Poincaré inequality

In mathematics, the Poincaré inequality is a result in the theory of Sobolev spaces, named after the French mathematician Henri Poincaré. The inequality allows one to obtain bounds on a function using bounds on its derivatives and the geometry of its domain of definition. Such bounds are of great importance in the modern, direct methods of the calculus of variations. A very closely related result is the Friedrichs' inequality.

1 Statement of the inequality
- 1.1 The classical Poincaré inequality
- 1.2 Generalizations
2 The Poincaré constant
3 References

Statement of the inequality

The classical Poincaré inequality

Assume that 1 ≤ p ≤ ∞ and that Ω is a bounded connected open subset of the n-dimensional Euclidean space Rⁿ with a Lipschitz boundary (i.e., Ω is a Lipschitz domain). Then there exists a constant C, depending only on Ω and p, such that for every function u in the Sobolev space W^1,p(Ω),

$\| u - u_{\Omega} \|_{L^{p} (\Omega)} \leq C \| \nabla u \|_{L^{p} (\Omega)},$

where

$u_{\Omega} = \frac{1}{|\Omega|} \int_{\Omega} u(y) \, \mathrm{d} y$

is the average value of u over Ω, with |Ω| standing for the Lebesgue measure of the domain Ω.

Generalizations

There exist generalizations of the Poincaré inequality to other Sobolev spaces. For example, the following (taken from Garroni & Müller (2005)) is a Poincaré inequality for the Sobolev space H^1/2(T²), i.e. the space of functions u in the L² space of the unit torus T² with Fourier transform û satisfying

$[ u ]_{H^{1/2} (\mathbf{T}^{2})}^{2} = \sum_{k \in \mathbf{Z}^{2}} | k | \big| \hat{u} (k) \big|^{2} < %2B \infty:$

there exists a constant C such that, for every u ∈ H^1/2(T²) with u identically zero on an open set E ⊆ T²,

$\int_{\mathbf{T}^{2}} | u(x) |^{2} \, \mathrm{d} x \leq C \left( 1 %2B \frac1{\mathrm{cap} (E \times \{ 0 \})} \right) [ u ]_{H^{1/2} (\mathbf{T}^{2})}^{2},$

where cap(E × {0}) denotes the harmonic capacity of E × {0} when thought of as a subset of R³.

The Poincaré constant

The optimal constant C in the Poincaré inequality is sometimes known as the Poincaré constant for the domain Ω. Determining the Poincaré constant is, in general, a very hard task that depends upon the value of p and the geometry of the domain Ω. Certain special cases are tractable, however. For example, if Ω is a bounded, convex, Lipschitz domain with diameter d, then the Poincaré constant is at most d/2 for p = 1, d/π for p = 2 (Acosta & Durán 2004; Payne & Weinberger 1960), and this is the best possible estimate on the Poincaré constant in terms of the diameter alone. For smooth functions, this can be understood as an application of the isoperimetric inequality to the function's level sets. [1] In one dimension, this is Wirtinger's inequality for functions.

However, in some special cases the constant C can be determined concretely. For example, for p = 2, it is well known that over the domain of unit isosceles right triangle, C = 1/π ( < d/π where $\scriptstyle{d=\sqrt{2}}$ ). (See, for instance,Kikuchi & Liu (2007).)

References

Acosta, Gabriel; Durán, Ricardo G. (2004), "An optimal Poincaré inequality in L¹ for convex domains", Proc. Amer. Math. Soc. 132 (1): 195–202 (electronic), doi:10.1090/S0002-9939-03-07004-7
Evans, Lawrence C. (1998), Partial differential equations, Providence, RI: American Mathematical Society, ISBN 0-8218-0772-2
Fumio, Kikuchi; Xuefeng, Liu (2007), "Estimation of interpolation error constants for the P0 and P1 triangular finite elements", Comput. Methods. Appl. Mech. Engrg. 196 (37–40): 3750–3758, doi:10.1016/j.cma.2006.10.029 MR 2340000
Garroni, Adriana; Müller, Stefan (2005), "Γ-limit of a phase-field model of dislocations", SIAM J. Math. Anal. 36 (6): 1943–1964 (electronic), doi:10.1137/S003614100343768X MR 2178227
Payne, L. E.; Weinberger, H. F. (1960), "An optimal Poincaré inequality for convex domains", Archive for Rational Mechanics and Analysis: 286–292, ISSN 0003-9527