Explorative gradient method for active drag reduction of the fluidic pinball and slanted Ahmed body

Abstract

We address a challenge of active flow control: the optimization of many actuation parameters guaranteeing fast convergence and avoiding suboptimal local minima. This challenge is addressed by a new optimizer, called explorative gradient method (EGM). EGM alternatively performs one exploitive downhill simplex step and an explorative Latin hypercube sampling iteration. Thus, the convergence rate of a gradient based method is guaranteed while, at the same time, better minima are explored. For an analytical multi-modal test function, EGM is shown to significantly outperform the downhill simplex method, the random restart variant, Latin hypercube sampling, Monte Carlo iterations and the genetic algorithm. EGM is applied to minimize the net drag power of the two-dimensional fluidic pinball benchmark with three cylinder rotations as actuation parameters. The net drag power is reduced by 40\% employing direct numerical simulations at a Reynolds number of 100 based on the cylinder diameter. This optimal actuation leads to 98\% drag reduction employing Coanda forcing for boat tailing and partial stabilization of vortex shedding. The price is an actuation energy corresponding to 58\% of the unforced parasitic drag power. EGM is also used to minimize drag of the 35 slanted Ahmed body employing distributed steady blowing with 10 inputs. 17\% drag reduction are achieved using Reynolds-Averaged Navier-Stokes simulations (RANS) at the Reynolds number ReH=1.9 × 105 based on the height of the Ahmed body. The optimal actuation emulates boat tailing by inward-directed blowing with velocities which are comparable to the oncoming velocity. We expect that EGM will be employed as efficient optimizer in many future active flow control plants.