In mathematics, Sobolev spaces for planar domains are one of the principal techniques used in the theory of partial differential equations for solving the Dirichlet and Neumann boundary value problems for the Laplacian in a bounded domain in the plane with smooth boundary. The methods use the theory of bounded operators on Hilbert space. They can be used to deduce regularity properties of solutions and to solve the corresponding eigenvalue problems.
Sobolev spaces with boundary conditions
Let Ω ⊂ R2 be a bounded domain with smooth boundary. Since Ω is contained in a large square in R2, it can be regarded as a domain in T2 by identifying opposite sides of the square. The theory of Sobolev spaces on T2 can be found in Bers, John & Schechter (1979), an account which is followed in several later textbooks such as Warner (1983) and Griffiths & Harris (1994).
For k an integer, the (restricted) Sobolev spaceHk 0(Ω) is defined as the closure of C∞ c(Ω) in the standard Sobolev spaceHk(T2).
H0 0(Ω) = L2(Ω).
Vanishing properties on boundary: For k > 0 the elements of Hk 0(Ω) are referred to as "L2 functions on Ω which vanish with their first k − 1 derivatives on ∂Ω."[1] In fact if f ∈ Ck(Ω) agrees with a function in Hk 0(Ω), then g = ∂αf is in C1. Let fn ∈ C∞ c(Ω) be such that fn → f in the Sobolev norm, and set gn = ∂αfn. Thus gn → g in H1 0(Ω). Hence for h ∈ C∞(T2) and D = a∂x + b∂y,
with n the unit normal to the boundary. Since such k form a dense subspace of L2(Ω), it follows that g = 0 on ∂Ω.
Support properties: Let Ωc be the complement of Ω and define restricted Sobolev spaces analogously for Ωc. Both sets of spaces have a natural pairing with C∞(T2). The Sobolev space for Ω is the annihilator in the Sobolev space for T2 of C∞ c(Ωc) and that for Ωc is the annihilator of C∞ c(Ω).[2] In fact this is proved by locally applying a small translation to move the domain inside itself and then smoothing by a smooth convolution operator.
Suppose g in Hk(T2) annihilates C∞ c(Ωc). By compactness, there are finitely many open sets U0, U1, ... , UN covering Ω such that the closure of U0 is disjoint from ∂Ω and each Ui is an open disc about a boundary point zi such that in Ui small translations in the direction of the normal vector ni carry Ω into Ω. Add an open UN+1 with closure in Ωc to produce a cover of T2 and let ψi be a partition of unity subordinate to this cover. If translation by n is denoted by λn, then the functions
tend to g as t decreases to 0 and still lie in the annihilator, indeed they are in the annihilator for a larger domain than Ωc, the complement of which lies in Ω. Convolving by smooth functions of small support produces smooth approximations in the annihilator of a slightly smaller domain still with complement in Ω. These are necessarily smooth functions of compact support in Ω.
Further vanishing properties on the boundary: The characterization in terms of annihilators shows that f ∈ Ck(Ω) lies in Hk 0(Ω) if (and only if) it and its derivatives of order less than k vanish on ∂Ω.[3] In fact f can be extended to T2 by setting it to be 0 on Ωc. This extension F defines an element in Hk(T2) using the formula for the norm
Moreover F satisfies (F, g) = 0 for g in C∞ c(Ωc).
Duality: For k ≥ 0, define H−k(Ω) to be the orthogonal complement of H−k 0(Ωc) in H−k(T2). Let Pk be the orthogonal projection onto H−k(Ω), so that Qk = I − Pk is the orthogonal projection onto H−k 0(Ωc). When k = 0, this just gives H0(Ω) = L2(Ω). If f ∈ Hk 0(Ωc) and g ∈ H−k(T2), then
This implies that under the pairing between Hk(T2) and H−k(T2), Hk 0(Ωc) and H−k(Ω) are each other's duals.
Approximation by smooth functions: The image of C∞ c(Ω) is dense in H−k(Ω) for k ≤ 0. This is obvious for k = 0 since the sum C∞ c(Ω) + C∞ c(Ωc) is dense in L2(T2). Density for k < 0 follows because the image of L2(T2) is dense in H−k(T2) and Pk annihilates C∞ c(Ωc).
Canonical isometries: The operator (I + ∆)k gives an isometry of H 2k 0(Ω) into H0(Ω) and of Hk 0(Ω) onto H−k(Ω). In fact the first statement follows because it is true on T2. That (I + ∆)k is an isometry on Hk 0(Ω) follows using the density of C∞ c(Ω) in H−k(Ω): for f, g ∈ C∞ c(Ω) we have:
Since the adjoint map between the duals can by identified with this map, it follows that (I + ∆)k is a unitary map.
