Difference between revisions of "User:Camillo.delellis/sandbox"
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| − | An area of analysis concerned with solving geometric problems via measure-theoretic techniques. The canonical motivating physical problem is probably that investigated experimentally by J. Plateau in the nineteenth century: Given a boundary wire, how does one find the (minimal) soap film which spans it? | + | An area of analysis concerned with solving geometric problems via measure-theoretic techniques. The canonical motivating physical problem is probably that investigated experimentally by J. Plateau in the nineteenth century: Given a boundary wire, how does one find the (minimal) soap film which spans it? In mathematical terms: Given a boundary curve, find the surface of minimal area spanning it. (Cf. also [[Plateau problem|Plateau problem]].) The many different approaches to solving this problem have found utility in most areas of modern mathematics and geometric measure theory is no exception: techniques and ideas from geometric measure theory have been found useful in the study of partial differential equations, the calculus of variations, geometric analysis, harmonic analysis, and fractals. |
=History= | =History= | ||
=Measure theoretic concepts= | =Measure theoretic concepts= | ||
| + | One of the central issues of geometric measure theory is to define the concepts of volume, area | ||
| + | and length in the uttermost generality. The roots of this concept are obviously in measure theory. In particular, the concept of [[Outer measure|outer measure]] in a [[Metric space|metric | ||
| + | space]] plays a fundamental role. | ||
| + | |||
==Caratheodory construction== | ==Caratheodory construction== | ||
| + | The following is a common construction of metric outer measures in metric spaces $(X, d)$. | ||
| + | |||
| + | '''Definition 1''' | ||
| + | If $\mathcal{C}$ is a class of subsets of $X$ containing the empty set, $\nu : \mathcal{C}\to [0, \infty]$ a set function with $\nu (\emptyset) =0$ and $\delta\in ]0, \infty]$, then for every $A\subset X$ we define | ||
| + | \[ | ||
| + | \mu^\delta (A) := \inf \left\{ \sum_i \nu (E_i) : \{E_i\}_{i\in \mathbb N} \subset \mathcal{C} \mbox{ covers $A$ and ${\rm diam}\, (E_i) \leq \delta$}\right\}\, | ||
| + | \] | ||
| + | and | ||
| + | \[ | ||
| + | \mu (A) := \lim_{\delta\downarrow 0}\; \mu^\delta (A)\, . | ||
| + | \] | ||
| + | |||
| + | Observe that the latter limit exists because $\mu^\delta (A)$ is a nonincreasing function of $\delta$. | ||
| + | This construction is often called ''Caratheodory construction''. See Section 2.1 of {{Cite|KP}} (cp. also with {{Cite|Fe}}). | ||
| + | |||
| + | '''Theorem 2''' | ||
| + | Let $\nu$ and $\mu$ be as in Definition 7. Then $\mu$ is a metric outer measure. | ||
| + | |||
| + | (Cp. with Claims 1,2 and 3 in the proof of Theorem 1 in Section 2.1 of {{Cite|EG}}: although the reference handles the cases of Hausdorff outer measures, the proof extends verbatim to the setting above). | ||
| + | |||
===Hausdorff measures=== | ===Hausdorff measures=== | ||
| + | The Caratheodory construction gives several generalizations of the concept of dimension and | ||
| + | volume. The most common is due to Hausdorff (cp. with {{Cite|Ha}}). | ||
| + | |||
| + | '''Definition 3''' | ||
| + | The [[Hausdorff measure|Hausdorff outer measure]] $\mathcal{H}^\alpha$ is given by such $\mu$ as in Definition 1 when we choose $\mathcal{C} = \mathcal{P} (X)$ and $\nu (A) = c_\alpha ({\rm diam}\, (A))^\alpha$, where | ||
