The performance of an active feedback control with wall deformation was tes
ted by direct numerical simulation of a fully developed turbulent channel f
low. The local wall movement is determined based on the flow condition dete
cted by virtual sensors distributed in the vicinity of the wall, i.e., the
wall velocity is made opposite to the wall normal velocity at y/delta =0.1.
The turbulent friction drag is reduced by 10% on average. The gain in the
pumping power reaches about 28 times the energy consumption for actuating t
he wall. The primary mode of the resultant wall velocity distribution, whic
h should be most: effective in the present drag reduction scheme, is found
to have wavelengths of about 300 and 50 viscous wall units in the streamwis
e and spanwise directions, respectively, while the time period is of the or
der of the time scale of the quasi-coherent vortical structure of near-wall
turbulence. The effects of active wall deformation on quasi-coherent struc
tures are investigated by a conditional averaging technique. in the present
control scheme, the Q2 vortex is displaced away from the wall and the wall
-normal and spanwise velocity fluctuations associated with the Q2 event are
decreased. On the other hand, the location of the Q4 vortex from the wall
remains unchanged while the vorticity of the Q4 vortex is substantially dec
reased. In the region downstream of the Q2 event, the wall is deformed in t
he shape of a shallow groove, which stabilizes the near-wall streaky struct
ures along the groove.