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In mathematics, lifting theory was first introduced by John von Neumann in a pioneering paper from 1931, in which he answered a question raised by Alfréd Haar.^[1] The theory was further developed by Dorothy Maharam (1958)^[2] and by Alexandra Ionescu Tulcea and Cassius Ionescu Tulcea (1961).^[3] Lifting theory was motivated to a large extent by its striking applications. Its development up to 1969 was described in a monograph of the Ionescu Tulceas.^[4] Lifting theory continued to develop since then, yielding new results and applications.

Definitions

A lifting on a measure space $(X,\Sigma ,\mu )$ is a linear and multiplicative operator $T:L^{\infty }(X,\Sigma ,\mu )\to {\mathcal {L}}^{\infty }(X,\Sigma ,\mu )$ which is a right inverse of the quotient map ${\begin{cases}{\mathcal {L}}^{\infty }(X,\Sigma ,\mu )\to L^{\infty }(X,\Sigma ,\mu )\\f\mapsto [f]\end{cases}}$

where ${\mathcal {L}}^{\infty }(X,\Sigma ,\mu )$ is the seminormed L^p space of measurable functions and $L^{\infty }(X,\Sigma ,\mu )$ is its usual normed quotient. In other words, a lifting picks from every equivalence class $[f]$ of bounded measurable functions modulo negligible functions a representative— which is henceforth written $T([f])$ or $T[f]$ or simply $Tf$ — in such a way that $T[1]=1$ and for all $p\in X$ and all $r,s\in \mathbb {R} ,$ $T(r[f]+s[g])(p)=rT[f](p)+sT[g](p),$ $T([f]\times [g])(p)=T[f](p)\times T[g](p).$

Liftings are used to produce disintegrations of measures, for instance conditional probability distributions given continuous random variables, and fibrations of Lebesgue measure on the level sets of a function.

Existence of liftings

Theorem. Suppose $(X,\Sigma ,\mu )$ is complete.^[5] Then $(X,\Sigma ,\mu )$ admits a lifting if and only if there exists a collection of mutually disjoint integrable sets in $\Sigma$ whose union is $X.$ In particular, if $(X,\Sigma ,\mu )$ is the completion of a σ-finite^[6] measure or of an inner regular Borel measure on a locally compact space, then $(X,\Sigma ,\mu )$ admits a lifting.

The proof consists in extending a lifting to ever larger sub-σ-algebras, applying Doob's martingale convergence theorem if one encounters a countable chain in the process.

Strong liftings

Suppose $(X,\Sigma ,\mu )$ is complete and $X$ is equipped with a completely regular Hausdorff topology $\tau \subseteq \Sigma$ such that the union of any collection of negligible open sets is again negligible – this is the case if $(X,\Sigma ,\mu )$ is σ-finite or comes from a Radon measure. Then the support of $\mu ,$ $\operatorname {Supp} (\mu ),$ can be defined as the complement of the largest negligible open subset, and the collection $C_{b}(X,\tau )$ of bounded continuous functions belongs to ${\mathcal {L}}^{\infty }(X,\Sigma ,\mu ).$

A strong lifting for $(X,\Sigma ,\mu )$ is a lifting $T:L^{\infty }(X,\Sigma ,\mu )\to {\mathcal {L}}^{\infty }(X,\Sigma ,\mu )$ such that $T\varphi =\varphi$ on $\operatorname {Supp} (\mu )$ for all $\varphi$ in $C_{b}(X,\tau ).$ This is the same as requiring that^[7] $TU\geq (U\cap \operatorname {Supp} (\mu ))$ for all open sets $U$ in $\tau .$

Theorem. If $(\Sigma ,\mu )$ is σ-finite and complete and $\tau$ has a countable basis then $(X,\Sigma ,\mu )$ admits a strong lifting.

Proof. Let $T_{0}$ be a lifting for $(X,\Sigma ,\mu )$ and $U_{1},U_{2},\ldots$ a countable basis for $\tau .$ For any point $p$ in the negligible set $N:=\bigcup \nolimits _{n}\left\{p\in \operatorname {Supp} (\mu ):(T_{0}U_{n})(p)<U_{n}(p)\right\}$ let $T_{p}$ be any character^[8] on $L^{\infty }(X,\Sigma ,\mu )$ that extends the character $\phi \mapsto \phi (p)$ of $C_{b}(X,\tau ).$ Then for $p$ in $X$ and $[f]$ in $L^{\infty }(X,\Sigma ,\mu )$ define: $(T[f])(p):={\begin{cases}(T_{0}[f])(p)&p\notin N\\T_{p}[f]&p\in N.\end{cases}}$ $T$ is the desired strong lifting.

Application: disintegration of a measure

Suppose $(X,\Sigma ,\mu )$ and $(Y,\Phi ,\nu )$ are σ-finite measure spaces ( $\mu ,\mu$ positive) and $\pi :X\to Y$ is a measurable map. A disintegration of $\mu$ along $\pi$ with respect to $\nu$ is a slew $Y\ni y\mapsto \lambda _{y}$ of positive σ-additive measures on $(\Sigma ,\mu )$ such that

$\lambda _{y}$ is carried by the fiber $\pi ^{-1}(\{y\})$ of $\pi$ over $y$ , i.e. $\{y\}\in \Phi$ and $\lambda _{y}\left((X\setminus \pi ^{-1}(\{y\})\right)=0$ for almost all $y\in Y$
for every $\mu$ -integrable function $f,$ $\int _{X}f(p)\;\mu (dp)=\int _{Y}\left(\int _{\pi ^{-1}(\{y\})}f(p)\,\lambda _{y}(dp)\right)\nu (dy)\qquad (*)$ in the sense that, for $\nu$ -almost all $y$ in $Y,$ $f$ is $\lambda _{y}$ -integrable, the function $y\mapsto \int _{\pi ^{-1}(\{y\})}f(p)\,\lambda _{y}(dp)$ is $\nu$ -integrable, and the displayed equality $(*)$ holds.