The operator ∆ defines an isomorphism between H1 0(Ω) and H−1(Ω). In fact it is a Fredholm operator of index 0. The kernel of ∆ in H1(T2) consists of constant functions and none of these except zero vanish on the boundary of Ω. Hence the kernel of H1 0(Ω) is (0) and ∆ is invertible.
In particular the equation ∆f = g has a unique solution in H1 0(Ω) for g in H−1(Ω).
Eigenvalue problem
Let T be the operator on L2(Ω) defined by
where R0 is the inclusion of L2(Ω) in H−1(Ω) and R1 of H1 0(Ω) in L2(Ω), both compact operators by Rellich's theorem. The operator T is compact and self-adjoint with (Tf, f ) > 0 for all f. By the spectral theorem, there is a complete orthonormal set of eigenfunctionsfn in L2(Ω) with
Since μn > 0, fn lies in H1 0(Ω). Setting λn = μ−n, the fn are eigenfunctions of the Laplacian:
Sobolev spaces without boundary condition
To determine the regularity properties of the eigenfunctions fn and solutions of
enlargements of the Sobolev spaces Hk 0(Ω) have to be considered. Let C∞(Ω−) be the space of smooth functions on Ω which with their derivatives extend continuously to Ω. By Borel's lemma, these are precisely the restrictions of smooth functions on T2. The Sobolev space Hk(Ω) is defined to the Hilbert space completion of this space for the norm
This norm agrees with the Sobolev norm on C∞ c(Ω) so that Hk 0(Ω) can be regarded as a closed subspace of Hk(Ω). Unlike Hk 0(Ω), Hk(Ω) is not naturally a subspace of Hk(T2), but the map restricting smooth functions from T2 to Ω is continuous for the Sobolev norm so extends by continuity to a map ρk : Hk(T2) → Hk(Ω).
Invariance under diffeomorphism: Any diffeomorphism between the closures of two smooth domains induces an isomorphism between the Sobolev space. This is a simple consequence of the chain rule for derivatives.
Extension theorem: The restriction of ρk to the orthogonal complement of its kernel defines an isomorphism onto Hk(Ω). The extension map Ek is defined to be the inverse of this map: it is an isomorphism (not necessarily norm preserving) of Hk(Ω) onto the orthogonal complement of Hk 0(Ωc) such that ρk ∘ Ek = I. On C∞ c(Ω), it agrees with the natural inclusion map. Bounded extension maps Ek of this kind from Hk(Ω) to Hk(T2) were constructed first constructed by Hestenes and Lions. For smooth curves the Seeley extension theorem provides an extension which is continuous in all the Sobolev norms. A version of the extension which applies in the case where the boundary is just a Lipschitz curve was constructed by Calderón using singular integral operators and generalized by Stein (1970).
It is sufficient to construct an extension E for a neighbourhood of a closed annulus, since a collar around the boundary is diffeomorphic to an annulus I × T with I a closed interval in T. Taking a smooth bump function ψ with 0 ≤ ψ ≤ 1, equal to 1 near the boundary and 0 outside the collar, E(ψf ) + (1 − ψ) f will provide an extension on Ω. On the annulus, the problem reduces to finding an extension for Ck( I ) in Ck(T). Using a partition of unity the task of extending reduces to a neighbourhood of the end points of I. Assuming 0 is the left end point, an extension is given locally by
Matching the first derivatives of order k or less at 0, gives
This matrix equation is solvable because the determinant is non-zero by Vandermonde's formula. It is straightforward to check that the formula for E( f ), when appropriately modified with bump functions, leads to an extension which is continuous in the above Sobolev norm.[4]
Restriction theorem: The restriction map ρk is surjective with ker ρk = Hk 0(Ωc). This is an immediate consequence of the extension theorem and the support properties for Sobolev spaces with boundary condition.
Duality:Hk(Ω) is naturally the dual of H−k0(Ω). Again this is an immediate consequence of the restriction theorem. Thus the Sobolev spaces form a chain:
The differentiation operators ∂x, ∂y carry each Sobolev space into the larger one with index 1 less.
Sobolev embedding theorem:Hk+2(Ω) is contained in Ck(Ω−). This is an immediate consequence of the extension theorem and the Sobolev embedding theorem for Hk+2(T2).
Characterization:Hk(Ω) consists of f in L2(Ω) = H0(Ω) such that all the derivatives ∂αf lie in L2(Ω) for |α| ≤ k. Here the derivatives are taken within the chain of Sobolev spaces above.[5] Since C∞ c(Ω) is weakly dense in Hk(Ω), this condition is equivalent to the existence of L2 functions fα such that
To prove the characterization, note that if f is in Hk(Ω), then ∂αf lies in Hk−|α|(Ω) and hence in H0(Ω) = L2(Ω). Conversely the result is well known for the Sobolev spaces Hk(T2): the assumption implies that the (∂x − i∂y)kf is in L2(T2) and the corresponding condition on the Fourier coefficients of f shows that f lies in Hk(T2). Similarly the result can be proved directly for an annulus [−δ, δ] × T. In fact by the argument on T2 the restriction of f to any smaller annulus [−δ',δ'] × T lies in Hk: equivalently the restriction of the function fR (x, y) = f (Rx, y) lies in Hk for R > 1. On the other hand ∂αfR → ∂αf in L2 as R → 1, so that f must lie in Hk. The case for a general domain Ω reduces to these two cases since f can be written as f = ψf + (1 − ψ) f with ψ a bump function supported in Ω such that 1 − ψ is supported in a collar of the boundary.
