Whitney covering lemma: Difference between revisions

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In mathematical analysis, the Whitney covering lemma, or Whitney decomposition, asserts the existence of a certain type of partition of an open set in a Euclidean space. Originally it was employed in the proof of Hassler Whitney's extension theorem. The lemma was subsequently applied to prove generalizations of the Calderón–Zygmund decomposition.

Roughly speaking, the lemma states that it is possible to decompose an open set by cubes each of whose diameters is proportional, within certain bounds, to its distance from the boundary of the open set. More precisely:

Whitney Covering Lemma (Grafakos 2008, Appendix J)

Let $\Omega$ be an open non-empty proper subset of $\mathbb {R} ^{n}$ . Then there exists a family of closed cubes $\{Q_{j}\}_{j}$ such that

$\cup _{j}Q_{j}=\Omega$ and the $Q_{j}$ 's have disjoint interiors.
${\sqrt {n}}\ell (Q_{j})\leq \mathrm {dist} (Q_{j},\Omega ^{c})\leq 4{\sqrt {n}}\ell (Q_{j}).$
If the boundaries of two cubes $Q_{j}$ and $Q_{k}$ touch then ${\frac {1}{4}}\leq {\frac {\ell (Q_{j})}{\ell (Q_{k})}}\leq 4.$
For a given $Q_{j}$ there exist at most $12^{n}Q_{k}$ 's that touch it.

Where $\ell (Q)$ denotes the length of a cube $Q$ .

References

Grafakos, Loukas (2008). Classical Fourier Analysis. Springer. ISBN 978-0-387-09431-1.
DiBenedetto, Emmanuele (2002), Real analysis, Birkhäuser, ISBN 0-8176-4231-5.
Stein, Elias (1970), Singular Integrals and Differentiability Properties of Functions, Princeton University Press.
Whitney, Hassler (1934), "Analytic extensions of functions defined in closed sets", Transactions of the American Mathematical Society, 36 (1), American Mathematical Society: 63–89, doi:10.2307/1989708, JSTOR 1989708.

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@@ Line 9: / Line 9: @@
 * <math>\cup_j Q_j = \Omega</math> and the <math>Q_j</math>'s have disjoint interiors.
-* <math>\sqrt{n} l(Q_j) \leq \mathrm{dist}(Q_j, \Omega^c) \leq 4 \sqrt{n} l(Q_j).</math>
+* <math>\sqrt{n} \ell(Q_j) \leq \mathrm{dist}(Q_j, \Omega^c) \leq 4 \sqrt{n} \ell(Q_j).</math>
-* If the boundaries of two cubes <math>Q_j</math> and <math>Q_k</math> touch then <math>\frac{1}{4} \leq \frac{l(Q_j)}{l(Q_k)} \leq 4.</math>
+* If the boundaries of two cubes <math>Q_j</math> and <math>Q_k</math> touch then <math>\frac{1}{4} \leq \frac{\ell(Q_j)}{\ell(Q_k)} \leq 4.</math>
 * For a given <math>Q_j</math> there exist at most <math>12^n Q_k</math>'s that touch it.
-Where <math>l(Q)</math> denotes the length of a cube <math>Q</math>.
+Where <math>\ell(Q)</math> denotes the length of a cube <math>Q</math>.
 ==References==