Disintegrations exist in various circumstances, the proofs varying but almost all using strong liftings. Here is a rather general result. Its short proof gives the general flavor.

Theorem. Suppose $X$ is a Polish space^[9] and $Y$ a separable Hausdorff space, both equipped with their Borel σ-algebras. Let $\mu$ be a σ-finite Borel measure on $X$ and $\pi :X\to Y$ a $\Sigma ,\Phi -$ measurable map. Then there exists a σ-finite Borel measure $\nu$ on $Y$ and a disintegration (*). If $\mu$ is finite, $\nu$ can be taken to be the pushforward^[10] $\pi _{*}\mu ,$ and then the $\lambda _{y}$ are probabilities.

Proof. Because of the polish nature of $X$ there is a sequence of compact subsets of $X$ that are mutually disjoint, whose union has negligible complement, and on which $\pi$ is continuous. This observation reduces the problem to the case that both $X$ and $Y$ are compact and $\pi$ is continuous, and $\nu =\pi _{*}\mu .$ Complete $\Phi$ under $\nu$ and fix a strong lifting $T$ for $(Y,\Phi ,\nu ).$ Given a bounded $\mu$ -measurable function $f,$ let $\lfloor f\rfloor$ denote its conditional expectation under $\pi ,$ that is, the Radon-Nikodym derivative of^[11] $\pi _{*}(f\mu )$ with respect to $\pi _{*}\mu .$ Then set, for every $y$ in $Y,$ $\lambda _{y}(f):=T(\lfloor f\rfloor )(y).$ To show that this defines a disintegration is a matter of bookkeeping and a suitable Fubini theorem. To see how the strongness of the lifting enters, note that $\lambda _{y}(f\cdot \varphi \circ \pi )=\varphi (y)\lambda _{y}(f)\qquad \forall y\in Y,\varphi \in C_{b}(Y),f\in L^{\infty }(X,\Sigma ,\mu )$ and take the infimum over all positive $\varphi$ in $C_{b}(Y)$ with $\varphi (y)=1;$ it becomes apparent that the support of $\lambda _{y}$ lies in the fiber over $y.$

References

^ von Neumann, John (1931). "Algebraische Repräsentanten der Funktionen "bis auf eine Menge vom Maße Null"". Journal für die reine und angewandte Mathematik (in German). 1931 (165): 109–115. doi:10.1515/crll.1931.165.109. MR 1581278.
^ Maharam, Dorothy (1958). "On a theorem of von Neumann". Proceedings of the American Mathematical Society. 9 (6): 987–994. doi:10.2307/2033342. JSTOR 2033342. MR 0105479.
^ Ionescu Tulcea, Alexandra; Ionescu Tulcea, Cassius (1961). "On the lifting property. I." Journal of Mathematical Analysis and Applications. 3 (3): 537–546. doi:10.1016/0022-247X(61)90075-0. MR 0150256.
^ Ionescu Tulcea, Alexandra; Ionescu Tulcea, Cassius (1969). Topics in the theory of lifting. Ergebnisse der Mathematik und ihrer Grenzgebiete. Vol. 48. New York: Springer-Verlag. MR 0276438. OCLC 851370324.
^ A subset $N\subseteq X$ is locally negligible if it intersects every integrable set in $\Sigma$ in a subset of a negligible set of $\Sigma .$ $(X,\Sigma ,\mu )$ is complete if every locally negligible set is negligible and belongs to $\Sigma .$
^ i.e., there exists a countable collection of integrable sets – sets of finite measure in $\Sigma$ – that covers the underlying set $X.$
^ $U,$ $\operatorname {Supp} (\mu )$ are identified with their indicator functions.
^ A character on a unital algebra is a multiplicative linear functional with values in the coefficient field that maps the unit to 1.
^ A separable space is Polish if its topology comes from a complete metric. In the present situation it would be sufficient to require that $X$ is Suslin, that is, is the continuous Hausdorff image of a Polish space.
^ The pushforward $\pi _{*}\mu$ of $\mu$ under $\pi ,$ also called the image of $\mu$ under $\pi$ and denoted $\pi (\mu ),$ is the measure $\nu$ on $\Phi$ defined by $\nu (A):=\mu \left(\pi ^{-1}(A)\right)$ for $A$ in $\Phi$ .
^ $f\mu$ is the measure that has density $f$ with respect to $\mu$

[1] von Neumann, John (1931). "Algebraische Repräsentanten der Funktionen "bis auf eine Menge vom Maße Null"". Journal für die reine und angewandte Mathematik (in German). 1931 (165): 109–115. doi:10.1515/crll.1931.165.109. MR 1581278.

[2] Maharam, Dorothy (1958). "On a theorem of von Neumann". Proceedings of the American Mathematical Society. 9 (6): 987–994. doi:10.2307/2033342. JSTOR 2033342. MR 0105479.

[3] Ionescu Tulcea, Alexandra; Ionescu Tulcea, Cassius (1961). "On the lifting property. I." Journal of Mathematical Analysis and Applications. 3 (3): 537–546. doi:10.1016/0022-247X(61)90075-0. MR 0150256.

[4] Ionescu Tulcea, Alexandra; Ionescu Tulcea, Cassius (1969). Topics in the theory of lifting. Ergebnisse der Mathematik und ihrer Grenzgebiete. Vol. 48. New York: Springer-Verlag. MR 0276438. OCLC 851370324.

[5] A subset $N\subseteq X$ is locally negligible if it intersects every integrable set in $\Sigma$ in a subset of a negligible set of $\Sigma .$ $(X,\Sigma ,\mu )$ is complete if every locally negligible set is negligible and belongs to $\Sigma .$

[6] .e., there exists a countable collection of integrable sets – sets of finite measure in $\Sigma$ – that covers the underlying set $X.$

[7] $U,$ $\operatorname {Supp} (\mu )$ are identified with their indicator functions.