| + | \[ | ||
| + | \omega_\alpha = \frac{\pi^{\alpha/2}}{\Gamma \left(\frac{\alpha}{2}+1\right)}\, | ||
| + | \] | ||
| + | (cp. with Section 2.1 of {{Cite|EG}}). | ||
| + | |||
| + | When $\alpha$ is a (positive) integer $n$, $\omega_n$ equals the Lebesgue measure of the unit ball in $\mathbb R^n$. With | ||
| + | this choice the $n$-dimensional Hausdorff outer measure on the euclidean space $\mathbb R^n$ coincides | ||
| + | with the Lebesgue measure. However some authors set $\omega_\alpha =1$ (see for instance {{Cite|Ma}}). | ||
| + | ====Hausdorff dimension==== | ||
| + | The following is a simple consequence of the definition (cp. with Theorem 4.7 of {{Cite|Ma}}). | ||
| + | |||
| + | '''Theorem 4''' | ||
| + | For $0\leq s<t<\infty$ and $A\subset X$ we have | ||
| + | * $\mathcal{H}^s (A) < \infty \Rightarrow \mathcal{H}^t (A) = 0$; | ||
| + | * $\mathcal{H}^t (A)>0 \Rightarrow \mathcal{H}^s (A) = \infty$. | ||
| + | |||
| + | The [[Hausdorff dimension]] ${\rm dim}_H (A)$ of a subset $A\subset X$ is then defined as | ||
| + | |||
| + | '''Definition 5''' | ||
| + | \begin{align*} | ||
| + | {\rm dim}_H (A) &= \sup \{s: \mathcal{H}^s (A)> 0\} = \sup \{s: \mathcal{H}^s (A) = \infty\}\\ | ||
| + | &=\inf \{t: \mathcal{H}^t (A) = 0\} = \inf \{t: \mathcal{H}^t (A) < \infty\}\, . | ||
| + | \end{align*} | ||
| + | ===Other measures related to the volume=== | ||
| + | The Caratheodory construction can be used to build other generalizations of the concept of volume, such as | ||
| + | * The spherical $\alpha$-dimensional outer measures on a metric space $(X,d)$, see Section 2.1.2 of {{Cite|KP}}. | ||
| + | * The Gross outer measures, the Caratheodory outer measures, the integral-geometric outer measures (see also [[Favard measure]]) and the Gillespie outer measures in $\mathbb R^n$, see Sections 2.1.3-2.1.4-2.1.5 of {{Cite|KP}} (cp. also with 2.10.2-2.10.3-2.10.4 of {{Cite|Fe}}). | ||
| + | All these measures coincide on sufficiently regular set (in particular on [[Rectifiable set|rectifiable sets]], see below), but they are, in general, different. | ||
===Fractals=== | ===Fractals=== | ||
| + | ==Differentiantion theorem== | ||
| + | ===Covering arguments=== | ||
=Rectifiable sets= | =Rectifiable sets= | ||
==Besicovitch's works== | ==Besicovitch's works== | ||
| Line 63: | Line 123: | ||
=Notable applications= | =Notable applications= | ||
=References= | =References= | ||
| + | {| | ||
| + | |- | ||
| + | |valign="top"|{{Ref|EG}}|| L.C. Evans, R.F. Gariepy, "Measure theory and fine properties of functions" Studies in Advanced Mathematics. CRC Press, Boca Raton, FL, 1992. {{MR|1158660}} {{ZBL|0804.2800}} | ||
| + | |- | ||
| + | |valign="top"|{{Ref|Fe}}|| H. Federer, "Geometric measure theory". Volume 153 of Die Grundlehren der mathematischen Wissenschaften. Springer-Verlag New York Inc., New York, 1969. {{MR|0257325}} {{ZBL|0874.49001}} | ||
| + | |- | ||
| + | |valign="top"|{{Ref|Ha}}|| F. Hausdorff, "Dimension and äusseres Mass" ''Math. Ann.'' , '''79''' (1918) pp. 157–179 {{MR|1511917}} {{ZBL|}} | ||
| + | |- | ||
| + | |valign="top"|{{Ref|KP}}|| S. G. Krantz, H. Parks, "Geometric Integration Theory", Birkhäuser (2008). | ||
| + | |- | ||
| + | |valign="top"|{{Ref|Ma}}|| P. Mattila, "Geometry of sets and measures in Euclidean spaces. Fractals and rectifiability". Cambridge Studies in Advanced Mathematics, 44. Cambridge University Press, Cambridge, 1995. {{MR|1333890}} {{ZBL|0911.28005}} | ||