Regularity theorem: If f in L2(Ω) has both derivatives ∂xf and ∂yf in Hk(Ω) then f lies in Hk+1(Ω). This is an immediate consequence of the characterization of Hk(Ω) above. In fact if this is true even when satisfied at the level of distributions: if there are functions g, h in Hk(Ω) such that (g,φ) = (f, φx) and (h,φ) = (f,φy) for φ in C∞ c(Ω), then f is in Hk+1(Ω).
Rotations on an annulus: For an annulus I × T, the extension map to T2 is by construction equivariant with respect to rotations in the second variable,
On T2 it is known that if f is in Hk, then the difference quotientδh f = h−1(Rh f − f ) → ∂yf in Hk−1; if the difference quotients are bounded in Hk then ∂yf lies in Hk. Both assertions are consequences of the formula:
These results on T2 imply analogous results on the annulus using the extension.
Regularity for Dirichlet problem
Regularity for dual Dirichlet problem
If ∆u = f with u in H1 0(Ω) and f in Hk−1(Ω) with k ≥ 0, then u lies in Hk+1(Ω).
Take a decomposition u = ψu + (1 − ψ)u with ψ supported in Ω and 1 − ψ supported in a collar of the boundary. Standard Sobolev theory for T2 can be applied to ψu: elliptic regularity implies that it lies in Hk+1(T2) and hence Hk+1(Ω). v = (1 − ψ)u lies in H1 0 of a collar, diffeomorphic to an annulus, so it suffices to prove the result with Ω a collar and ∆ replaced by
The proof[6] proceeds by induction on k, proving simultaneously the inequality
for some constant C depending only on k. It is straightforward to establish this inequality for k = 0, where by density u can be taken to be smooth of compact support in Ω:
The collar is diffeomorphic to an annulus. The rotational flow Rt on the annulus induces a flow St on the collar with corresponding vector field Y = r∂x + s∂y. Thus Y corresponds to the vector field ∂θ. The radial vector field on the annulus r∂r is a commuting vector field which on the collar gives a vector field Z = p∂x + q∂y proportional to the normal vector field. The vector fields Y and Z commute.
The difference quotients δhu can be formed for the flow St. The commutators [δh, ∆1] are second order differential operators from Hk+1(Ω) to Hk−1(Ω). Their operators norms are uniformly bounded for h near 0; for the computation can be carried out on the annulus where the commutator just replaces the coefficients of ∆1 by their difference quotients composed with Sh. On the other hand, v = δhu lies in H1 0(Ω), so the inequalities for u apply equally well for v:
The uniform boundedness of the difference quotients δhu implies that Yu lies in Hk+1(Ω) with
It follows that Vu lies in Hk+1(Ω) where V is the vector field
Moreover, Vu satisfies a similar inequality to Yu.
Let W be the orthogonal vector field
It can also be written as ξZ for some smooth nowhere vanishing function ξ on a neighbourhood of the collar.
It suffices to show that Wu lies in Hk+1(Ω). For then
so that ∂xu and ∂yu lie in Hk+1(Ω) and u must lie in Hk+2(Ω).
To check the result on Wu, it is enough to show that VWu and W2u lie in Hk(Ω). Note that
are vector fields. But then
with all terms on the right hand side in Hk(Ω). Moreover, the inequalities for Vu show that
Hence
Smoothness of eigenfunctions
It follows by induction from the regularity theorem for the dual Dirichlet problem that the eigenfunctions of ∆ in H1 0(Ω) lie in C∞(Ω−). Moreover, any solution of ∆u = f with f in C∞(Ω−) and u in H1 0(Ω) must have u in C∞(Ω−). In both cases by the vanishing properties, the eigenfunctions and u vanish on the boundary of Ω.
Solving the Dirichlet problem
The dual Dirichlet problem can be used to solve the Dirichlet problem:
By Borel's lemma g is the restriction of a function G in C∞(Ω−). Let F be the smooth solution of ∆F = ∆G with F = 0 on ∂Ω. Then f = G − F solves the Dirichlet problem. By the maximal principle, the solution is unique.[7]
Application to smooth Riemann mapping theorem
The solution to the Dirichlet problem can be used to prove a strong form of the Riemann mapping theorem for simply connected domains with smooth boundary. The method also applies to a region diffeomorphic to an annulus.[8] For multiply connected regions with smooth boundary Schiffer & Hawley (1962) have given a method for mapping the region onto a disc with circular holes. Their method involves solving the Dirichlet problem with a non-linear boundary condition. They construct a function g such that:
g is harmonic in the interior of Ω;
On ∂Ω we have: ∂ng = κ − KeG, where κ is the curvature of the boundary curve, ∂n is the derivative in the direction normal to ∂Ω and K is constant on each boundary component.
