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法图引理

在测度论中，法图引理说明了一个函数列的下极限的积分（在勒贝格意义上）和其积分的下极限的不等关系。法图引理的名称来源于法国数学家皮埃尔·法图（Pierre Fatou），被用来证明测度论中的法图-勒贝格定理和勒贝格控制收敛定理。

叙述

设 $(S,\Sigma ,\mu )$ 为一个测度空间， ${\displaystyle (f_{n})_{n\geq 0))$ 是一个实值的可测正值函数列。那么：

\int _{S}\liminf _{n\to \infty }f_{n}\,d\mu \leq \liminf _{n\to \infty }\int _{S}f_{n}\,d\mu \,.

其中的函数极限是在逐点收敛的意义上的极限，函数的取值和积分可以是无穷大。

证明

定理的证明基于单调收敛定理（非常容易证明）。设 $f$ 为函数列 ${\displaystyle (f_{n})_{n\geq 0))$ 的下极限。对每个正整数 $k$ ，逐点定义下极限函数：

g_{k}=\inf _{n\geq k}f_{n}.

于是函数列 $g_{1},g_{2},\ldots$ 单调递增并趋于 $f$ 。

任意 $k\leq n$ ，我们有 ${\displaystyle g_{k}\leq f_{n))$ ，因此

\int _{S}g_{k}\,d\mu \leq \int _{S}f_{n}\,d\mu ,

于是

\int _{S}g_{k}\,d\mu \leq \inf _{n\geq k}\int _{S}f_{n}\,d\mu .

据此，由单调收敛定理以及下极限的定义，就有：

\int _{S}\liminf _{n\to \infty }f_{n}\,d\mu =\lim _{k\to \infty }\int _{S}g_{k}\,d\mu \leq \lim _{k\to \infty }\inf _{n\geq k}\int _{S}f_{n}\,d\mu =\liminf _{n\to \infty }\int _{S}f_{n}\,d\mu \,.

反向法图引理

令 $(f_{n})$ 为测度空间 $(S,\Sigma ,\mu )$ 中的一列可测函数，函数的值域为扩展实数（包括无穷大）。如果存在一个在 $S$ 上可积的正值函数 $g$ ，使得对所有的 $n$ 都有 $f_{n}\leq g$ ，那么

\int _{S}\limsup _{n\to \infty }f_{n}\,d\mu \geq \limsup _{n\to \infty }\int _{S}f_{n}\,d\mu .

这里 $g$ 只需弱可积，即 $\textstyle \int _{S}g\,d\mu <\infty$ 。

证明：对函数列 $(g-f_{n})$ 应用法图引理即可。

推广

推广到任意实值函数

法图引理不仅对取正值的函数列成立，在一定限制条件下，可以扩展到任意的实值函数。令 ${\displaystyle (f_{n})_{n\geq 0))$ 为测度空间 $(S,\Sigma ,\mu )$ 中的一列可测函数，函数的值域为扩展实数（包括无穷大）。如果存在一个在 $S$ 上可积的正值函数 $g$ ，使得对所有的 $n$ 都有 $f_{n}\geq g$ ，那么

证明：对函数列 $\scriptstyle (f_{n}-g)$ 应用法图引理即可。

逐点收敛

在以上的条件下，如果函数列在 $S$ 上μ-几乎处处逐点收敛到一个函数 $\scriptstyle f$ ，那么

\int _{S}f\,d\mu \leq \liminf _{n\to \infty }\int _{S}f_{n}\,d\mu \,.

证明： $\scriptstyle f$ 是函数列的极限，因此自然是下极限。此外，零测集上的差异对于积分值没有影响。

依测度收敛

如果函数列在 $S$ 上依测度收敛到 $f$ ，那么上面的命题仍然成立。

证明：存在 $\scriptstyle (f_{n})$ 的一个子列使得

\lim _{k\to \infty }\int _{S}f_{n_{k))\,d\mu =\liminf _{n\to \infty }\int _{S}f_{n}\,d\mu \,.

这个子列仍然依测度收敛到 $\scriptstyle f$ ，于是又存在这个子列的一个子列在 $S$ 上μ-几乎处处逐点收敛到 $f$ ，于是命题成立。

外部链接

法图引理. PlanetMath.

参考来源

H.L. Royden, "Real Analysis", Prentice Hall, 1988.

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