Generalized proof of uncertainty relations in terms of commutation relation and interpretation based on action function

TL;DR

This paper presents a generalized proof of the uncertainty relations based on commutation relations and action functions, establishing the de Broglie relation as their foundation and offering a new interpretation aligned with physical phenomena.

Contribution

It introduces an alternative, generalized proof of the uncertainty principle using commutation relations and action functions, and proposes a new interpretation based on the action function.

Findings

De Broglie relation underpins the uncertainty principle.

Wave function form leads to operator conception in quantum mechanics.

Interpretation based on action function aligns with physical phenomena.

Abstract

The uncertainty principle is the most important for the foundations of quantum mechanics but it still remains failed to reach a consensus of its interpretation, which gives rise to debates upon its physical nature. In this work, we address the problem of its foundation from a different aspect to present an alternative formulation for proving the uncertainty relations in a general way in terms of commutation relations and action function. The relationship between the de Broglie relation and the uncertainty principle is studied from a new angle. As a result, it is demonstrated that the de Broglie relation is the foundation of the uncertainty principle. Starting with the origin of the problem, we show that the de Broglie relation provides the form of the wave function and the determined form of the wave function in turn leads to the conception of operators for quantum mechanics, and thus it is possible to provide with the help of the operators and wave function a generalized proof of the uncertainty principle as the law governing ensemble of states. As a decisive solution to the problem, the interpretation of the uncertainty principle in terms of the action function is offered that gives one self-consistent explanation in agreement with the known physical phenomena. Eventually, we show the necessity and possibility of reassessing and improving the foundation and interpretation of the uncertainty principle as a leading principle of quantum mechanics.