In mathematical analysis, a Young measure is a parameterized measure that is associated with certain subsequences of a given bounded sequence of measurable functions. They are a quantification of the oscillation effect of the sequence in the limit. Young measures have applications in the calculus of variations, especially models from material science, and the study of nonlinear partial differential equations, as well as in various optimization (or optimal control problems). They are named after Laurence Chisholm Young who invented them, already in 1937 in one dimension (curves) and later in higher dimensions in 1942.[1]

Young measures provide a solution to Hilbert’s twentieth problem, as a broad class of problems in the calculus of variations have solutions in the form of Young measures.[2]

Definition

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Intuition

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Young constructed the Young measure in order to complete sets of ordinary curves in the calculus of variations. That is, Young measures are "generalized curves".[2]

Consider the problem of  , where   is a function such that  , and continuously differentiable. It is clear that we should pick   to have value close to zero, and its slope close to  . That is, the curve should be a tight jagged line hugging close to the x-axis. No function can reach the minimum value of  , but we can construct a sequence of functions   that are increasingly jagged, such that  .

The pointwise limit   is identically zero, but the pointwise limit   does not exist. Instead, it is a fine mist that has half of its weight on  , and the other half on  .

Suppose that   is a functional defined by  , where   is continuous, then  so in the weak sense, we can define   to be a "function" whose value is zero and whose derivative is  . In particular, it would mean that  .

Motivation

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The definition of Young measures is motivated by the following theorem: Let m, n be arbitrary positive integers, let   be an open bounded subset of   and   be a bounded sequence in  [clarification needed]. Then there exists a subsequence   and for almost every   a Borel probability measure   on   such that for each   we have

 

weakly in   if the limit exists (or weakly* in   in case of  ). The measures   are called the Young measures generated by the sequence  .

A partial converse is also true: If for each   we have a Borel measure   on   such that  , then there exists a sequence  , bounded in  , that has the same weak convergence property as above.

More generally, for any Carathéodory function  , the limit

 

if it exists, will be given by[3]

 .

Young's original idea in the case   was to consider for each integer   the uniform measure, let's say   concentrated on graph of the function   (Here,   is the restriction of the Lebesgue measure on  ) By taking the weak* limit of these measures as elements of   we have

 

where   is the mentioned weak limit. After a disintegration of the measure   on the product space   we get the parameterized measure  .

General definition

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Let   be arbitrary positive integers, let   be an open and bounded subset of  , and let  . A Young measure (with finite p-moments) is a family of Borel probability measures   on   such that  .

Examples

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Pointwise converging sequence

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A trivial example of Young measure is when the sequence   is bounded in   and converges pointwise almost everywhere in   to a function  . The Young measure is then the Dirac measure

 

Indeed, by dominated convergence theorem,   converges weakly* in   to

 

for any  .

Sequence of sines

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A less trivial example is a sequence

 

The corresponding Young measure satisfies[4]

 

for any measurable set  , independent of  . In other words, for any  :

 

in  . Here, the Young measure does not depend on   and so the weak* limit is always a constant.

To see this intuitively, consider that at the limit of large  , a rectangle of   would capture a part of the curve of  . Take that captured part, and project it down to the x-axis. The length of that projection is  , which means that   should look like a fine mist that has probability density   at all  .

Minimizing sequence

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For every asymptotically minimizing sequence   of

 

subject to   (that is, the sequence satisfies  ), and perhaps after passing to a subsequence, the sequence of derivatives   generates Young measures of the form  . This captures the essential features of all minimizing sequences to this problem, namely, their derivatives   will tend to concentrate along the minima   of the integrand  .

If we take  , then its limit has value zero, and derivative  , which means  .

See also

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References

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  1. ^ Young, L. C. (1942). "Generalized Surfaces in the Calculus of Variations". Annals of Mathematics. 43 (1): 84–103. doi:10.2307/1968882. ISSN 0003-486X. JSTOR 1968882.
  2. ^ a b Balder, Erik J. "Lectures on Young measures." Cahiers de Mathématiques de la Décision 9517 (1995).
  3. ^ Pedregal, Pablo (1997). Parametrized measures and variational principles. Basel: Birkhäuser Verlag. ISBN 978-3-0348-8886-8. OCLC 812613013.
  4. ^ Dacorogna, Bernard (2006). Weak continuity and weak lower semicontinuity of non-linear functionals. Springer.
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