Taylor (2011) gives a proof of the Riemann mapping theorem for a simply connected domain Ω with smooth boundary. Translating if necessary, it can be assumed that 0 ∈ Ω. The solution of the Dirichlet problem shows that there is a unique smooth function U(z) on Ω which is harmonic in Ω and equals −log|z| on ∂Ω. Define the Green's function by G(z) = log|z| + U(z). It vanishes on ∂Ω and is harmonic on Ω away from 0. The harmonic conjugateV of U is the unique real function on Ω such that U + iV is holomorphic. As such it must satisfy the Cauchy–Riemann equations:
The solution is given by
where the integral is taken over any path in Ω. It is easily verified that Vx and Vy exist and are given by the corresponding derivatives of U. Thus V is a smooth function on Ω, vanishing at 0. By the Cauchy-Riemann f = U + iV is smooth on Ω, holomorphic on Ω and f (0) = 0. The function H = arg z + V(z) is only defined up to multiples of 2π, but the function
is a holomorphic on Ω and smooth on Ω. By construction, F(0) = 0 and |F(z)| = 1 for z ∈ ∂Ω. Since z has winding number1, so too does F(z). On the other hand, F(z) = 0 only for z = 0 where there is a simple zero. So by the argument principleF assumes every value in the unit disc, D, exactly once and F′ does not vanish inside Ω. To check that the derivative on the boundary curve is non-zero amounts to computing the derivative of eiH, i.e. the derivative of H should not vanish on the boundary curve. By the Cauchy-Riemann equations these tangential derivative are up to a sign the directional derivative in the direction of the normal to the boundary. But G vanishes on the boundary and is strictly negative in Ω since |F| = eG. The Hopf lemma implies that the directional derivative of G in the direction of the outward normal is strictly positive. So on the boundary curve, F has nowhere vanishing derivative. Since the boundary curve has winding number one, F defines a diffeomorphism of the boundary curve onto the unit circle. Accordingly, F : Ω → D is a smooth diffeomorphism, which restricts to a holomorphic map Ω → D and a smooth diffeomorphism between the boundaries.
Similar arguments can be applied to prove the Riemann mapping theorem for a doubly connected domain Ω bounded by simple smooth curves Ci (the inner curve) and Co (the outer curve). By translating we can assume 1 lies on the outer boundary. Let u be the smooth solution of the Dirichlet problem with U = 0 on the outer curve and −1 on the inner curve. By the maximum principle0 < u(z) < 1 for z in Ω and so by the Hopf lemma the normal derivatives of u are negative on the outer curve and positive on the inner curve. The integral of −uydx + uydx over the boundary is zero by Stokes' theorem so the contributions from the boundary curves cancel. On the other hand, on each boundary curve the contribution is the integral of the normal derivative along the boundary. So there is a constant c > 0 such that U = cu satisfies
on each boundary curve. The harmonic conjugate V of U can again be defined by
and is well-defined up to multiples of 2π. The function
is smooth on Ω and holomorphic in Ω. On the outer curve |F| = 1 and on the inner curve |F| = e−c = r < 1. The tangential derivatives on the outer curves are nowhere vanishing by the Cauchy-Riemann equations, since the normal derivatives are nowhere vanishing. The normalization of the integrals implies that F restricts to a diffeomorphism between the boundary curves and the two concentric circles. Since the images of outer and inner curve have winding number 1 and 0 about any point in the annulus, an application of the argument principle implies that F assumes every value within the annulus r < |z| < 1 exactly once; since that includes multiplicities, the complex derivative of F is nowhere vanishing in Ω. This F is a smooth diffeomorphism of Ω onto the closed annulus r ≤ |z| ≤ 1, restricting to a holomorphic map in the interior and a smooth diffeomorphism on both boundary curves.
Trace map
The restriction map τ : C∞(T2) → C∞(T) = C∞(1 × T) extends to a continuous map Hk(T2) → Hk − 1/2(T) for k ≥ 1.[9] In fact
The map τ is onto since a continuous extension map E can be constructed from Hk − 1/2(T) to Hk(T2).[10][11] In fact set
where
Thus ck < λn < Ck. If g is smooth, then by construction Eg restricts to g on 1 × T. Moreover, E is a bounded linear map since
It follows that there is a trace map τ of Hk(Ω) onto Hk − 1/2(∂Ω). Indeed, take a tubular neighbourhood of the boundary and a smooth function ψ supported in the collar and equal to 1 near the boundary. Multiplication by ψ carries functions into Hk of the collar, which can be identified with Hk of an annulus for which there is a trace map. The invariance under diffeomorphisms (or coordinate change) of the half-integer Sobolev spaces on the circle follows from the fact that an equivalent norm on Hk + 1/2(T) is given by[12]
It is also a consequence of the properties of τ and E (the "trace theorem").[13] In fact any diffeomorphism f of T induces a diffeomorphism F of T2 by acting only on the second factor. Invariance of Hk(T2) under the induced map F* therefore implies invariance of Hk − 1/2(T) under f*, since f* = τ ∘ F* ∘ E.
