Glivenko–Cantelli classes and NIP formulas

IF 0.4 4区数学 Q4 LOGIC

Archive for Mathematical Logic Pub Date : 2024-06-03 DOI:10.1007/s00153-024-00932-7

Karim Khanaki

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引用次数: 0

Abstract

We give several new equivalences of NIP for formulas and new proofs of known results using Talagrand (Ann Probab 15:837–870, 1987) and Haydon et al. (in: Functional Analysis Proceedings, The University of Texas at Austin 1987–1989, Lecture Notes in Mathematics, Springer, New York, 1991). We emphasize that Keisler measures are more complicated than types (even in the NIP context), in an analytic sense. Among other things, we show that for a first order theory T and a formula $\phi (x,y)$, the following are equivalent:

(i)
$\phi $ has NIP with respect to T.
(ii)
For any global $\phi $-type p(x) and any model M, if p is finitely satisfiable in M, then p is generalized DBSC definable over M. In particular, if M is countable, then p is DBSC definable over M. (Cf. Definition 3.7, Fact 3.8.)
(iii)
For any global Keisler $\phi $-measure $\mu (x)$ and any model M, if $\mu $ is finitely satisfiable in M, then $\mu $ is generalized Baire-1/2 definable over M. In particular, if M is countable, $\mu $ is Baire-1/2 definable over M. (Cf. Definition 3.9.)
(iv)
For any model M and any Keisler $\phi $-measure $\mu (x)$ over M,
$$\begin{aligned} \sup _{b\in M}\Big |\frac{1}{k}\sum _{i=1}^k\phi (p_i,b)-\mu (\phi (x,b))\Big |\rightarrow 0, \end{aligned}$$
for almost every $(p_i)\in S_{\phi }(M)^{\mathbb N}$ with the product measure $\mu ^{\mathbb N}$. (Cf. Theorem 4.4.)
(v)
Suppose moreover that T is countable and NIP, then for any countable model M, the space of global M-finitely satisfied types/measures is a Rosenthal compactum. (Cf. Theorem 5.1.)

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格利文科-康特利类和 NIP 公式

我们利用塔拉格兰德（Ann Probab 15:837-870, 1987）和海顿等人（in：功能分析论文集，德克萨斯大学奥斯汀分校，1987-1989 年，数学讲座笔记，施普林格，纽约，1991 年）。我们强调，从分析意义上讲，Keisler 度量比类型（即使在 NIP 范畴内）更复杂。除其他外，我们证明对于一阶理论 T 和公式（\phi (x,y)\), 以下内容是等价的： (i)$\phi $ 相对于 T 具有 NIP。(ii)For any global $\phi $-typep(x)和任何模型 M, if p is finitely satisfiable in M, then p is generalized DBSC definable over M. In particular, if M is countable, then p is DBSC definable over M. (Cf. Definition 3.(iii)For any global Keisler $\phi $-测度 $\mu (x)$ and any model M, if $\mu $ is finitely satisfiable in M, then $\mu $ is generalized Baire-1/2 definable over M.(参见定义3.9。)(iv)对于任何模型M和任何凯斯勒（Keisler）在M上的度量（(\mu (x)\)），$$\begin{aligned}。\sup _{b\in M}\Big |\frac{1}{k}\sum _{i=1}^k\phi (p_i,b)-\mu (\phi (x,b))\Big |\rightarrow 0、\end{aligned}$$ 对于几乎每一个 S_{\phi }(M)^{\mathbb N} 中的 $(p_i)$都有乘积度量 $\mu ^{\mathbb N}$.(参见定理 4.4。)(v)再假设 T 是可数和 NIP 的，那么对于任何可数模型 M，全局 M 无限满足类型/度量的空间是一个罗森塔尔紧凑集。

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来源期刊

Archive for Mathematical Logic 数学-数学

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期刊介绍： The journal publishes research papers and occasionally surveys or expositions on mathematical logic. Contributions are also welcomed from other related areas, such as theoretical computer science or philosophy, as long as the methods of mathematical logic play a significant role. The journal therefore addresses logicians and mathematicians, computer scientists, and philosophers who are interested in the applications of mathematical logic in their own field, as well as its interactions with other areas of research.