[character-8] A character on a unital algebra is a multiplicative linear functional with values in the coefficient field that maps the unit to 1.

[9] A separable space is Polish if its topology comes from a complete metric. In the present situation it would be sufficient to require that $X$ is Suslin, that is, is the continuous Hausdorff image of a Polish space.

[10] The pushforward $\pi _{*}\mu$ of $\mu$ under $\pi ,$ also called the image of $\mu$ under $\pi$ and denoted $\pi (\mu ),$ is the measure $\nu$ on $\Phi$ defined by $\nu (A):=\mu \left(\pi ^{-1}(A)\right)$ for $A$ in $\Phi$ .

[11] $f\mu$ is the measure that has density $f$ with respect to $\mu$

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]

@@ Line 1: / Line 1: @@
+{{Short description|Notion in measure theory}}
-In mathematics, '''lifting theory''' was first introduced by [[John von Neumann]] in a pioneering paper from 1931, in which he answered a question raised by [[Alfréd Haar]].<ref>von Neumann, J.: Algebraische Repräsentanten der Funktionen bis auf eine Menge von Maße Null. J. Crelle '''165''', 109–115 (1931)</ref> The theory was further developed by [[Dorothy Maharam]] (1958)<ref>Maharam, Doroth: On a theorem of von Neumann. Proc. Amer. Math. Soc. '''9''', 987–995 (1958)</ref> and by [[Alexandra Bellow|Alexandra Ionescu Tulcea]] and [[Cassius Ionescu-Tulcea]] (1961).<ref>A. Ionescu Tulcea and C. Ionescu Tulcea: On the lifting property, I., J. Math. Anal. App. '''3''', 537–546 (1961)</ref>
+In mathematics, '''lifting theory''' was first introduced by [[John von Neumann]] in a pioneering paper from 1931, in which he answered a question raised by [[Alfréd Haar]].<ref>
+{{Cite journal|year=1931|first=John|last=von Neumann|authorlink=John von Neumann|title=Algebraische Repräsentanten der Funktionen "bis auf eine Menge vom Maße Null"| url=http://www.degruyter.com/view/j/crll.1931.1931.issue-165/crll.1931.165.109/crll.1931.165.109.xml|journal=[[Crelle's Journal|Journal für die reine und angewandte Mathematik]]|language=de|volume=1931|issue=165|pages=109–115|doi=10.1515/crll.1931.165.109|mr=1581278}}</ref> The theory was further developed by [[Dorothy Maharam]] (1958)<ref>{{Cite journal|last=Maharam|first=Dorothy|authorlink=Dorothy Maharam|year=1958|title=On a theorem of von Neumann|url=https://www.ams.org/jourcgi/jour-getitem?pii=S0002-9939-1958-0105479-6|journal=[[Proceedings of the American Mathematical Society]]|volume=9|issue=6|pages=987–994|doi=10.2307/2033342|jstor=2033342|mr=0105479|doi-access=free}}</ref> and by [[Alexandra Bellow|Alexandra Ionescu Tulcea]] and [[Cassius Ionescu-Tulcea|Cassius Ionescu Tulcea]] (1961).<ref>{{Cite journal|last1= Ionescu Tulcea|first1=Alexandra|author1-link=Alexandra Bellow|last2=Ionescu Tulcea|first2=Cassius|author2-link=Cassius Ionescu-Tulcea|year=1961|title=On the lifting property. I.|journal=[[Journal of Mathematical Analysis and Applications]]|volume=3|issue=3|pages=537–546|doi=10.1016/0022-247X(61)90075-0|mr=0150256|doi-access=free}}</ref> Lifting theory was motivated to a large extent by its striking applications. Its development up to 1969 was described in a monograph of the Ionescu Tulceas.<ref>{{cite book|last1= Ionescu Tulcea|first1=Alexandra|author1-link=Alexandra Bellow|last2=Ionescu Tulcea|first2=Cassius|author2-link=Cassius Ionescu-Tulcea|year=1969|title=Topics in the theory of lifting|series=[[Ergebnisse der Mathematik und ihrer Grenzgebiete]]|volume=48|publisher=[[Springer Science+Business Media|Springer-Verlag]]|location= New York|oclc=851370324|mr=0276438}}</ref> Lifting theory continued to develop since then, yielding new results and applications.
+==Definitions==
-Lifting theory was motivated to a large extent by its striking applications; for its development up to 1969, see the Ionescu Tulceas' work and the monograph,<ref>Alexandra Ionescu Tulcea and Cassius Ionescu Tulcea, ''Topics in the Theory of Lifting'', Ergebnisse der Mathematik, Vol. 48, Springer-Verlag, Berlin, Heidelberg, New York (1969)</ref> now a standard reference in the field. Lifting theory continued to develop after 1969, yielding significant new results and applications.
-A '''lifting''' on a [[measure space]] (''X'', Σ, ''μ'') is a linear and multiplicative inverse
+A '''lifting''' on a [[measure space]] <math>(X, \Sigma, \mu)</math> is a linear and multiplicative operator
+<math display=block>T : L^\infty(X, \Sigma, \mu) \to \mathcal{L}^\infty(X, \Sigma, \mu)</math>
+which is a [[Inverse function#Right inverses|right inverse]] of the quotient map
-:<math> T:L^\infty(X,\Sigma,\mu)\to \mathcal L^\infty(X,\Sigma,\mu)</math>
+<math display=block>\begin{cases}
+\mathcal L^\infty(X,\Sigma,\mu) \to L^\infty(X,\Sigma,\mu) \\
-of the quotient map
+f \mapsto [f]
+\end{cases}</math>
-: <math>\begin{cases}\mathcal L^\infty(X,\Sigma,\mu)\to L^\infty(X,\Sigma,\mu) \\
- f\mapsto [f]\end{cases}</math>