Further consequences of the trace theorem are the two exact sequences[14][15]
and
where the last map takes f in H2(Ω) to f|∂Ω and ∂nf|∂Ω. There are generalizations of these sequences to Hk(Ω) involving higher powers of the normal derivative in the trace map:
The trace map to Hj − 1/2(∂Ω) takes f to ∂k − j nf |∂Ω
Abstract formulation of boundary value problems
The Sobolev space approach to the Neumann problem cannot be phrased quite as directly as that for the Dirichlet problem. The main reason is that for a function f in H1(Ω), the normal derivative ∂nf |∂Ω cannot be a priori defined at the level of Sobolev spaces. Instead an alternative formulation of boundary value problems for the Laplacian Δ on a bounded region Ω in the plane is used. It employs Dirichlet forms, sesqulinear bilinear forms on H1(Ω), H1 0(Ω) or an intermediate closed subspace. Integration over the boundary is not involved in defining the Dirichlet form. Instead, if the Dirichlet form satisfies a certain positivity condition, termed coerciveness, solution can be shown to exist in a weak sense, so-called "weak solutions". A general regularity theorem than implies that the solutions of the boundary value problem must lie in H2(Ω), so that they are strong solutions and satisfy boundary conditions involving the restriction of a function and its normal derivative to the boundary. The Dirichlet problem can equally well be phrased in these terms, but because the trace map f |∂Ω is already defined on H1(Ω), Dirichlet forms do not need to be mentioned explicitly and the operator formulation is more direct. A unified discussion is given in Folland (1995) and briefly summarised below. It is explained how the Dirichlet problem, as discussed above, fits into this framework. Then a detailed treatment of the Neumann problem from this point of view is given following Taylor (2011).
The Hilbert space formulation of boundary value problems for the Laplacian Δ on a bounded region Ω in the plane proceeds from the following data:[16]
A closed subspace H1 0(Ω) ⊆ H ⊆ H1(Ω).
A Dirichlet form for Δ given by a bounded Hermitian bilinear form D( f, g) defined for f, g ∈ H1(Ω) such that D( f, g) = (∆f, g) for f, g ∈ H1 0(Ω).
D is coercive, i.e. there is a positive constant C and a non-negative constant λ such that D( f, f ) ≥ C ( f, f )(1) − λ( f, f ).
A weak solution of the boundary value problem given initial data f in L2(Ω) is a function u satisfying
for all g.
For both the Dirichlet and Neumann problem
For the Dirichlet problem H = H1 0(Ω). In this case
By the trace theorem the solution satisfies u|Ω = 0 in H1/2(∂Ω).
For the Neumann problem H is taken to be H1(Ω).
Application to Neumann problem
The classical Neumann problem on Ω consists in solving the boundary value problem
Thus if Δu = 0 in Ω and satisfies the Neumann boundary conditions, ux = uy = 0, and so u is constant in Ω.
Hence the Neumann problem has a unique solution up to adding constants.[17]
Consider the Hermitian form on H1(Ω) defined by
Since H1(Ω) is in duality with H−1 0(Ω), there is a unique element Lu in H−1 0(Ω) such that
The map I + L is an isometry of H1(Ω) onto H−1 0(Ω), so in particular L is bounded.
In fact
So
On the other hand, any f in H−1 0(Ω) defines a bounded conjugate-linear form on H1(Ω) sending v to ( f, v). By the Riesz–Fischer theorem, there exists u ∈ H1(Ω) such that
Hence (L + I)u = f and so L + I is surjective. Define a bounded linear operator T on L2(Ω) by
where R1 is the map H1(Ω) → L2(Ω), a compact operator, and R0 is the map L2(Ω) → H−1 0(Ω), its adjoint, so also compact.
The operator T has the following properties:
T is a contraction since it is a composition of contractions
T is compact, since R0 and R1 are compact by Rellich's theorem
T is self-adjoint, since if f, g ∈ L2(Ω), they can be written f = (L + I)u, g = (L + I)v with u, v ∈ H1(Ω) so
T has positive spectrum and kernel (0), for
and Tf = 0 implies u = 0 and hence f = 0.
There is a complete orthonormal basis fn of L2(Ω) consisting of eigenfunctions of T. Thus
with 0 < μn ≤ 1 and μn decreasing to 0.
