Critical elements in algebras of numerical events

TL;DR

This paper investigates the structure of algebras of numerical events in physical systems, highlighting the role of critical events in determining classical or quantum behavior and how enlarging the state space affects the logical structure.

Contribution

It introduces the concept of critical numerical events and analyzes their influence on the classicality or non-classicality of physical systems within algebraic frameworks.

Findings

Critical events can alter the classical or quantum nature of the system.

Enlarging the state space impacts the algebraic and logical structure of numerical events.

The study clarifies how numerical events shape the logic of physical systems.

Abstract

The probability p(s) of the occurrence of an event pertaining to a physical system which is observed in different states s determines a function p from the set S of states of the system to [0,1]. The function p is called a numerical event or more precisely an S-probability. When appropriately structured, sets P of numerical events form so-called algebras of S-probabilities, which are orthomodular posets that can serve as quantum logics. If one deals with a classical physical system, then P will be a Boolean algebra. Starting with a supposed quantum logic or logics obtained by individual measurements, newly added numerical events may turn out to be crucial for the assumption of classicality or non-classicality of the physical system. We will call those numerical events critical and will study their impacts among various classes of algebras of numerical events. Moreover, we will consider the situation of enlarging S by new states and will describe how elements of an algebra of S-probabilities contribute to the character of a logic when there exists a certain relation between them and the element that is newly added.