Localization of the W-1,q norm for local a posteriori efficiency

Blechta, Jan; Málek, Josef; Vohralı́k, Martin

doi:10.1093/imanum/drz002

Cited by 17 publications

(20 citation statements)

References 40 publications

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“…Proof of (5.14) and The proof is essentially a counting argument after local Riesz mappings are introduced to evaluate the negative norms ∂ t (u − Iu hτ ) 2 H −1 (ωa) for all a ∈ V n , see also [2]. Summing (5.12) over K ∈ T n and using (8.10) then leads to K∈T…”

Section: Global Efficiencymentioning

confidence: 99%

Guaranteed, Locally Space-Time Efficient, and Polynomial-Degree Robust a Posteriori Error Estimates for High-Order Discretizations of Parabolic Problems

Ern¹,

Smears²,

Vohralı́k³

2017

SIAM J. Numer. Anal.

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We consider the a posteriori error analysis of approximations of parabolic problems based on arbitrarily high-order conforming Galerkin spatial discretizations and arbitrarily highorder discontinuous Galerkin temporal discretizations. Using equilibrated flux reconstructions, we present a posteriori error estimates for a norm composed of the L 2 (H 1 )∩H 1 (H −1 )-norm of the error and the temporal jumps of the numerical solution. The estimators provide guaranteed upper bounds for this norm, without unknown constants. Furthermore, the efficiency of the estimators with respect to this norm is local in both space and time, with constants that are robust with respect to the mesh-size, time-step size, and the spatial and temporal polynomial degrees. We further show that this norm, which is key for local space-time efficiency, is globally equivalent to the L 2 (H 1 ) ∩ H 1 (H −1 )-norm of the error, with polynomial-degree robust constants. The proposed estimators also have the practical advantage of allowing for very general refinement and coarsening between the timesteps.

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Section: Global Efficiencymentioning

confidence: 99%

Guaranteed, Locally Space-Time Efficient, and Polynomial-Degree Robust a Posteriori Error Estimates for High-Order Discretizations of Parabolic Problems

Ern¹,

Smears²,

Vohralı́k³

2017

SIAM J. Numer. Anal.

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“…on the intrinsic error u − u h * given by (2.2) seem rather Σand T-dependent, see in particular the numerical study in Section 6 of [22]. Finally, Figure 5 illustrates that the distribution of the error is predicted very correctly by our estimators (plotting by a piecewise affine function is done as explained in Section 5 of [8]).…”

Section: A Regular Weak Solutionmentioning

confidence: 70%

“…Remark 3.4 (Further generalization). Theorem 3.3 has recently been extended to any bounded linear functional on the Sobolev space W 1,p 0 (Ω), p > 1, in [8].…”

Section: Localization Of Dual (Residual) Normsmentioning

confidence: 99%

“…We will focus on our a posteriori error estimates of Theorem 4.5, while tracing the error u − u h * defined by (2.1a) In what follows, we compute u − u h * approximately, while approximating (5.4). We again employ a posteriori error estimates to ensure that u − u h * is computed with relative accuracy 10 −2 , see the details in Section 5 of [8]. We will also display the canonical H 1 0 (Ω)-norm of the error ∇(u − u h ) .…”

Section: Numerical Experimentsmentioning

confidence: 99%

“…For dual (residual) norms, a result of this type has probably first been shown in Babuška and Miller Theorem 2.1.1 of [4], and may be deduced from more recent a posteriori analyses, see in particular Carstensen and Funken [17], Morin et al [38], Verfürth [48,50], Veeser and Verfürth [46], Cohen et al [24], and the references therein, typically for piecewise polynomial approximations. It has recently been extended in [8] to any bounded linear functional on the Sobolev space W 1,p 0 (Ω), p > 1. Galerkin orthogonality with respect to lowest-order modes turns out to be crucial here for one direction of the equivalence.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Localization of global norms and robust a posteriori error control for transmission problems with sign-changing coefficients