The eigenfunctions all lie in H1(Ω) since the image of T lies in H1(Ω).
The fn are eigenfunctions of L with
Thus λn are non-negative and increase to ∞.
The eigenvalue 0 occurs with multiplicity one and corresponds to the constant function. For if u ∈ H1(Ω) satisfies Lu = 0, then
so u is constant.
Regularity for Neumann problem
Weak solutions are strong solutions
The first main regularity result shows that a weak solution expressed in terms of the operator L and the Dirichlet form D is a strong solution in the classical sense, expressed in terms of the Laplacian Δ and the Neumann boundary conditions. Thus if u = Tf with u ∈ H1(Ω), f ∈ L2(Ω), then u ∈ H2(Ω), satisfies Δu + u = f and ∂nu|∂Ω = 0. Moreover, for some constant C independent of u,
Note that
since
Take a decomposition u = ψu + (1 − ψ)u with ψ supported in Ω and 1 − ψ supported in a collar of the boundary.
The operator L is characterized by
Then
so that
The function v = ψu and w = (1 − ψ)u are treated separately, v being essentially subject to usual elliptic regularity considerations for interior points while w requires special treatment near the boundary using difference quotients. Once the strong properties are established in terms of ∆ and the Neumann boundary conditions, the "bootstrap" regularity results can be proved exactly as for the Dirichlet problem.
Interior estimates
The function v = ψu lies in H1 0(Ω1) where Ω1 is a region with closure in Ω. If f ∈ C∞ c(Ω) and g ∈ C∞(Ω−)
By continuity the same holds with f replaced by v and hence Lv = ∆v. So
Hence regarding v as an element of H1(T2), ∆v ∈ L2(T2). Hence v ∈ H2(T2). Since v = φv for φ ∈ C∞ c(Ω), we have v ∈ H2 0(Ω). Moreover,
so that
Boundary estimates
The function w = (1 − ψ)u is supported in a collar contained in a tubular neighbourhood of the boundary. The difference quotients δhw can be formed for the flow St and lie in H1(Ω), so the first inequality is applicable:
The commutators [L, δh] are uniformly bounded as operators from H1(Ω) to H−1 0(Ω). This is equivalent to checking the inequality
for g, h smooth functions on a collar. This can be checked directly on an annulus, using invariance of Sobolev spaces under dffeomorphisms and the fact that for the annulus the commutator of δh with a differential operator is obtained by applying the difference operator to the coefficients after having applied Rh to the function:[18]
Hence the difference quotients δhw are uniformly bounded, and therefore Yw ∈ H1(Ω) with
Hence Vw ∈ H1(Ω) and Vw satisfies a similar inequality to Yw:
Let W be the orthogonal vector field. As for the Dirichlet problem, to show that w ∈ H2(Ω), it suffices to show that Ww ∈ H1(Ω).
To check this, it is enough to show that VWw, W 2u ∈ L2(Ω). As before
are vector fields. On the other hand, (Lw, φ) = (∆w, φ) for φ ∈ C∞ c(Ω), so that Lw and ∆w define the same distribution on Ω. Hence
Since the terms on the right hand side are pairings with functions in L2(Ω), the regularity criterion shows that Ww ∈ H2(Ω). Hence Lw = ∆w since both terms lie in L2(Ω) and have the same inner products with φ's.
Moreover, the inequalities for Vw show that
Hence
It follows that u = v + w ∈ H2(Ω). Moreover,
Neumann boundary conditions
Since u ∈ H2(Ω), Green's theorem is applicable by continuity. Thus for v ∈ H1(Ω),
Hence the Neumann boundary conditions are satisfied:
where the left hand side is regarded as an element of H1/2(∂Ω) and hence L2(∂Ω).
Regularity of strong solutions
The main result here states that if u ∈ Hk+1 (k ≥ 1), ∆u ∈ Hk and ∂nu|∂Ω = 0, then u ∈ Hk+2 and
for some constant independent of u.
Like the corresponding result for the Dirichlet problem, this is proved by induction on k ≥ 1. For k = 1, u is also a weak solution of the Neumann problem so satisfies the estimate above for k = 0. The Neumann boundary condition can be written
Since Z commutes with the vector field Y corresponding to the period flow St, the inductive method of proof used for the Dirichlet problem works equally well in this case: for the difference quotients δh preserve the boundary condition when expressed in terms of Z.[19]
Smoothness of eigenfunctions
It follows by induction from the regularity theorem for the Neumann problem that the eigenfunctions of D in H1(Ω) lie in C∞(Ω−). Moreover, any solution of Du = f with f in C∞(Ω−) and u in H1(Ω) must have u in C∞(Ω−). In both cases by the vanishing properties, the normal derivatives of the eigenfunctions and u vanish on ∂Ω.
