|
|
| (One intermediate revision by one other user not shown) |
| Line 1: |
Line 1: |
| In [[mathematics]], the '''capacity of a set''' in [[Euclidean space]] is a measure of that set's "size". Unlike, say, [[Lebesgue measure]], which measures a set's [[volume]] or physical extent, capacity is a mathematical analogue of a set's ability to hold [[electrical charge]]. More precisely, it is the [[capacitance]] of the set: the total charge a set can hold while maintaining a given [[potential energy]]. The potential energy is computed with respect to an idealized ground at infinity for the '''harmonic''' or '''Newtonian capacity''', and with respect to a surface for the '''condenser capacity'''.
| | Nothing to tell about myself really.<br>Enjoying to be a member of this community.<br>I just wish Im useful at all<br>xunjie 子供たちは非常にそれを持って好きでなければなりません!興味のある方は、 |
| | パリで韓国のアイドルグループ少女時代だけのワールドツアー公演ステーションの終了後に仁川(インチョン)国際空港を通じて韓国に戻った。 |
| | より多くのきれいなウールを開始しましたデザインは、 [http://annikalarsson.com/Scripts/good/list/p/chloe/ ���� ؔ�� 2014] 「子どもの新たな成長のアイデアとして文化を生きていると、 |
| | 绝対秋・冬の外に乗るのは聖品ですよね。 |
| | 安定的かつ健全な発展に唇の販売網を作る。 [http://www.mazz.ch/windowset/r/best/chanel.html ����ͥ� �Хå� �ǥ˥�] 2011达芙妮新型サンダル暗い色のケーキスカートに取り组み鮮かな薄緑色キャミソール、 |
| | ソフィー·オースターとDREEヘミングウェイ。 |
| | 300平方メートルの店舗面積の大きなフォリフォリの春と夏の広告、[http://anghaeltacht.net/ctg/cocog/p/top/gaga/ �����ߥ�� �rӋ �˚�] 世界で最も魅力的な店で最も繁栄大都市に設立され、 |
| | スタイリッシュなカジュアルウェアの味と文化を反映しています。 |
| | 大連理工大学職業提携大学から小さなフロントは、 |
| | 子供の頃の色カラフルバラカラフルな色の子供時代を誇示するためにゴージャスなバラの幼年期のカラフルなコントラストカラーのベストのスカートを披露する華やかな色のコントラストカラーのベストのスカートを誇示する、 [http://www.otto-weibel.ch/media/nobs/header/shop/celine/ ����`�� �Хå<br><br>�� 2014] |
|
| |
|
| ==Historical note==
| | Also visit my web site :: [http://gjpipe.com/images/tomford.html トムフォード メガネ レディース] |
| The notion of capacity of a set and of "capacitable" set was introduced by [[Gustave Choquet]] in 1950: for a detailed account, see reference {{harv|Choquet|1986}}.
| |
| | |
| ==Definitions==
| |
| ===Condenser capacity===
| |
| | |
| Let Σ be a [[closed surface|closed]], smooth, (''n'' − 1)-[[dimension]]al [[hypersurface]] in ''n''-dimensional Euclidean space ℝ<sup>''n''</sup>, ''n'' ≥ 3; ''K'' will denote the ''n''-dimensional [[compact space|compact]] (i.e., [[closed set|closed]] and [[bounded set|bounded]]) set of which Σ is the [[boundary (topology)|boundary]]. Let ''S'' be another (''n'' − 1)-dimensional hypersurface that encloses Σ: in reference to its origins in [[electromagnetism]], the pair (Σ, ''S'') is known as a [[capacitor|condenser]]. The '''condenser capacity''' of Σ relative to ''S'', denoted ''C''(Σ, ''S'') or cap(Σ, ''S''), is given by the surface integral
| |
| | |
| :<math>C(\Sigma, S) = - \frac1{(n - 2) \sigma_{n}} \int_{S'} \frac{\partial u}{\partial \nu}\,\mathrm{d}\sigma',</math>
| |
| | |
| where:
| |
| | |
| * ''u'' is the unique [[harmonic function]] defined on the region ''D'' between Σ and ''S'' with the [[boundary condition]]s ''u''(''x'') = 1 on Σ and ''u''(''x'') = 0 on ''S'';
| |
| * ''S''′ is any intermediate surface between Σ and ''S'';
| |
| * ''ν'' is the outward [[unit normal]] [[vector field|field]] to ''S''′ and
| |
| | |
| ::<math>\frac{\partial u}{\partial \nu} (x) = \nabla u (x) \cdot \nu (x)</math>
| |
| | |
| :is the [[normal derivative]] of ''u'' across ''S''′; and
| |
| * ''σ''<sub>''n''</sub> = 2''π''<sup>''n''⁄2</sup> ⁄ Γ(''n'' ⁄ 2) is the surface area of the [[unit sphere]] in ℝ<sup>''n''</sup>.
