量子逻辑在实验行为科学中的应用

Q2 Physics and Astronomy
L. Narens
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引用次数: 0

摘要

1933年,Kolmogorov将当时普遍使用的概率基本概念综合为概念,并从一组简单的公理中推导出概率是一个σ加性函数,从事件的布尔代数到[0,1]。1932年,冯·诺伊曼意识到在量子力学中使用概率需要一个不同的概念,他将其表述为从希尔伯特空间的闭子空间到[0,1]的σ加性函数。1935年,Birkhoff和von Neumann用代数泛化取代了Hilbert空间。今天,对伯克霍夫-冯·诺伊曼概括的一个轻微修改被称为“量子逻辑”。概率论哲学的一个中心问题是在一个给定的应用中对概率的定义进行论证。这通常是通过论证所考虑的情况的方法的合理性来实现的。de Finetti在1972年提出的荷兰书argument的一个版本经常被用来证明Kolmogorov理论,特别是在科学应用中。正如冯·诺伊曼在1955年所指出的,量子逻辑没有可接受的基础,他的批评至今仍然有效。虽然这里并没有争论量子物理学是否采用了一种理性的方法,但有人认为:(1)在行为科学中发现的许多重要情况下,量子概率论是一种合理的选择,(2)对于行为科学的某些领域,例如Between Subjects实验的行为范式,量子概率论具有可论证的理性基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An Application of Quantum Logic to Experimental Behavioral Science
In 1933, Kolmogorov synthesized the basic concepts of probability that were in general use at the time into concepts and deductions from a simple set of axioms that said probability was a σ-additive function from a boolean algebra of events into [0, 1]. In 1932, von Neumann realized that the use of probability in quantum mechanics required a different concept that he formulated as a σ-additive function from the closed subspaces of a Hilbert space onto [0,1]. In 1935, Birkhoff & von Neumann replaced Hilbert space with an algebraic generalization. Today, a slight modification of the Birkhoff-von Neumann generalization is called “quantum logic”. A central problem in the philosophy of probability is the justification of the definition of probability used in a given application. This is usually done by arguing for the rationality of that approach to the situation under consideration. A version of the Dutch book argument given by de Finetti in 1972 is often used to justify the Kolmogorov theory, especially in scientific applications. As von Neumann in 1955 noted, and his criticisms still hold, there is no acceptable foundation for quantum logic. While it is not argued here that a rational approach has been carried out for quantum physics, it is argued that (1) for many important situations found in behavioral science that quantum probability theory is a reasonable choice, and (2) that it has an arguably rational foundation to certain areas of behavioral science, for example, the behavioral paradigm of Between Subjects experiments.
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来源期刊
Quantum Reports
Quantum Reports Physics and Astronomy-Physics and Astronomy (miscellaneous)
CiteScore
3.30
自引率
0.00%
发文量
33
审稿时长
10 weeks
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