Solving the associated Neumann problem
The method above can be used to solve the associated Neumann boundary value problem:
By Borel's lemma g is the restriction of a function G ∈ C∞(Ω−). Let F be a smooth function such that ∂nF = G near the boundary. Let u be the solution of ∆u = −∆F with ∂nu = 0. Then f = u + F solves the boundary value problem.[20]
Bers, Lipman; John, Fritz; Schechter, Martin (1979), Partial differential equations, with supplements by Lars Gårding and A. N. Milgram, Lectures in Applied Mathematics, vol. 3A, American Mathematical Society, ISBN0-8218-0049-3
Stein, Elias M. (1970), Singular Integrals and Differentiability Properties of Functions, Princeton University Press
Greene, Robert E.; Krantz, Steven G. (2006), Function theory of one complex variable, Graduate Studies in Mathematics, vol. 40 (3rd ed.), American Mathematical Society, ISBN0-8218-3962-4
Taylor, Michael E. (2011), Partial differential equations I. Basic theory, Applied Mathematical Sciences, vol. 115 (2nd ed.), Springer, ISBN978-1-4419-7054-1
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Holy Fvck Студийный альбом Деми Ловато Дата выпуска 19 августа 2022 Дата записи 2022 Жанры Хард-рок[1], поп-панк[2] Длительность 47:48 Продюсеры Oak, Алекс Найс, Ten4 Язык песен английский Лейбл Island Records Хронология Деми Ловато Dancing with the Devil...The Art of Starting Over(2021) Holy Fvck(2022) Revamped(2023) Сингл...
Cabbage Garden Burial GroundGarraí an ChabáistePart of the burial ground was converted into a public park in 1982DetailsEstablished1666Closed1896LocationCathedral Lane, DublinCountryIrelandCoordinates53°20′13″N 6°16′16″W / 53.337°N 6.271°W / 53.337; -6.271TypePublicOwned byChapter of St. Patrick's CathedralSize0.56 hectares (1.4 acres)WebsiteOfficial websiteFind a GraveCabbage Garden Burial Ground The Cabbage Garden (Irish: Garraí an Chabáiste),[1...
Public school in Romney, West Virginia, United StatesWest Virginia Schoolsfor the Deaf and the BlindThe schools' administration building, 2013Address301 East Main StreetRomney, West Virginia 26757United StatesCoordinates39°20′26″N 78°45′07″W / 39.34056°N 78.75194°W / 39.34056; -78.75194InformationTypePublic schoolMottoVision: Achieve. Challenge. Thrive.[1]EstablishedMarch 3, 1870 (1870-03-03)[2]School boardWest Virginia Board ...
آلة حفر الأنفاقمعلومات عامةتصنيف معدات ثقيلة الاستعمال تشييد الأنفاق تاريخ الاختراع 1846 تعديل - تعديل مصدري - تعديل ويكي بيانات آلة حفر الأنفاق خلال عملها في نفق قاعدة غوتارد في سويسرا. آلة حفر الأنفاق أو حفَّارة الأنفاق (بالإنجليزية: tunnel boring machine اختصارًا TBM) هي آلة تستخدم ل
John Rutter Rutter in 2012 Geboren 24 september 1945 Land Vlag van Verenigd Koninkrijk Verenigd Koninkrijk Stijl eclecticisme Officiële website (en) IMDb-profiel (en) Allmusic-profiel (en) Last.fm-profiel (en) Discogs-profiel (en) MusicBrainz-profiel Portaal Muziek John Rutter (Londen, 24 september 1945) is een Engels componist, organist en koordirigent. Hij schrijft hoofdzakelijk composities voor koren. Leven Hij ging in Londen samen met de componist John Tavener naar de H...
Der Gratis Comic Tag ist eine Gemeinschafts-Marketingaktion von Comicverlagen und -händlern. Er findet in Deutschland, Österreich und der Schweiz jährlich seit 2010 statt. Der Termin liegt auf dem zweiten Samstag im Mai, jeweils eine Woche nach dem US-amerikanischen Vorbild, dem Free Comic Book Day, der seit 2002 veranstaltet wird. Inhaltsverzeichnis 1 Ziele und Ablauf 2 Geschichte 3 Verlage und Comics 4 Sonstiges 5 Batman-Tag 6 Manga Day 7 Weblinks 8 Einzelnachweise Ziele und Ablauf Typis...
університет Одеський національний морський університет ОНМУ Емблема Країна УкраїнаМісто ОдесаРозташування ОдесаЗасновано 1930Акредитація: IV рівняЧленство у Асоціація університетів Європи[1]Ректор Руденко Сергій ВасильовичСтудентів: 5340Докторів наук: 32Профе...
