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Optimal growth as function of t_f (Re=2000,A=2.6,Wo=15)
The data are obtained via an in-house Matlab script (developed by Dr. Baofang Song) to compute the non-modal transient growth of disturbances in pulsatile and oscillatory pipe... -
Optimal growth as function of t_f (Re=2000,A=2.4,Wo=15)
The data are obtained via an in-house Matlab script (developed by Dr. Baofang Song) to compute the non-modal transient growth of disturbances in pulsatile and oscillatory pipe... -
Optimal wavenumber envelope (Re=2000,A=1,Wo=15)
The data are obtained via an in-house Matlab script (developed by Dr. Baofang Song) to compute the non-modal transient growth of disturbances in pulsatile and oscillatory pipe... -
Optimal growth envelope (Re=2000,A=1,Wo=15)
The data are obtained via an in-house Matlab script (developed by Dr. Baofang Song) to compute the non-modal transient growth of disturbances in pulsatile and oscillatory pipe... -
Optimal perturbation (helical, Re=2000,A=1,Wo=15): kinetic energy components ...
The data are obtained via an in-house Matlab script (developed by Dr. Baofang Song) to compute the non-modal transient growth of disturbances in pulsatile and oscillatory pipe... -
Optimal perturbation (classic, Re=2000,A=1,Wo=15): energy components time series
The data are obtained via an in-house Matlab script (developed by Dr. Baofang Song) to compute the non-modal transient growth of disturbances in pulsatile and oscillatory pipe... -
Optimal perturbation (helical, Re=2000,A=1,Wo=15): Time series of the r-theta...
Laminar flows through pipes driven at steady, pulsatile or oscillatory rates undergo a subcritical transition to turbulence. We carry out an extensive linear non-modal stability... -
Optimal perturbation (classic, Re=2000,A=1,Wo=15): Time series of the r-theta...
Laminar flows through pipes driven at steady, pulsatile or oscillatory rates undergo a subcritical transition to turbulence. We carry out an extensive linear non-modal stability...
