INIS
acoustic measurements
100%
cavities
100%
wind tunnels
100%
acoustics
44%
boundary layers
41%
simulation
34%
geometry
24%
noise
17%
aerodynamics
17%
signal-to-noise ratio
17%
walls
17%
attenuation
13%
depth
13%
finite element method
10%
energy
10%
wind turbines
10%
foams
10%
shape
10%
fluctuations
10%
aircraft
10%
design
6%
levels
6%
coverings
6%
decay
6%
computational fluid dynamics
6%
ducts
6%
size
6%
experimental data
6%
modeling
6%
apertures
6%
signals
6%
increasing
3%
economic impact
3%
production
3%
surfaces
3%
cross sections
3%
axial symmetry
3%
testing
3%
reduction
3%
efficiency
3%
standing waves
3%
spectra
3%
decomposition
3%
animals
3%
amplitudes
3%
air flow
3%
mitigation
3%
cost
3%
coherence length
3%
data
3%
humans
3%
algorithms
3%
noise pollution
3%
sound waves
3%
Engineering
Cavity
100%
Acoustics
100%
Tunnels
100%
Signal-to-Noise Ratio
17%
Pressure Field
13%
Foam
10%
Finite Element Method
10%
Aircraft
10%
Mechanisms
10%
Beamforming
10%
Pressure Fluctuation
10%
Models
6%
Computational Fluid Dynamics
6%
Acoustic Signal
6%
Aperture Size
6%
Experiments
6%
Design
6%
Aerodynamic Noise
6%
Aerodynamics
6%
Environmental Noise
3%
Microphone Array
3%
Operational Efficiency
3%
Aerodynamic Surface
3%
Array Data
3%
Coherence Length
3%
Modal Decomposition
3%
Cross-Section Constant
3%
Streamwise
3%
Axisymmetric
3%
Determines
3%
Acoustic Mode
3%
Flow Field
3%
Energy Production
3%
Simulation Result
3%
Empirical Model
3%
Distributed Energy
3%
Measurement Signal
3%
Boltzmann Equation
3%
Geometric Parameter
3%
Reduction
3%
Measurement Campaign
3%
Energy Engineering
3%
Physics
Acoustics
100%
Turbulent Boundary Layer
92%
Microphone
46%
Signal-to-Noise Ratio
38%
Shapes
30%
Pressure
30%
Finite Element Method
23%
Foams
23%
Impact
23%
Independent Variables
15%
Computational Fluid Dynamics
15%
Arrays
7%
Aeroacoustics
7%
Coherence
7%
Standing Wave
7%
Technology
7%
Governments
7%