| + | |- | ||
| + | |valign="top"|{{Ref|Mu}}|| M. E. Munroe, "Introduction to Measure and Integration". Addison Wesley (1953). | ||
| + | |- | ||
| + | |} | ||
Revision as of 14:40, 10 November 2012
2020 Mathematics Subject Classification: Primary: 49Q15 Secondary: 49Q2049Q0528A7532C3058A2558C35 [MSN][ZBL]
An area of analysis concerned with solving geometric problems via measure-theoretic techniques. The canonical motivating physical problem is probably that investigated experimentally by J. Plateau in the nineteenth century: Given a boundary wire, how does one find the (minimal) soap film which spans it? In mathematical terms: Given a boundary curve, find the surface of minimal area spanning it. (Cf. also Plateau problem.) The many different approaches to solving this problem have found utility in most areas of modern mathematics and geometric measure theory is no exception: techniques and ideas from geometric measure theory have been found useful in the study of partial differential equations, the calculus of variations, geometric analysis, harmonic analysis, and fractals.
History
Measure theoretic concepts
One of the central issues of geometric measure theory is to define the concepts of volume, area and length in the uttermost generality. The roots of this concept are obviously in measure theory. In particular, the concept of outer measure in a metric space plays a fundamental role.
Caratheodory construction
The following is a common construction of metric outer measures in metric spaces $(X, d)$.
Definition 1 If $\mathcal{C}$ is a class of subsets of $X$ containing the empty set, $\nu : \mathcal{C}\to [0, \infty]$ a set function with $\nu (\emptyset) =0$ and $\delta\in ]0, \infty]$, then for every $A\subset X$ we define \[ \mu^\delta (A) := \inf \left\{ \sum_i \nu (E_i) : \{E_i\}_{i\in \mathbb N} \subset \mathcal{C} \mbox{ covers '"`UNIQ-MathJax8-QINU`"' and '"`UNIQ-MathJax9-QINU`"'}\right\}\, \] and \[ \mu (A) := \lim_{\delta\downarrow 0}\; \mu^\delta (A)\, . \]
Observe that the latter limit exists because $\mu^\delta (A)$ is a nonincreasing function of $\delta$. This construction is often called Caratheodory construction. See Section 2.1 of [KP] (cp. also with [Fe]).
Theorem 2 Let $\nu$ and $\mu$ be as in Definition 7. Then $\mu$ is a metric outer measure.
(Cp. with Claims 1,2 and 3 in the proof of Theorem 1 in Section 2.1 of [EG]: although the reference handles the cases of Hausdorff outer measures, the proof extends verbatim to the setting above).
Hausdorff measures
The Caratheodory construction gives several generalizations of the concept of dimension and volume. The most common is due to Hausdorff (cp. with [Ha]).
Definition 3 The Hausdorff outer measure $\mathcal{H}^\alpha$ is given by such $\mu$ as in Definition 1 when we choose $\mathcal{C} = \mathcal{P} (X)$ and $\nu (A) = c_\alpha ({\rm diam}\, (A))^\alpha$, where \[ \omega_\alpha = \frac{\pi^{\alpha/2}}{\Gamma \left(\frac{\alpha}{2}+1\right)}\, \] (cp. with Section 2.1 of [EG]).
When $\alpha$ is a (positive) integer $n$, $\omega_n$ equals the Lebesgue measure of the unit ball in $\mathbb R^n$. With this choice the $n$-dimensional Hausdorff outer measure on the euclidean space $\mathbb R^n$ coincides with the Lebesgue measure. However some authors set $\omega_\alpha =1$ (see for instance [Ma]).
Hausdorff dimension
The following is a simple consequence of the definition (cp. with Theorem 4.7 of [Ma]).
