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On using large-eddy simulation for the prediction of noise from cold and heated turbulent jets
Daniel J. Bodony
, Sanjiva K. Lele
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Keyphrases
Large Eddy Simulation
100%
Turbulent Jet
100%
Tanna
100%
Mach number
50%
Acoustics
50%
Operating Conditions
50%
Decay Rate
50%
Experimental Spectra
50%
Mean Field
50%
Existing Data
50%
Turbulent Mixing
50%
Maximum Frequency
50%
Qualitative Change
50%
Root Mean Square
50%
Temperature Conditions
50%
Low Speed
50%
Shear Layer
50%
Mean Velocity
50%
Turbulent Field
50%
Field Structure
50%
Linear Instability
50%
Jet Noise
50%
Annular Shear
50%
Velocity Decay
50%
Acoustic Frequency
50%
Stagnation Temperature
50%
Jet Mach number
50%
OASPL
50%
Sound Pressure Level Prediction
50%
Acoustic Pressure Fluctuation
50%
Heat Conditions
50%
Radiated Sound
50%
Instability Theory
50%
Engineering
Large Eddy Simulation
100%
Mach Number
100%
Limited Resolution
50%
Grid Point
50%
Acoustic Pressure
50%
Root Mean Square
50%
Pressure Fluctuation
50%
Centerline
50%
Shear Layer
50%
Sound Pressure Level
50%
Stagnation Temperature
50%
Overprediction
50%