Abstract
In this study, simulations of the laminar boundary layer response to forcing by an array of streamwise oriented plasma actuators are performed. The objective of this study is to evaluate a method to mitigate the non-minimum phase behaviour of the flow that occurs during the step response to input by the actuators. It was recently shown that when the actuators are abruptly started the non-minimum phase response of the wall shear and near-wall disturbance velocity is detected downstream of the actuators. This was shown to be caused by a secondary flow generated between the wall and the front of the tilted vortex structure that is advected downstream [1]. In the present study the step input response is compared to gradually applied inputs. For the step response, the actuators are abruptly activated for 0.2 s followed by a rest period for the flow to return to the undisturbed Blasius condition. For the gradually applied input, the body force of the actuators increases linearly from zero for either 0.005 s, 0.01 s, 0.02 s and 0.04 s to the same maximum value of the step, which simulates a reduced slew rate applied to the physical actuator. The value is held constant and then linearly decreases over a total duration of 0.2 s. It is shown the that inverse response remains for the gradually applied input. However, the peak magnitude is less for the lower ramp rates and the overall response appears more damped.