Nabi dan Rasul'Īsāعيس'alaihissalam, Ulul 'AzmiKaligrafi Isa 'alaihis-salamLahirBethlehemTempat tinggalPalestinaGelar 'Alaihissalam Almasih Ulul 'Azmi Ibnu Maryam Ruhullah Kalimatullah PendahuluYahya (Sesuai urutan 25 nabi dan rasul)PenggantiMuhammad (Sesuai urutan 25 nabi dan rasul)Orang tuaMaryam Nabi dan Rasul dalam Islam Nabi dalam Al-Qur'anMenyesuaikan antara nama Islam dan Alkitab. ʾĀdam (Adam) ʾIdrīs (Henokh?) Nūḥ (Nuh) Hūd (Eber?) Ṣāliḥ (Selah) ʾIbrāhīm (Abraham) L...
Energy needed to remove an electron For the values of the ionization energies of the elements, see Molar ionization energies of the elements and Ionization energies of the elements (data page) This article needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed.Find sources: Ionization energy – news · newspapers · books · scholar · JSTOR (Sep...
El Gran Telescopio Canarias en la puesta del sol. En este artículo se aborda la ciencia y la tecnología en España, que engloba un conjunto de políticas, planes y programas desarrollados por el Ministerio de Ciencia e Innovación y otros organismos. Estas iniciativas están orientadas hacia la investigación, desarrollo e innovación (I+D+i) en el país, así como hacia las infraestructuras e instalaciones científicas y tecnológicas españolas. En cuanto a la posición de España en el ...
Gerobak yang dipakai untuk angkutan tebu ke pabrik gula Tangaran (1927-1929) pedati yang ditarik keledai di afrika selatan Gerobak atau pedati atau kereta adalah sebuah kendaraan atau alat yang memiliki dua atau empat buah roda yang digunakan sebagai sarana transportasi. Gerobak dapat ditarik oleh hewan seperti kuda, sapi, kambing, zebu atau dapat pula ditarik oleh manusia. Kereta (Inggris: wagon) adalah sejenis gerobak dengan empat buah roda untuk transportasi yang lebih berat ditarik oleh s...
Leland Todd PowersBorn(1857-01-28)January 28, 1857Pultneyville, New York, United StatesDiedNovember 27, 1920(1920-11-27) (aged 63)Brookline, MassachusettsNationalityAmericanOccupationEducatorKnown forFounder of the Leland Powers SchoolSpouse Carol Hoyt (m. 1895) Leland Todd Powers (January 28, 1857 – November 27, 1920) was an American performing arts educator, author, and actor. The founder of the Leland Powers School, he was once renowned as the hig...
Road in Ireland R608 roadBóthar R608R608 passing the White Horse, BallincolligRoute informationLength12.2 km (7.6 mi)Major junctionsFrom N22 BarnagoreMajor intersections N22 Ballincollig Crosses Curraheen River R641 Cork (Wilton Road) R849 Cork (Glasheen Road) R851 Cork (Evergreen Street)To N22 Cork (Washington Street) LocationCountryIreland Highway system Roads in Ireland Motorways Primary Secondary Regional The R608 road is a regional road in Ireland, located in County Cork ...
Соціалістичний робітничий інтернаціонал Тип Інтернаціоналміжнародна організаціяЗасновано 21 травня 1923Розпущено 3 квітня 1940Ідеологія марксизмШтаб-квартира Лондон, Цюрих і БрюссельГенеральний секретар Фрідріх Адлер Соціалістичний робітничий інтернаціонал...
Painting by Gustave Moureau The Mystic Flower (c. 1890) by Gustave Moreau You can help expand this article with text translated from the corresponding article in French. (February 2023) Click [show] for important translation instructions. View a machine-translated version of the French article. Machine translation, like DeepL or Google Translate, is a useful starting point for translations, but translators must revise errors as necessary and confirm that the translation is accurate, rath...
4-DEpisode The X-FilesNomor episodeMusim 9Episode 4SutradaraTony WharmbyPenulisSteven MaedaKode produksi9ABX05Tanggal siar9 Desember 2001Durasi44 menitBintang tamu Cary Elwes sebagai Brad Follmer Gil Colon sebagai Agen Rice Dylan Haggerty sebagai Erwin Timothy Lukesh Ming Lo sebagai Dokter Kim Angela Paton sebagai Miriam Lukesh[1] Kronologi episode ← SebelumnyaDæmonicus Selanjutnya →Lord of the Flies 4-D adalah episode keempat dari musim kesembilan dan episode ke-1...
Steven UniversePrimera aparición Episodio PilotoCreado por Rebecca SugarVoz original Zach CallisonDoblador en España Isabel VallsDoblador en Hispanoamérica Leisha Medina (Temporada 1 - 5)Jorge Bringas (Película y Future)Información personalNacimiento 15 de agosto de 2002Nacionalidad EstadounidenseCaracterísticas físicasRaza híbrido Humano-GemaSexo MasculinoColor de pelo castaño oscuroColor de ojos negroFamilia y relacionesPadres Greg Universe (padre)Rose Cuarzo/Pink Diamond (madre)Ot...