener position (phonon collection)

5
Previous Work
Scattered data
Surfaces
Single particle
Listener based
6
Overview
  • Motivation
  • Acoustic Simulation
  • Modified Phonon Tracing
  • FEM-based solver
  • Comparison approach
  • Interference pattern visualization
  • Gain visualization

7
Modified Phonon Tracing
  • Tracing pressure rather then energy
  • gt better comparison with FEM
  • Modeling linear pressure attenuation by Gaussian
    basis functions dilated proportional with
    traversed distance
  • gt approximates partition of unity for the basis
    functions

8
Phonon Emission
  • For each phonon
  • Pressure spectrum
  • Virtual source
  • Phonons current position
  • One emmission, multiple collection passes for
    different listeners

9
Phonon Emission
  • Emission according to source distribution
  • Reflection at scene elements
  • Update virtual source
  • Multiply pressure by
  • Re-use path by next phonons
  • Record phonons on scene elements

10
Phonon Collection
  • For each visible phonon
  • Add unit pulse translated by distance
  • Scaling decreases with
  • Accumulated length
  • Wall absorption
  • Scaling depends on
  • Phonon outgoing direction
  • Direction from virtual source to listener position

11
Phonon Collection
  • Scaling depends on
  • Reference pressure at 1m from source
  • Gaussian weighting function
  • split unit pulse into frequency bands

12
Overview
  • Motivation
  • Acoustic Simulation
  • Modified Phonon Tracing
  • FEM-based solver
  • Comparison approach
  • Interference pattern visualization
  • Gain visualization

13
Finite Element Method (FEM)
  • Solving wave equation by FEM
  • FEM approximates the wave equation by a large
    system of ODEs
  • To many unknowns to solve the ODEs gt reduction
    needed

14
Finite Element Method (FEM)
  • Representation of the system dynamics by a
    superposition of eigenmodes
  • The coefficients of the eigenmodes are the
    unknowns of the reduced system
  • Samplewise constant input gt transformation of
    the continuous state-space model into a discrete
    one

15
Finite Element Method (FEM)
  • Typically few hundred unknowns rather than 10,000
    degrees of freedom
  • Required number of unknowns increases as the
    third power of the frequency gt only for
    low-frequency bands

16
Overview
  • Motivation
  • Acoustic Simulation
  • Modified Phonon Tracing
  • FEM-based solver
  • Comparison approach
  • Interference pattern visualization
  • Gain visualization

17
Test Scenario
Simulation scenario
Geometry
18
Simulation
  • regular grid
  • wave number k 3, 6, 9, 12, 15
  • f 164.25, 328.5, 492.7, 657, 821.2 Hz
  • Phonon Tracing point source, 100000 phonons
  • FEM small membrane

19
Overview
  • Motivation
  • Acoustic Simulation
  • Modified Phonon Tracing
  • FEM-based solver
  • Comparison approach
  • Interference pattern visualization
  • Gain visualization

20
Interference Pattern Visualization
  • Color mapping
  • Positive pressure to red
  • Negative pressure to blue
  • Reduction of saturation, depending on the
    absolute pressure value
  • Mapping of pressure values below the hearing
    threshold to gray
  • Bilinear interpolation of color values for
    additional grid points

21
Interference Pattern (k6 / f328.5 Hz)
Phonon Tracing
FEM
22
Interference Pattern (k12 / f657 Hz)
Phonon Tracing
FEM
23
Interference Pattern
k6
k6
Phonon Tracing
FEM
k12
k12
24
Overview
  • Motivation
  • Acoustic Simulation
  • Modified Phonon Tracing
  • FEM-based solver
  • Comparison approach
  • Interference pattern visualization
  • Gain visualization

25
Gain Visualization
  • Acoustic metric influence of the room
  • Error

26
Gain Visualization
  • Color coding
  • Use of HSV color space
  • Red for maximum value
  • Blue for minimum value
  • Same range for different simulations
  • Same range for all error plots

27
Gain - Error
28
Gain (k3 / f164.25 Hz)
Error
FEM
Phonon Tracing
29
Gain (k6 / f328.5 Hz)
Error
FEM
Phonon Tracing
30
Gain (k12 / f657 Hz)
Error
FEM
Phonon Tracing
31
Acknowledgments
  • Stiftung Rheinland-Pfalz fuer Innovation
  • Kaiserslautern Excellence Cluster Dependable
    Adaptive Systems and Mathematical Modeling
  • US Army Research Office

32
Thank you for attention!
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