-where <math> \mathcal L^\infty(X,\Sigma,\mu)</math> is the seminormed [[Lp_space |L<sup>p</sup> space]] of measurable functions and <math> L^\infty(X,\Sigma,\mu)</math> is its usual normed quotient. In other words, a lifting picks from every equivalence class [''f''] of bounded measurable functions modulo negligible functions a representative&mdash; which is henceforth written ''T''([''f'']) or ''T''[''f''] or simply ''Tf'' &mdash; in such a way that
+where <math>\mathcal{L}^\infty(X,\Sigma,\mu)</math> is the seminormed [[Lp space|L<sup>p</sup> space]] of measurable functions and <math>L^\infty(X, \Sigma, \mu)</math> is its usual normed quotient. In other words, a lifting picks from every equivalence class <math>[f]</math> of bounded measurable functions modulo negligible functions a representative&mdash; which is henceforth written <math>T([f])</math> or <math>T[f]</math> or simply <math>Tf</math> &mdash; in such a way that <math>T[1] = 1</math> and for all <math>p \in X</math> and all <math>r, s \in \Reals,</math>
-:<math>T(r[f]+s[g])(p)=rT[f](p) + sT[g](p), \qquad \forall p\in X, r,s\in \mathbf R;</math>
-:<math>T([f]\times[g])(p)=T[f](p)\times T[g](p), \qquad \forall p\in X;</math>
+<math display=block>T(r[f]+s[g])(p) = rT[f](p) + sT[g](p),</math>
-:<math>T[1]=1.</math>
+<math display=block>T([f]\times[g])(p) = T[f](p) \times T[g](p).</math>
 Liftings are used to produce [[Disintegration theorem|disintegrations of measures]], for instance [[conditional probability distribution]]s given continuous random variables, and fibrations of Lebesgue measure on the level sets of a function.
@@ Line 22: / Line 21: @@
 ==Properties of liftings==
 A lifting is necessarily positive:
-:<math>[f]\ge0\implies T[f]\ge0 \mathrm{\ (since\ } [f] \mathrm{\ is\ a\ square)} </math>
+<math display=block>[f]\ge0\implies T[f]\ge0 \mathrm{\ (since\ } [f] \mathrm{\ is\ a\ square)} </math>
 and an isometry:<ref>The ''essential supremum'' of a class [''f''] of ''μ''-measurable functions is the smallest number α for which the set [''f'' > α] is ''μ''-negligible.</ref>
+<math display=block>\big\Vert T[f]\big\Vert_\infty:= \sup_{p\in X}\,\big|T[f](p)\big|=\mathrm{ess.sup}\,\big|[f]\big|.</math>
+For every point ''p'' in ''X'', the map <math>[f]\mapsto T_pf:= T[f](p)</math> is a character<ref name=character> A ''character'' on a unital algebra is a multiplicative linear functional with values in the coefficient field that maps the unit to 1.</ref> of <math>L^\infty(X, \Sigma, \mu).</math>
-:<math> \big\Vert T[f]\big\Vert_\infty:= \sup_{p\in X}\,\big|T[f](p)\big|=\mathrm{ess.sup}\,\big|[f]\big|.</math>
-For every point ''p'' in ''X'', the map <math>[f]\mapsto T_pf:= T[f](p)</math> is a character<ref name=character> A ''character'' on a unital algebra is a multiplicative linear functional with values in the coefficient field that maps the unit to 1.</ref> of ''L''<sup>∞</sup>(''X'', Σ, ''μ'').
 -->
 ==Existence of liftings==
-<blockquote>'''Theorem.''' Suppose (''X'', Σ, ''μ'') is complete.<ref>A subset ''N'' ⊂ ''X'' is locally negligible if it intersects every integrable set in Σ in a subset of a negligible set of Σ. (''X'', Σ, ''μ'') is ''complete'' if every locally negligible set is negligible and belongs to Σ.</ref> Then (''X'', Σ, ''μ'') admits a lifting if and only if there exists a collection of mutually disjoint integrable sets in Σ whose union is&nbsp;''X''.
+<blockquote>'''Theorem.''' Suppose <math>(X, \Sigma, \mu)</math> is complete.<ref>A subset <math>N \subseteq X</math> is locally negligible if it intersects every integrable set in <math>\Sigma</math> in a subset of a negligible set of <math>\Sigma.</math> <math>(X, \Sigma, \mu)</math> is ''complete'' if every locally negligible set is negligible and belongs to <math>\Sigma.</math></ref> Then <math>(X, \Sigma, \mu)</math> admits a lifting if and only if there exists a collection of mutually disjoint integrable sets in <math>\Sigma</math> whose union is <math>X.</math>
-In particular, if (''X'', Σ, ''μ'') is the completion of a ''σ''-finite<ref>i.e., there exists a countable collection of integrable sets &ndash; sets of finite measure in Σ &ndash; that covers the underlying set ''X''.</ref> measure or of an inner regular Borel measure on a locally compact space, then (''X'', Σ, ''μ'') admits a lifting.</blockquote>
+In particular, if <math>(X, \Sigma, \mu)</math> is the completion of a ''σ''-finite<ref>i.e., there exists a countable collection of integrable sets &ndash; sets of finite measure in <math>\Sigma</math> &ndash; that covers the underlying set <math>X.</math></ref> measure or of an inner regular Borel measure on a [[locally compact space]], then <math>(X, \Sigma, \mu)</math> admits a lifting.</blockquote>
-The proof consists in extending a lifting to ever larger sub-''σ''-algebras, applying [[Doob's martingale convergence theorems|Doob's martingale convergence theorem]] if one encounters a countable chain in the process.
