"Sassi, Taoufik" . . . "http://link.springer.com/article/10.1007%2Fs10492-014-0077-z" . . "10.1007/s10492-014-0077-z" . "24620" . . "Shape Optimization for Stokes Problem with Threshold Slip" . . "I, N, P(GA201/09/0917), P(GAP201/12/0671)" . "Stebel, Jan" . "Haslinger, Jaroslav" . . "6" . . . "RIV/46747885:24620/14:#0000667" . . . "[0B0EDA1EC73C]" . . . "Stokes problem; friction boundary condition; shape optimization"@en . "CZ - \u010Cesk\u00E1 republika" . . "44693" . "Applications of Mathematics" . . "1"^^ . . . . "3"^^ . "Shape Optimization for Stokes Problem with Threshold Slip"@en . . "Shape Optimization for Stokes Problem with Threshold Slip"@en . "00034508910" . "22"^^ . "RIV/46747885:24620/14:#0000667!RIV15-MSM-24620___" . "We study the Stokes problems in a bounded planar domain Omega with a friction type boundary condition that switches between a slip and no-slip stage. Our main goal is to determine under which conditions concerning smoothness of Omega , solutions to the Stokes system with the slip boundary conditions depend continuously on variations of Omega. Having this result at our disposal, we easily prove the existence of a solution to optimal shape design problems for a large class of cost functionals. In order to release the impermeability condition, whose numerical treatment could be troublesome, we use a penalty approach. We introduce a family of shape optimization problems with the penalized state relations. Finally we establish convergence properties between solutions to the original and modified shape optimization problems when the penalty parameter tends to zero." . "Shape Optimization for Stokes Problem with Threshold Slip" . "59" . "0862-7940" . "We study the Stokes problems in a bounded planar domain Omega with a friction type boundary condition that switches between a slip and no-slip stage. Our main goal is to determine under which conditions concerning smoothness of Omega , solutions to the Stokes system with the slip boundary conditions depend continuously on variations of Omega. Having this result at our disposal, we easily prove the existence of a solution to optimal shape design problems for a large class of cost functionals. In order to release the impermeability condition, whose numerical treatment could be troublesome, we use a penalty approach. We introduce a family of shape optimization problems with the penalized state relations. Finally we establish convergence properties between solutions to the original and modified shape optimization problems when the penalty parameter tends to zero."@en .