English

Approximate controllability for linear degenerate parabolic problems with bilinear control

Analysis of PDEs 2011-06-22 v1 Systems and Control Optimization and Control

Abstract

In this work we study the global approximate multiplicative controllability for the linear degenerate parabolic Cauchy-Neumann problem {arraylvt(a(x)vx)x=α(t,x)vinQT=(0,T)×(1,1)[2.5ex]a(x)vx(t,x)x=±1=0t(0,T)[2.5ex]v(0,x)=v0(x)x(1,1),array. \{{array}{l} \displaystyle{v_t-(a(x) v_x)_x =\alpha (t,x)v\,\,\qquad {in} \qquad Q_T \,=\,(0,T)\times(-1,1)} [2.5ex] \displaystyle{a(x)v_x(t,x)|_{x=\pm 1} = 0\,\,\qquad\qquad\qquad\,\, t\in (0,T)} [2.5ex] \displaystyle{v(0,x)=v_0 (x) \,\qquad\qquad\qquad\qquad\quad\,\, x\in (-1,1)}, {array}. with the bilinear control α(t,x)L(QT).\alpha(t,x)\in L^\infty (Q_T). The problem is strongly degenerate in the sense that aC1([1,1]),a\in C^1([-1,1]), positive on (1,1),(-1,1), is allowed to vanish at ±1\pm 1 provided that a certain integrability condition is fulfilled. We will show that the above system can be steered in L2(Ω)L^2(\Omega) from any nonzero, nonnegative initial state into any neighborhood of any desirable nonnegative target-state by bilinear static controls. Moreover, we extend the above result relaxing the sign constraint on v0v_0.

Keywords

Cite

@article{arxiv.1106.4232,
  title  = {Approximate controllability for linear degenerate parabolic problems with bilinear control},
  author = {Piermarco Cannarsa and Giuseppe Floridia},
  journal= {arXiv preprint arXiv:1106.4232},
  year   = {2011}
}
R2 v1 2026-06-21T18:25:33.095Z