| |
| | |
| ''C''(Σ, ''S'') can be equivalently defined by the volume integral
| |
| | |
| :<math>C(\Sigma, S) = \frac1{(n - 2) \sigma_{n}} \int_{D} | \nabla u |^{2}\mathrm{d}x.</math>
| |
| | |
| The condenser capacity also has a [[calculus of variations|variational characterization]]: ''C''(Σ, ''S'') is the [[infimum]] of the [[Dirichlet's energy]] [[functional (mathematics)|functional]]
| |
| | |
| :<math>I[v] = \frac1{(n - 2) \sigma_{n}} \int_{D} | \nabla v |^{2}\mathrm{d}x</math>
| |
| | |
| over all [[smooth function|continuously-differentiable functions]] ''v'' on ''D'' with ''v''(''x'') = 1 on Σ and ''v''(''x'') = 0 on ''S''.
| |
| | |
| ===Harmonic/Newtonian capacity===
| |
| | |
| [[Heuristic]]ally, the harmonic capacity of ''K'', the region bounded by Σ, can be found by taking the condenser capacity of Σ with respect to infinity. More precisely, let ''u'' be the harmonic function in the complement of ''K'' satisfying ''u'' = 1 on Σ and ''u''(''x'') → 0 as ''x'' → ∞. Thus ''u'' is the [[Newtonian potential]] of the simple layer Σ. Then the '''harmonic capacity''' (also known as the '''Newtonian capacity''') of ''K'', denoted ''C''(''K'') or cap(''K''), is then defined by
| |
| | |
| :<math>C(K) = \int_{\mathbb{R}^n\setminus K} |\nabla u|^2\mathrm{d}x.</math> | |
| | |
| If ''S'' is a rectifiable hypersurface completely enclosing ''K'', then the harmonic capacity can be equivalently rewritten as the integral over ''S'' of the outward normal derivative of ''u'':
| |
| | |
| :<math>C(K) = \int_S \frac{\partial u}{\partial\nu}\,\mathrm{d}\sigma.</math>
| |
| | |
| The harmonic capacity can also be understood as a limit of the condenser capacity. To wit, let ''S''<sub>''r''</sub> denote the [[sphere]] of radius ''r'' about the origin in ℝ<sup>''n''</sup>. Since ''K'' is bounded, for sufficiently large ''r'', ''S''<sub>''r''</sub> will enclose ''K'' and (Σ, ''S''<sub>''r''</sub>) will form a condenser pair. The harmonic capacity is then the [[Limit of a function|limit]] as ''r'' tends to infinity:
| |
| | |
| :<math>C(K) = \lim_{r \to \infty} C(\Sigma, S_{r}).</math>
| |
| | |
| The harmonic capacity is a mathematically abstract version of the [[electrostatic capacity]] of the conductor ''K'' and is always non-negative and finite: 0 ≤ ''C''(''K'') < +∞.
| |
| | |
| ==Generalizations==
| |
| The characterization of the capacity of a set as the minimum of an [[energy functional]] achieving particular boundary values, given above, can be extended to other energy functionals in the [[calculus of variations]].
| |
| | |
| ===Divergence form elliptic operators===
| |
| Solutions to a uniformly [[elliptic partial differential equation]] with divergence form
| |
| :<math> \nabla \cdot ( A \nabla u ) = 0 </math>
| |
| are minimizers of the associated energy functional
| |
| :<math>I[u] = \int_D (\nabla u)^T A (\nabla u)\,\mathrm{d}x</math>
| |
| subject to appropriate boundary conditions.
| |
| | |
| The capacity of a set ''E'' with respect to a domain ''D'' containing ''E'' is defined as the [[infimum]] of the energy over all [[smooth function|continuously-differentiable functions]] ''v'' on ''D'' with ''v''(''x'') = 1 on ''E''; and ''v''(''x'') = 0 on the boundary of ''D''.
