Higher-order estimates for fully nonlinear difference equations. I

Holtby, Derek William

doi:10.1017/s0013091500021155

Cited by 5 publications

(10 citation statements)

References 16 publications

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“…We pass from the frozen to the general case though a method employed by Safonov [10,11,15] for fully nonlinear partial di¬erential equations, which was already extended to di¬erence equations by Holtby in [2,3]. As remarked earlier, our equations are more general than those considered by Holtby, and overall our approach in simpler.…”

Section: The General Casementioning

confidence: 99%

“…As in the continuous case (see [10,11,15]), the interior k, ® semi-norms in (3.11) where d = diam « . By choosing°su¯ciently small and using the interpolation inequalities [3,13] (as in the continuous case [10,11]), we nally arrive at the interior [u] ¤ k;« + [u] ¤ 2;® ;« 6 C(juj 0;« + (diam « ) 2+ ® ); (3.14) where C depends on n, ¤ = ¶ , • = ¶ , • h=h, a 0 =» h,ã= ¶ 0 ,`0, ® and K. Accordingly, we have the following theorem.…”

Section: The General Casementioning

confidence: 99%

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Schauder estimates for fully nonlinear elliptic difference operators

Kuo

Trudinger

2002

Proceedings of the Royal Society of Edinburgh: Section A Mathem

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In this paper, we are concerned with discrete Schauder estimates for solutions of fully nonlinear elliptic difference equations. Our estimates are discrete versions of second derivative Hölder estimates of Evans, Krylov and Safonov for fully nonlinear elliptic partial differential equations. They extend previous results of Holtby for the special case of functions of pure second-order differences on cubic meshes. As with Holtby's work, the fundamental ingredients are the pointwise estimates of Kuo-Trudinger for linear difference schemes on general meshes.

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Section: The General Casementioning

confidence: 99%

Section: The General Casementioning

confidence: 99%

Schauder estimates for fully nonlinear elliptic difference operators

Kuo

Trudinger

2002

Proceedings of the Royal Society of Edinburgh: Section A Mathem

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“…(See [5] for an exposition of Kunkle's construction and details of the said modification, as well as proofs of the facts contained in the above lemma. )…”

Section: Lemma 11 (Theorem 132 In [7])mentioning

confidence: 99%

“…In this paper the setting and notation are as in [6], where we derived a discrete a priori C 2,α estimate for solutions of difference equations involving operators of the form…”

Section: Introductionmentioning

confidence: 99%

Higher-Order Estimates for Fully Nonlinear Difference Equations. Ii

Holtby

2001

Proceedings of the Edinburgh Mathematical Society

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The purpose of this work is to establish a priori C 2,α estimates for mesh function solutions of nonlinear difference equations of positive type in fully nonlinear form on a uniform mesh, where the fully nonlinear finite difference operator F h is concave in the second-order variables. The estimate is an analogue of the corresponding estimate for solutions of concave fully nonlinear elliptic partial differential equations. We use the results for the special case that the operator does not depend explicitly upon the independent variables (the so-called frozen case) established in part I to approach the general case of explicit dependence upon the independent variables. We make our approach for the diagonal case via a discretization of the approach of Safonov for fully nonlinear elliptic partial differential equations using the discrete linear theory of Kuo and Trudinger and an especially agreeable mesh function interpolant provided by Kunkle. We generalize to non-diagonal operators using an idea which, to the author's knowledge, is novel. In this paper we establish the desired Hölder estimate in the large, that is, on the entire mesh n-plane. In a subsequent paper a truly interior estimate will be established in a mesh n-box.

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“…In two papers [2,3], Holtby used a multivariate Favard-like theorem from [4] to arrive at bounds on solutions to multivariate difference equations. The results presented here have potential for similar applications.…”

Section: Introductionmentioning

confidence: 99%

Favard interpolation from subsets of a rectangular lattice

Kunkle

2011

Journal of Approximation Theory

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This is a study of Favard interpolation -in which the nth derivatives of the interpolant are bounded above by a constant times the nth divided differences of the data -in the case where the data are given on some subset of a rectangular lattice in R k . In some instances, depending on the geometry of this subset, we construct a Favard interpolant, and in other instances, we prove that none exists.

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Higher-order estimates for fully nonlinear difference equations. I

Cited by 5 publications

References 16 publications

Schauder estimates for fully nonlinear elliptic difference operators

Schauder estimates for fully nonlinear elliptic difference operators

Higher-Order Estimates for Fully Nonlinear Difference Equations. Ii

Favard interpolation from subsets of a rectangular lattice

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