Ciarlet

Vohralı́k

2018

ESAIM: M2AN

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We present a posteriori error analysis of diffusion problems where the diffusion tensor is not necessarily symmetric and positive definite and can in particular change its sign. We first identify the correct intrinsic error norm for such problems, covering both conforming and nonconforming approximations. It combines a dual (residual) norm together with the distance to the correct functional space. Importantly, we show the equivalence of both these quantities defined globally over the entire computational domain with the Hilbertian sums of their localizations over patches of elements. In this framework, we then design a posteriori estimators which deliver simultaneously guaranteed error upper bound, global and local error lower bounds, and robustness with respect to the (sign-changing) diffusion tensor. Robustness with respect to the approximation polynomial degree is achieved as well. The estimators are given in a unified setting covering at once conforming, nonconforming, mixed, and discontinuous Galerkin finite element discretizations in two or three space dimensions. Numerical results illustrate the theoretical developments.

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Finite Elements II

Ern¹,

Guermond²

2021

Texts in Applied Mathematics

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Exercise . The goal of this exercise is to derive another proof of the Lax-Milgram lemma. Let A ∈ L(V ; V ) be defined by (A(v), w) V := a(v, w) for all v, w ∈ V (note that we use an inner product to define A). Let L be the representative in V of the linear form ℓ ∈ V ′ . Let λ be a positive real number. Consider the mapwith ρ λ ∈ (0, 1), and show that (25.6) is well-posed. (Hint : use Banach's fixed-point theorem.) Exercise 25.7 (Coercivity as necessary condition). Let V be a reflexive Banach space and let A ∈ L(V ; V ′ ) be a monotone self-adjoint operator; see Definition C.31. Prove that A is bijective if and only if A is coercive (with ξ := 1). (Hint : prove that ℜ(for all v, w ∈ V.) Exercise 25.8 (Darcy). Prove that the problem (24.14) is well-posed. (Hint : adapt the proof of Proposition 25.18.) Exercise 25.9 (First-order PDE). Prove that the problem (24.21) is well-posed. (Hint : adapt the proof of Proposition 25.19.) Exercise 25.10 (T -coercivity). Let V, W be Hilbert spaces. Prove that (bnb1)-(bnb2) are equivalent to the existence of a bijective operator T ∈ L(V ; W ) and a real number η > 0 such that ℜ(a(v, T (v))) ≥ η v 2V for all v ∈ V. (Hint : use J −1 W , (A −1 ) * , and the map J rf V from the Riesz-Fréchet theorem to construct T .) Exercise 25.11 (Sign-changing diffusion). Let D be a Lipschitz domain D in R d partitioned into two disjoint Lipschitz subdomains D 1 and D 2 . Set Σ := ∂D 1 ∩∂D 2 , each having an intersection with ∂D of positive measure. Let κ 1 , κ 2 be two real numbers s.t. κ 1 > 0 and κ 2 < 0. Set κ(x) := κ 1 1 D1 (x)+κ 2 1 D2 (x) for all x ∈ D. Let V := H 1 0 (D) be equipped with the norm ∇v L 2 (D) . The goal is to show that the bilinear form a(v, w) := D κ∇v•∇w satisfies conditions (bnb1)-(bnb2) on V ×V ; see Chesnel and Ciarlet [118]. Set V m := {v| Dm | v ∈ V } for all m ∈ {1, 2}, equipped with the norm ∇v m L 2 (Dm) for all v m ∈ V m , and let γ 0,m be the traces of functions in V m on Σ. (i) Assume that there isProve that T ∈ L(V ) and that T is an isomorphism. (Hint : verify that T • T = I V , the identity in V.) (ii) Assume that κ1 |κ2| > S 1 2 L(V1;V2) . Prove that the conditions (bnb1)-(bnb2) are satisfied.

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Localization of the W-1,q norm for local a posteriori efficiency

Cited by 17 publications

References 40 publications

Guaranteed, Locally Space-Time Efficient, and Polynomial-Degree Robust a Posteriori Error Estimates for High-Order Discretizations of Parabolic Problems

Guaranteed, Locally Space-Time Efficient, and Polynomial-Degree Robust a Posteriori Error Estimates for High-Order Discretizations of Parabolic Problems

Localization of global norms and robust a posteriori error control for transmission problems with sign-changing coefficients

Finite Elements II

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