Conceptual variables, quantum theory, and statistical inference theory

TL;DR

This paper proposes a novel epistemic interpretation of quantum theory based on conceptual variables and group representation, connecting quantum states to questions posed to nature and their sharp answers, with implications for foundations and paradoxes.

Contribution

It introduces a new epistemic framework for quantum theory using conceptual variables and group actions, deriving operators and the Born rule, and relating quantum states to questions and answers.

Findings

Derives operators from group representation theory for accessible variables

Connects quantum states to focused questions and sharp answers

Discusses implications for quantum paradoxes and statistical inference

Abstract

A different approach towards quantum theory is proposed in this paper. The basis is taken to be conceptual variables, physical variables that may be accessible or inaccessible, i.e., it may be possible or impossible to assign numerical values to them. In an epistemic process, the accessible variables are just ideal observations as observed by an actor or by some communicating actors. Group actions are defined on these variables, and using group representation theory this is the basis for developing the Hilbert space formalism here. Operators corresponding to accessible conceptual variables are derived as a result of the formalism, and in the discrete case it is argued that the possible physical values are the eigenvalues of these operators. The Born formula is derived under specific assumptions. The whole discussion here is a supplement to the author's book [1]. The interpretation of quantum states (or eigenvector spaces) implied by this approach is as focused questions to nature together with sharp answers to those questions. Resolutions if the identity are then connected to the questions themselves; these may be complementary in the sense defined by Bohr. This interpretation may be called a general epistemic interpretation of quantum theory. It is similar to Zwirn's recent Convival Solipsism, and also to QBism, and more generally, can be seen as a concrete implementation of Rovelli's Relational Quantum Mechanics. The focus in the present paper is, however, as much on foundation as on interpretation. But the simple consequences of an epistemic interpretation for some so called quantum paradoxes are discussed. Connections to statistical inference theory are discussed in a preliminary way, both through an example and through a brief discussion of quantum measurement theory.