Theorem 4 For $0\leq s<t<\infty$ and $A\subset X$ we have
- $\mathcal{H}^s (A) < \infty \Rightarrow \mathcal{H}^t (A) = 0$;
- $\mathcal{H}^t (A)>0 \Rightarrow \mathcal{H}^s (A) = \infty$.
The Hausdorff dimension ${\rm dim}_H (A)$ of a subset $A\subset X$ is then defined as
Definition 5 \begin{align*} {\rm dim}_H (A) &= \sup \{s: \mathcal{H}^s (A)> 0\} = \sup \{s: \mathcal{H}^s (A) = \infty\}\\ &=\inf \{t: \mathcal{H}^t (A) = 0\} = \inf \{t: \mathcal{H}^t (A) < \infty\}\, . \end{align*}
The Caratheodory construction can be used to build other generalizations of the concept of volume, such as
- The spherical $\alpha$-dimensional outer measures on a metric space $(X,d)$, see Section 2.1.2 of [KP].
- The Gross outer measures, the Caratheodory outer measures, the integral-geometric outer measures (see also Favard measure) and the Gillespie outer measures in $\mathbb R^n$, see Sections 2.1.3-2.1.4-2.1.5 of [KP] (cp. also with 2.10.2-2.10.3-2.10.4 of [Fe]).
All these measures coincide on sufficiently regular set (in particular on rectifiable sets, see below), but they are, in general, different.
Fractals
Differentiantion theorem
Covering arguments
Rectifiable sets
Besicovitch's works
One-dimensional sets
General dimension and codimension
Besicovitch-Federer projection theorem
Marstrand's theorem
Besicovitch-Preiss theorem
Tangent measures
Caccioppoli sets
Functions of bounded variation
Plateau's problem in codimension 1
Existence
Regularity theory
Bernstein's problem
Simons' cone
De Giorgi's $\varepsilon$-regularity theorem
Simons' inequality and solution of the Bernstein's problem
Stable surfaces
Federer's estimate of the singular set
Simon's rectifiability theorem
Mumford Shah conjecture
Currents
Federer-Fleming theory
Compactness for integral currents
Deformation theorem
Plateau's problem in any codimension
Regularity theory
Almgren's $\varepsilon$-regularity theorem
Almgren's big regularity paper
Currents in metric spaces
Varifolds
General theory
Rectifiable and integral varifolds
Regularity theory
Allard's rectifiability theorem
Allard's $\varepsilon$-regularity theorem
Calculus of variations in the large
Pitts' theory
Schoen-Simon curvature estimates
The Willmore conjecture
Smith's theorem and generalizations
Applications to topology
Uniqueness of tangent cones
White's theorem
Simon's theorem
Lojasievicz inequality
Soap films
Almgren's $\varepsilon-\delta$ minimal sets
Taylor's theorem
Double-bubble conjecture
Notable applications
References
| [EG] | L.C. Evans, R.F. Gariepy, "Measure theory and fine properties of functions" Studies in Advanced Mathematics. CRC Press, Boca Raton, FL, 1992. MR1158660 Zbl 0804.2800 |
| [Fe] | H. Federer, "Geometric measure theory". Volume 153 of Die Grundlehren der mathematischen Wissenschaften. Springer-Verlag New York Inc., New York, 1969. MR0257325 Zbl 0874.49001 |
| [Ha] | F. Hausdorff, "Dimension and äusseres Mass" Math. Ann. , 79 (1918) pp. 157–179 MR1511917 |
| [KP] | S. G. Krantz, H. Parks, "Geometric Integration Theory", Birkhäuser (2008). |
| [Ma] | P. Mattila, "Geometry of sets and measures in Euclidean spaces. Fractals and rectifiability". Cambridge Studies in Advanced Mathematics, 44. Cambridge University Press, Cambridge, 1995. MR1333890 Zbl 0911.28005 |
| [Mu] | M. E. Munroe, "Introduction to Measure and Integration". Addison Wesley (1953). |
Camillo.delellis/sandbox. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Camillo.delellis/sandbox&oldid=28498