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In mathematics, a function of bounded deformation is a function whose distributional derivatives are not quite well-behaved-enough to qualify as functions of bounded variation, although the symmetric part of the derivative matrix does meet that condition. Thought of as deformations of elasto-plastic bodies, functions of bounded deformation play a major role in the mathematical study of materials, e.g. the Francfort-Marigo model of brittle crack evolution. More precisely, given an open subset Ω of R''n'', a function ''u'' : Ω → R''n'' is said to be of bounded deformation if the symmetrized gradient ''ε''(''u'') of ''u'', : is a bounded, symmetric ''n'' × ''n'' matrix-valued Radon measure. The collection of all functions of bounded deformation is denoted BD(Ω; R''n''), or simply BD, introduced essentially by P.-M.Subsequent in 1978. BD is a strictly larger space than the space BV of functions of bounded variation. One can show that if ''u'' is of bounded deformation then the measure ''ε''(''u'') can be decomposed into three parts: one absolutely continuous with respect to Lebesgue measure, denoted ''e''(''u'') d''x''; a jump part, supported on a rectifiable (''n'' − 1)-dimensional set ''J''''u'' of points where ''u'' has two different approximate limits ''u''+ and ''u''−, together with a normal vector ''ν''''u''; and a "Cantor part", which vanishes on Borel sets of finite ''H''''n''−1-measure (where ''H''''k'' denotes ''k''-dimensional Hausdorff measure). A function ''u'' is said to be of special bounded deformation if the Cantor part of ''ε''(''u'') vanishes, so that the measure can be written as : where ''H'' ''n''−1 | ''J''''u'' denotes ''H'' ''n''−1 on the jump set ''J''''u'' and denotes the symmetrized dyadic product: : The collection of all functions of special bounded deformation is denoted SBD(Ω; R''n''), or simply SBD. ==References== * * * 抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)』 ■ウィキペディアで「Bounded deformation」の詳細全文を読む スポンサード リンク
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