On the Cauchy problem for the elliptic complexes in spaces of distributions

Abstract: Let D be a bounded domain in R n with a smooth boundary ∂D. We indicate appropriate Sobolev spaces of negative smoothness to study the non-homogeneous Cauchy problem for an elliptic differential complex {A i } of first order operators. In particular, we describe traces on ∂D of tangential part τ i (u) and normal part ν i (u) of a (vector)-function u from the corresponding Sobolev space and give an adequate formulation of the problem. If the Laplacians of the complex satisfy the uniqueness condition in the smal… Show more

“…Proof. Follows from [27, Theorems 2.8 and 5.2] for the case f = 0 and [6] for f = 0 because both the set S = ∂Ω where the boundary Cauchy data are defined and its complement ∂Ω b \ S = ∂Ω m are non empty and open in the relative topology.…”

“…Moreover, since the operator ∆ (b) is elliptic and its coefficients are real analytic, it admits a bilateral fundamental solutions to the operator, say ϕ b , in a neighbourhood of the compact Ω b . Let us indicate a solvability criterion and formulas for its solutions based on results from [27], [6] and [36]. With this purpose, we set…”

On the uniqueness theorems for transmissions problems related to models of elasticity, diffusion and electrocardiography

“…Proof. Follows from [27, Theorems 2.8 and 5.2] for the case f = 0 and [6] for f = 0 because both the set S = ∂Ω where the boundary Cauchy data are defined and its complement ∂Ω b \ S = ∂Ω m are non empty and open in the relative topology.…”

“…Moreover, since the operator ∆ (b) is elliptic and its coefficients are real analytic, it admits a bilateral fundamental solutions to the operator, say ϕ b , in a neighbourhood of the compact Ω b . Let us indicate a solvability criterion and formulas for its solutions based on results from [27], [6] and [36]. With this purpose, we set…”

On the uniqueness theorems for transmissions problems related to models of elasticity, diffusion and electrocardiography

“…equality the first equation in (4) is valid for U − . Formula (9) means that that the normal derivative of the volume potential G + Ω,0 (f ) is continuous if the point (x, t) passes over the surface Γ T . Therefore…”

“…He found principal ingredients, leading to the construction of integral formulas for its solution (Carleman formulas): a proper integral formula recovering the function via the data on the whole boundary, the uniqueness theorem and an effective tool, providing the analytic continuation from a domain to a larger one. This method was successfully used in the framework of Hilbert space methods to investigate the Cauchy problem for general elliptic systems of partial differential equations, see [6][7][8], and even to elliptic complexes of differential operators, see [9]. It provided both a solvability criterion and formulas for exact and approximate solutions.…”

On Carleman-type Formulas for Solutions to the Heat Equation

“…[1], [2], [3], è äð.). Íà ñàìîì äåëå îíà ÿâëÿåòñÿ òèïè÷íûì ïðèìåðîì íåêîððåêòíîé çà-äà÷è äëÿ áîëåå îáùåãî êëàññà ýëëèïòè÷åñêèõ ñèñòåì (ñì., íàïðèìåð, [4], [5], [3]) èëè äàaeå ýëëèïòè÷åñêèõ äèôôåðåíöèàëüíûõ êîìïëåêñîâ ( [6], [7]). …”

Construction of Carleman formulas by using mixed problems with parameter-dependent boundary conditions