| |
| | |
| The minimum energy is achieved by a function known as the ''capacitary potential'' of ''E'' with respect to ''D'', and it solves the [[obstacle problem]] on ''D'' with the obstacle function provided by the [[indicator function]] of ''E''. The capacitary potential is alternately characterized as the unique solution of the equation with the appropriate boundary conditions.
| |
| | |
| ==See also==
| |
| *[[Capacitance]]
| |
| *[[Newtonian potential]]
| |
| *[[Potential theory]]
| |
| | |
| ==References==
| |
| * {{citation
| |
| | last = Brélot
| |
| | first = Marcel
| |
| | author-link = Marcel Brélot
| |
| | title = Lectures on potential theory (Notes by K. N. Gowrisankaran and M. K. Venkatesha Murthy.)
| |
| | series = Tata Institute of Fundamental Research Lectures on Mathematics and Physics. Mathematics.
| |
| | volume = No. 19
| |
| | edition = 2nd
| |
| | publisher = Tata Institute of Fundamental Research
| |
| | location = Bombay
| |
| | year = 1967
| |
| | origyear = 1960
| |
| | pages = ii+170+iv
| |
| | url = http://www.math.tifr.res.in/~publ/ln/tifr19.pdf
| |
| | mr = 0259146
| |
| | zbl= 0257.31001
| |
| }}. The second edition of these lecture notes, revised and enlarged with the help of S. Ramaswamy, re–typeset, proof read once and freely available for download.
| |
| *{{Citation
| |
| | last = Choquet
| |
| | first = Gustave
| |
| | author-link = Gustave Choquet
| |
| | title = La naissance de la théorie des capacités: réflexion sur une expérience personnelle
| |
| | journal = [[Comptes rendus de l'Académie des sciences|Comptes rendus de l'Académie des sciences. Série générale, La Vie des sciences]]
| |
| | volume = 3
| |
| | issue = 4
| |
| | pages = 385–397
| |
| | year = 1986
| |
| | language = French
| |
| | url = http://gallica.bnf.fr/ark:/12148/bpt6k54708101/f85
| |
| | mr = 0867115
| |
| | zbl = 0607.01017
| |
| }}, available from [[Gallica]]. A historical account of the development of capacity theory by its founder and one of the main contributors; an English translation of the title reads: "The birth of capacity theory: reflections on a personal experience".
| |
| *{{citation
| |
| | last = Doob
| |
| | first = Joseph Leo
| |
| | author-link = Joseph Leo Doob
| |
| | title = Classical potential theory and its probabilistic counterpart
| |
| | series = Grundlehren der Mathematischen Wissenschaften
| |
| | volume = 262
| |
| | publisher = Springer-Verlag
| |
| | location = Berlin–[[Heidelberg]]–New York
| |
| | year = 1984
| |
| | pages = xxiv+846
| |
| | isbn = 0-387-90881-1
| |
| | mr = 731258
| |
| | zbl = 0549.31001
| |
| }}
| |
| *{{Citation
| |
| | last = Littman
| |
| | first = W.
| |
| | author-link = Walter Littman
| |
| | last2 = Stampacchia
| |
| | first2 = G.
| |
| | author2-link = Guido Stampacchia
| |
| | last3 = Weinberger
| |
| | first3 = H.
| |
| | author3-link = Hans Weinberger
| |
| | year = 1963
| |
| | title = Regular points for elliptic equations with discontinuous coefficients
| |
| | journal = Annali della Scuola Normale Superiore di Pisa – Classe di Scienze
| |
| | series = Serie III
| |
| | volume = 17
| |
| | issue = 12
| |
| | pages = 43–77
| |
| | url = http://www.numdam.org/item?id=ASNSP_1963_3_17_1-2_43_0
| |
| | mr = 161019
| |
| | zbl = 0116.30302
| |
| }}, available at [http://www.numdam.org NUMDAM].
| |
| * {{citation | last=Ransford | first=Thomas | title=Potential theory in the complex plane | series=London Mathematical Society Student Texts | volume=28 | location=Cambridge | publisher=[[Cambridge University Press]] | year=1995 | isbn=0-521-46654-7 | zbl=0828.31001 }}
| |
| * {{springer
| |
| | id = c/c020280
| |
| | title = Capacity of a set
| |
| | last = Solomentsev
| |
| | first = E. D.
| |
| }}
| |
| | |
| [[Category:Potential theory]]
| |