Neumann Boundary Controllability of the Gear--Grimshaw System With Critical Size Restrictions on the Spacial Domain

Abstract

In this paper we study the boundary controllability of the Gear-Grimshaw system posed on a finite domain (0,L), with Neumann boundary conditions: equation abs cases ut + uux+uxxx + a vxxx + a1vvx+a2 (uv)x =0, & in \,\, (0,L)× (0,T), c vt +rvx +vvx+abuxxx +vxxx+a2buux+a1b(uv)x =0, & in \,\, (0,L)× (0,T), uxx(0,t)=h0(t),\,\,ux(L,t)=h1(t),\,\,uxx(L,t)=h2(t), & in \,\, (0,T), vxx(0,t)=g0(t),\,\,vx(L,t)=g1(t),\,\,vxx(L,t)=g2(t), & in \,\, (0,T), u(x,0)= u0(x), v(x,0)= v0(x), & in \,\, (0,L). cases equation We first prove that the corresponding linearized system around the origin is exactly controllable in (L2(0,L))2 when h2(t)=g2(t)=0. In this case, the exact controllability property is derived for any L>0 with control functions h0, g0∈ H-13(0,T) and h1, g1∈ L2(0,T). If we change the position of the controls and consider h0(t)=h2(t)=0 (resp. g0(t)=g2(t)=0) we obtain the result with control functions g0, g2∈ H-13(0,T) and h1, g1∈ L2(0,T) if and only if the length L of the spatial domain (0,L) belongs to a countable set. In all cases the regularity of the controls are sharp in time. If only one control act in the boundary condition, h0(t)=g0(t)=h2(t)=g2(t)=0 and g1(t)=0 (resp. h1(t)=0), the linearized system is proved to be exactly controllable for small values of the length L and large time of control T. Finally, the nonlinear system is shown to be locally exactly controllable via the contraction mapping principle, if the associated linearized systems are exactly controllable.