+The proof consists in extending a lifting to ever larger sub-''σ''-algebras, applying [[Doob's martingale convergence theorems|Doob's martingale convergence theorem]] if one encounters a countable chain in the process.
 <!--
-Here are the details. Henceforth write ''Tf'' := ''T''[''f''] = ''T''([''f'']). (Σ, ''μ'') is ''σ''-finite if there exists a countable collection of sets of finite measure in Σ whose union has negligible complement. This permits a reduction to the case that the measure ''μ'' is finite, in fact, it may be taken to be a probability. The proof uses [[Zorn's lemma]] together with the following order on pairs <math>(\mathfrak A,T_{\mathfrak A})</math> of sub-''σ''-algebras <math>\mathfrak A</math> of Σ and liftings <math>T_{\mathfrak A}</math> for them: <math> (\mathfrak A,T_{\mathfrak A})\le(\mathfrak B,T_{\mathfrak B}) </math> if <math>\mathfrak A\subseteq\mathfrak B</math> and <math>T_{\mathfrak A}</math> is the restriction of <math>T_{\mathfrak B}</math> to <math>L^\infty(X,\mathfrak A,\mu)</math>. It is to be shown that a chain <math>\mathfrak C</math> of such pairs has an upper bound, and that a maximal pair, which then exists by Zorn's lemma, has Σ for its first entry.
+Here are the details. Henceforth write ''Tf'' := ''T''[''f''] = ''T''([''f'']). <math>(\Sigma, \mu)</math> is ''σ''-finite if there exists a countable collection of sets of finite measure in <math>\Sigma</math> whose union has negligible complement. This permits a reduction to the case that the measure <math>\mu</math> is finite, in fact, it may be taken to be a probability. The proof uses [[Zorn's lemma]] together with the following order on pairs <math>(\mathfrak A,T_{\mathfrak A})</math> of sub-''σ''-algebras <math>\mathfrak A</math> of <math>\Sigma</math> and liftings <math>T_{\mathfrak A}</math> for them: <math> (\mathfrak A,T_{\mathfrak A})\le(\mathfrak B,T_{\mathfrak B}) </math> if <math>\mathfrak A\subseteq\mathfrak B</math> and <math>T_{\mathfrak A}</math> is the restriction of <math>T_{\mathfrak B}</math> to <math>L^\infty(X,\mathfrak A,\mu)</math>. It is to be shown that a chain <math>\mathfrak C</math> of such pairs has an upper bound, and that a maximal pair, which then exists by Zorn's lemma, has <math>\Sigma</math> for its first entry.
-If <math>\mathfrak C</math> has no countable [[Cofinal (mathematics)|cofinal]] subset, then the union <math>\mathfrak U:=\bigcup\{\mathfrak A:\,(\mathfrak A,T_{\mathfrak A}) \in \mathfrak C\} </math> is a ''σ''-algebra and there is an obvious lifting <math>T_{\mathfrak U}</math> for it that restricts to the liftings of the chain; <math>(\mathfrak U,T_{\mathfrak U})</math> is the sought upper bound of the chain.
+If <math>\mathfrak C</math> has no countable [[Cofinal (mathematics)|cofinal]] subset, then the union <math>\mathfrak U := \bigcup\{\mathfrak A:\,(\mathfrak A,T_{\mathfrak A}) \in \mathfrak C\}</math> is a ''σ''-algebra and there is an obvious lifting <math>T_{\mathfrak U}</math> for it that restricts to the liftings of the chain; <math>(\mathfrak U,T_{\mathfrak U})</math> is the sought upper bound of the chain.
-The argument is more complicated when the chain <math> \mathfrak C</math> has a countable cofinal subset <math>\left\{(\mathfrak A_n,T_{\mathfrak A_n}), n = 1, 2, \ldots \right\}</math>. In this case let <math>\mathfrak U</math> be the  [[Sigma-algebra|''σ''-algebra generated]] by the union <math>\bigcup\{\mathfrak A_n: \, n = 1, 2, \ldots\} </math>, which is generally only an [[Field of sets|algebra of sets]]. For the construction of <math>T_{\mathfrak U}</math> it is convenient to identify a set ''A'' ⊆ ''X'' with its indicator function and to write <math>TA:=TI_A=T[I_A]</math>. For <math>A\in\mathfrak U</math> let ''A<sub>n</sub>'' denote the [[conditional expectation]] of ''A'' under <math>\mathfrak A_n</math>. By [[Doob's martingale convergence theorems|Doob's martingale convergence theorem]] the set ''θ''(''A'')of points where ''A''<sub>''n''</sub> converges to 1 differs negligibly from&nbsp;''A''.
+The argument is more complicated when the chain <math> \mathfrak C</math> has a countable cofinal subset <math>\left\{(\mathfrak A_n,T_{\mathfrak A_n}), n = 1, 2, \ldots\right\}</math>. In this case let <math>\mathfrak U</math> be the  [[Sigma-algebra|''σ''-algebra generated]] by the union <math>\bigcup\{\mathfrak A_n: \, n = 1, 2, \ldots\},</math> which is generally only an [[Field of sets|algebra of sets]]. For the construction of <math>T_{\mathfrak U}</math> it is convenient to identify a set <math>A \subseteq X</math> with its indicator function and to write <math>TA := TI_A=T[I_A].</math> For <math>A \in \mathfrak U</math> let <math>A_n</math> denote the [[conditional expectation]] of <math>A</math> under <math>\mathfrak A_n</math>. By [[Doob's martingale convergence theorems|Doob's martingale convergence theorem]] the set <math>\theta(A)</math> of points where <math>A_n</math> converges to 1 differs negligibly from&nbsp;''A''.
