An Introduction to Influence Theory: Kinematics and Dynamics

TL;DR

This paper explores influence theory as a foundational physics framework that derives traditional concepts like space, time, and momentum from primitive influence interactions among particles, emphasizing a new approach to understanding physical laws.

Contribution

It advances the kinematics and dynamics within influence theory, providing a novel perspective on how influence-based models can underpin physical concepts.

Findings

Influence events can be consistently quantified to derive space and time.

Observer chains enable tracking and measurement of influence interactions.

The framework offers a new foundation for physical laws based on influence relations.

Abstract

Influence theory is a foundational theory of physics that is not based on traditional empirically defined concepts, such as positions in space and time, mass, energy, or momentum. Instead, the aim is to derive these concepts, and their empirically determined relationships, from a more primitive model. It is postulated that there exist things, which we call particles, that influence one another in a discrete and directed fashion resulting in a partially ordered set of influence events. We consider the problem of consistent quantification of the influence events. Observers are modeled as particle chains (observer chains) as if an observer were able to track a particle and quantify the influence events that the particle experiences. From these quantified influence events, we study consistent quantification of the universe of events based on the observer chains. In this paper, we both review and further develop the kinematics and dynamics of particles from the perspective of influence theory.