Approximate boundary controllability for parabolic equations with inverse square infinite potential wells
Abstract
We consider heat operators on a bounded domain ⊂eq Rn, with a critically singular potential diverging as the inverse square of the distance to ∂ . While null boundary controllability for such operators was recently proved in all dimensions in arXiv:2112.04457, it crucially assumed (i) was convex, (ii) the control must be prescribed along all of ∂ , and (iii) the strength of the singular potential must be restricted to a particular subrange. In this article, we prove instead a definitive approximate boundary control result for these operators, in that we (i) do not assume convexity of , (ii) allow for the control to be localized near any x0 ∈ ∂ , and (iii) treat the full range of strength parameters for the singular potential. Morever, we lower the regularity required for ∂ and the lower-order coefficients. The key novelty is a local Carleman estimate near x0, with a carefully chosen weight that takes into account both the appropriate boundary conditions and the local geometry of ∂ .
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