Affine section tomography for inverse source problems in k-Hessian equations with restricted large boundary data

Abstract

We consider an inverse source problem for the k-Hessian equation equation* σk(D2u)=f(x) equation* on the k-admissible branch in a smooth uniformly convex domain in Rn, where 2 k n. We prove that the nonlinear Dirichlet-to-Neumann map determines the positive smooth source from its values on the restricted large-data rays tϕE|∂Ω, where E∈ Gr(k-1,n), ϕE(x)=|PEx|2/2, and t is sufficiently large. The Hessian of each boundary profile has exactly k-1 large directions and is flat on V=E. Thus, the leading profile lies on a rank k-1 face of the k-Hessian structure, and the first source-dependent correction is governed by the missing directions. More precisely, this correction solves fiberwise Poisson equations on the affine sections Ω(y+V) of dimension q=n-k+1. We prove that these sectionwise solutions patch smoothly through glancing points where the sections collapse, and we obtain boundary normal derivative asymptotics by local barriers. The boundary flux of the correction gives the section integrals ∫Ω(y+V)f\,d Hq. Varying E yields the affine q-plane Radon transform of the zero extension of f. We give an explicit reconstruction formula through the Fourier slice identity, and the injectivity of the affine Radon transform gives uniqueness. The endpoint k=n recovers the Monge--Ampère chord/X-ray geometry, while the range n3 and 2 k<n gives inverse source results for genuinely non-determinant Hessian equations.

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