-Here are a few facts that are straightforward to check (some use the completeness and finiteness of <math>(X,\mathfrak U,\mu)</math>):
-:<math> \tau:=\{\theta(A)\setminus N \ : \ A\in\mathfrak U, \mu(N)=0\}\subset\mathfrak U</math>
-is a topology whose only negligible open set is the empty set and such that every <math> A=I_A\in\mathfrak U</math> is almost everywhere continuous, to wit, on <math> A\cap\theta(A)</math> and on <math> A^c\cap\theta(A^c)</math>. Then every <math>f \in\mathcal L^\infty(X,\mathfrak U,\mu)</math>, being the uniform limit of a sequence of step functions over <math>\mathfrak U</math>, is almost everywhere continuous in this topology. For ''p'' in ''X''
-:<math> I_p:=\{[f]: f \text{ is continuous at } p \text{ and }f(p)=0\}.</math>
-is a proper ideal of <math> L^\infty(X,\mathfrak U,\mu)</math>, contained (by another application of Zorn's lemma) in some maximal proper ideal <math> J_p\subset L^\infty(X,\mathfrak U,\mu)</math>, which has codimension 1. The quotient map <math>L^\infty(X,\mathfrak U,\mu)\to L^\infty(X,\mathfrak U,\mu)/J_p</math> can be viewed as a character<ref name=character/>''T''<sub>''p''</sub>. Defining
-:<math> \left(T_{\mathfrak U}[f]\right)(p):=T_p[f]\;\;,\;\;\;\;\;\;p\in E,</math>
+Here are a few facts that are straightforward to check (some use the completeness and finiteness of <math>(X, \mathfrak U, \mu)</math>):
+<math display=block>\tau := \{\theta(A)\setminus N \ : \ A\in\mathfrak U, \mu(N) = 0\}\subset\mathfrak U</math>
+is a topology whose only negligible open set is the empty set and such that every <math> A=I_A\in\mathfrak U</math> is almost everywhere continuous, to wit, on <math> A\cap\theta(A)</math> and on <math> A^c\cap\theta(A^c)</math>. Then every <math>f \in\mathcal L^\infty(X,\mathfrak U,\mu)</math>, being the uniform limit of a sequence of step functions over <math>\mathfrak U</math>, is almost everywhere continuous in this topology. For <math>p</math> in <math>X</math>
+<math display=block>I_p:=\{[f]: f \text{ is continuous at } p \text{ and }f(p) = 0\}.</math>
+is a proper ideal of <math> L^\infty(X,\mathfrak U,\mu)</math>, contained (by another application of Zorn's lemma) in some maximal proper ideal <math>J_p\subset L^\infty(X, \mathfrak U, \mu),</math> which has codimension 1. The quotient map <math>L^\infty(X, \mathfrak U, \mu) \to L^\infty(X, \mathfrak U,\mu) / J_p</math> can be viewed as a character<ref name=character/>''T''<sub>''p''</sub>. Defining
+<math display=block>\left(T_{\mathfrak U}[f]\right)(p):=T_p[f]\;\;,\;\;\;\;\;\;p\in E,</math>
 provides the upper bound <math>(\mathfrak U,T_{\mathfrak U})</math> for the chain <math>\mathfrak C</math>.
@@ Line 60: / Line 53: @@
 and a small additional calculation shows that <math> \mathfrak U=\mathfrak F</math>. END OF DETAILED PROOF-->
-== Strong liftings ==
+==Strong liftings==
-Suppose (''X'', Σ, ''μ'') is complete and ''X'' is equipped with a completely regular Hausdorff topology τ ⊂ Σ such that the union of any collection of negligible open sets is again negligible &ndash; this is the case if (''X'', Σ, ''μ'') is ''σ''-finite or comes from a [[Radon measure]]. Then the ''support'' of ''μ'', Supp(''μ''), can be defined as the complement of the largest negligible open subset, and the collection ''C<sub>b</sub>''(''X'', ''τ'') of bounded continuous functions belongs to <math> \mathcal L^\infty(X,\Sigma,\mu)</math>.
+Suppose <math>(X, \Sigma, \mu)</math> is complete and <math>X</math> is equipped with a completely regular Hausdorff topology <math>\tau \subseteq \Sigma</math> such that the union of any collection of negligible open sets is again negligible &ndash; this is the case if <math>(X, \Sigma, \mu)</math> is ''σ''-finite or comes from a [[Radon measure]]. Then the ''support'' of <math>\mu,</math> <math>\operatorname{Supp}(\mu),</math> can be defined as the complement of the largest negligible open subset, and the collection <math>C_b(X, \tau)</math> of bounded continuous functions belongs to <math> \mathcal L^\infty(X, \Sigma, \mu).</math>
-A '''strong lifting''' for (''X'', Σ, ''μ'') is a lifting
-:<math> T:L^\infty(X,\Sigma,\mu)\to \mathcal L^\infty(X,\Sigma,\mu)</math>
-such that ''Tφ'' = ''φ'' on Supp(''μ'') for all φ in ''C<sub>b</sub>''(''X'', τ). This is the same as requiring that<ref>''U'', Supp(''μ'') are identified with their indicator functions.</ref> ''TU'' ≥ (''U'' ∩ Supp(''μ'')) for all open sets ''U'' in&nbsp;''τ''.
+A '''strong lifting''' for <math>(X, \Sigma, \mu)</math> is a lifting
-<blockquote>'''Theorem.''' If (Σ, ''μ'') is ''σ''-finite and complete and ''τ'' has a countable basis then (''X'', Σ, ''μ'') admits a strong lifting.</blockquote>
+<math display=block>T : L^\infty(X, \Sigma, \mu) \to \mathcal{L}^\infty(X, \Sigma, \mu)</math>
+such that <math>T\varphi = \varphi</math> on <math>\operatorname{Supp}(\mu)</math> for all <math>\varphi</math> in <math>C_b(X, \tau).</math> This is the same as requiring that<ref><math>U,</math> <math>\operatorname{Supp}(\mu)</math> are identified with their indicator functions.</ref> <math>T U \geq (U \cap \operatorname{Supp}(\mu))</math> for all open sets <math>U</math> in <math>\tau.</math>
-'''Proof.''' Let ''T''<sub>0</sub> be a lifting for (''X'', Σ, ''μ'') and {''U''<sub>1</sub>, ''U''<sub>2</sub>, ...} a countable basis for ''τ''. For any point ''p'' in the negligible set
+<blockquote>'''Theorem.''' If <math>(\Sigma, \mu)</math> is ''σ''-finite and complete and <math>\tau</math> has a countable basis then <math>(X, \Sigma, \mu)</math> admits a strong lifting.</blockquote>
+'''Proof.''' Let <math>T_0</math> be a lifting for <math>(X, \Sigma, \mu)</math> and <math>U_1, U_2, \ldots</math> a countable basis for <math>\tau.</math> For any point <math>p</math> in the negligible set
-:<math>N:=\bigcup\nolimits _n \left\{p\in \mathrm{Supp}(\mu): (T_0U_n)(p)<U_n(p) \right\}</math>
+<math display=block>N := \bigcup\nolimits_n \left\{p \in \operatorname{Supp}(\mu) : (T_0U_n)(p) < U_n(p)\right\}</math>
-let ''T<sub>p</sub>'' be any character<ref name=character>A ''character'' on a unital algebra is a multiplicative linear functional with values in the coefficient field that maps the unit to 1.</ref> on ''L''<sup>∞</sup>(''X'', Σ, ''μ'') that extends the character φ ↦ φ(''p'') of ''C<sub>b</sub>''(''X'', τ). Then for ''p'' in ''X'' and [''f''] in ''L''<sup>∞</sup>(''X'', Σ, ''μ'') define:
+let <math>T_p</math> be any character<ref name=character>A ''character'' on a unital algebra is a multiplicative linear functional with values in the coefficient field that maps the unit to 1.</ref> on <math>L^\infty(X, \Sigma, \mu)</math> that extends the character <math>\phi \mapsto \phi(p)</math> of <math>C_b(X, \tau).</math> Then for <math>p</math> in <math>X</math> and <math>[f]</math> in <math>L^\infty(X, \Sigma, \mu)</math> define:
+<math display=block>(T[f])(p):= \begin{cases} (T_0[f])(p)& p\notin N\\
-:<math> (T[f])(p):= \begin{cases} (T_0[f])(p)& p\notin N\\
 T_p[f]& p\in N.
 \end{cases}</math>
+<math>T</math> is the desired strong lifting.
-''T'' is the desired strong lifting.
 ==Application: disintegration of a measure==
-Suppose (''X'', Σ, ''μ''), (''Y'', Φ, ν) are ''σ''-finite measure spaces (''μ'', ''ν'' positive) and ''π'' : ''X'' → ''Y'' is a measurable map. A '''disintegration of ''μ'' along ''π'' with respect to ''ν''''' is a slew <math>Y\ni y\mapsto \lambda_y</math> of positive ''σ''-additive measures on (''X'', Σ) such that
+Suppose <math>(X, \Sigma, \mu)</math> and <math>(Y, \Phi, \nu)</math> are ''σ''-finite measure spaces (<math>\mu, \mu</math> positive) and <math>\pi : X \to Y</math> is a measurable map. A '''disintegration of <math>\mu</math> along <math>\pi</math> with respect to <math>\nu</math>''' is a slew <math>Y \ni y \mapsto \lambda_y</math> of positive ''σ''-additive measures on <math>(\Sigma, \mu)</math> such that
-#λ<sub>''y''</sub> is carried by the fiber <math>\pi^{-1}(\{y\})</math> of π over ''y'':
-:::<math> \{y\}\in\Phi\;\;\mathrm{ and }\;\; \lambda_y\left((X\setminus \pi^{-1}(\{y\})\right)=0 \qquad \forall y\in Y</math>
-#for every ''μ''-integrable function ''f'',
-:::<math> \int_X f(p)\;\mu(dp)= \int_Y \left(\int_{\pi^{-1}(\{y\})}f(p)\,\lambda_y(dp)\right) \nu(dy) \qquad (*)</math>
-::in the sense that, for ''ν''-almost all ''y'' in ''Y'', ''f'' is ''λ''<sub>''y''</sub>-integrable, the function
-:::<math> y\mapsto \int_{\pi^{-1}(\{y\})} f(p)\,\lambda_y(dp) </math>
-::is ν-integrable, and the displayed equality (*) holds.
+#<math>\lambda_y</math> is carried by the fiber <math>\pi^{-1}(\{y\})</math> of <math>\pi</math> over <math>y</math>, i.e. <math> \{y\} \in \Phi </math> and <math> \lambda_y\left((X\setminus \pi^{-1}(\{y\})\right) = 0 </math> for almost all <math> y \in Y </math>
-[[Disintegration theorem|Disintegrations]] exist in various circumstances, the proofs varying but almost all using strong liftings. Here is a rather general result. Its short proof gives the general flavor.
+#for every <math>\mu</math>-integrable function <math>f,</math><math display=block>\int_X f(p)\;\mu(dp)= \int_Y \left(\int_{\pi^{-1}(\{y\})} f(p)\,\lambda_y(dp)\right) \nu(dy) \qquad (*)</math> in the sense that, for <math>\nu</math>-almost all <math>y</math> in <math>Y,</math> <math>f</math> is <math>\lambda_y</math>-integrable, the function <math display=block>y \mapsto \int_{\pi^{-1}(\{y\})} f(p)\,\lambda_y(dp) </math> is <math>\nu</math>-integrable, and the displayed equality <math>(*)</math> holds.
+[[Disintegration theorem|Disintegrations]] exist in various circumstances, the proofs varying but almost all using strong liftings. Here is a rather general result. Its short proof gives the general flavor.
-<blockquote>'''Theorem.''' Suppose ''X'' is a Polish<ref>A separable space is ''Polish'' if its topology comes from a complete metric. In the present situation it would be sufficient to require that ''X'' is ''Suslin'', i.e., is the continuous Hausdorff image of a polish space.</ref> space and ''Y'' a separable Hausdorff space, both equipped with their Borel ''σ''-algebras. Let ''μ'' be a ''σ''-finite Borel measure on ''X'' and π : ''X'' → ''Y'' a Σ, Φ&ndash;measurable map. Then there exists a σ-finite Borel measure ν on ''Y'' and a disintegration (*).
+<blockquote>'''Theorem.''' Suppose <math>X</math> is a [[Polish space]]<ref>A separable space is ''Polish'' if its topology comes from a complete metric. In the present situation it would be sufficient to require that <math>X</math> is ''Suslin'', that is, is the continuous Hausdorff image of a Polish space.</ref> and <math>Y</math> a separable Hausdorff space, both equipped with their Borel ''σ''-algebras. Let <math>\mu</math> be a ''σ''-finite Borel measure on <math>X</math> and <math>\pi : X \to Y</math> a <math>\Sigma, \Phi-</math>measurable map. Then there exists a σ-finite Borel measure <math>\nu</math> on <math>Y</math> and a disintegration (*).
-If ''μ'' is finite, ''ν'' can be taken to be the pushforward<ref>The ''pushforward'' ''π''<sub>∗</sub>''μ'' of ''μ'' under ''π'', also called the image of ''μ'' under ''π'' and denoted ''π''(''μ''), is the measure ν on Φ defined by <math>\nu(A):=\mu\left(\pi^{-1}(A)\right)</math> for ''A'' in Φ.</ref> ''π''<sub>∗</sub>''μ'', and then the ''λ''<sub>''y''</sub> are probabilities.</blockquote>
+If <math>\mu</math> is finite, <math>\nu</math> can be taken to be the pushforward<ref>The ''pushforward'' <math>\pi_* \mu</math> of <math>\mu</math> under <math>\pi,</math> also called the image of <math>\mu</math> under <math>\pi</math> and denoted <math>\pi(\mu),</math> is the measure <math>\nu</math> on <math>\Phi</math> defined by <math>\nu(A) := \mu\left(\pi^{-1}(A)\right)</math> for <math>A</math> in <math>\Phi</math>.</ref> <math>\pi_* \mu,</math> and then the <math>\lambda_y</math> are probabilities.</blockquote>
-'''Proof.''' Because of the polish nature of ''X'' there is a sequence of compact subsets of ''X'' that are mutually disjoint, whose union has negligible complement, and on which π is continuous. This observation reduces the problem to the case that both ''X'' and ''Y'' are compact and π is continuous, and ''ν'' = ''π''<sub>∗</sub>''μ''. Complete Φ under ''ν'' and fix a strong lifting ''T'' for (''Y'', Φ, ''ν''). Given a bounded ''μ''-measurable function  ''f'', let <small><math>\lfloor f\rfloor</math></small> denote its conditional expectation under π, i.e., the [[Radon–Nikodym theorem|Radon-Nikodym derivative]] of<ref>''fμ'' is the measure that has density ''f'' with respect to ''μ''</ref> ''π''<sub>∗</sub>(''fμ'') with respect to ''π''<sub>∗</sub>''μ''. Then set, for every ''y'' in ''Y'', <math>\lambda_y(f):=T(\lfloor f\rfloor)(y).</math> To show that this defines a disintegration is a matter of bookkeeping and a suitable Fubini theorem. To see how the strongness of the lifting enters, note that
+'''Proof.''' Because of the polish nature of <math>X</math> there is a sequence of compact subsets of <math>X</math> that are mutually disjoint, whose union has negligible complement, and on which <math>\pi</math> is continuous. This observation reduces the problem to the case that both <math>X</math> and <math>Y</math> are compact and <math>\pi</math> is continuous, and <math>\nu = \pi_* \mu.</math> Complete <math>\Phi</math> under <math>\nu</math> and fix a strong lifting <math>T</math> for <math>(Y, \Phi, \nu).</math> Given a bounded <math>\mu</math>-measurable function <math>f,</math> let <small><math>\lfloor f\rfloor</math></small> denote its conditional expectation under <math>\pi,</math> that is, the [[Radon–Nikodym theorem|Radon-Nikodym derivative]] of<ref><math>f \mu</math> is the measure that has density <math>f</math> with respect to <math>\mu</math></ref> <math>\pi_*(f \mu)</math> with respect to <math>\pi_* \mu.</math> Then set, for every <math>y</math> in <math>Y,</math> <math>\lambda_y(f) := T(\lfloor f\rfloor)(y).</math> To show that this defines a disintegration is a matter of bookkeeping and a suitable Fubini theorem. To see how the strongness of the lifting enters, note that
-:<math> \lambda_y(f\cdot\varphi\circ\pi)=\varphi(y) \lambda_y(f) \qquad \forall y\in Y, \varphi\in C_b(Y), f\in L^\infty(X,\Sigma,\mu)</math>
+<math display=block>\lambda_y(f \cdot \varphi \circ \pi) = \varphi(y) \lambda_y(f) \qquad \forall y\in Y, \varphi \in C_b(Y), f \in L^\infty(X, \Sigma, \mu)</math>
+and take the infimum over all positive <math>\varphi</math> in <math>C_b(Y)</math> with <math>\varphi(y) = 1;</math> it becomes apparent that the support of <math>\lambda_y</math> lies in the fiber over <math>y.</math>
+==References==
-and take the infimum over all positive ''φ'' in ''C''<sub>''b''</sub>(''Y'') with ''φ''(''y'') = 1; it becomes apparent that the support of ''λ''<sub>''y''</sub> lies in the fiber over&nbsp;''y''.
+{{reflist}}
-== References ==
+{{Measure theory}}
-<references />
 [[Category:Measure theory]]