Invariant Set Theory
Abstract
Invariant Set Theory (IST) is a realistic, locally causal theory of fundamental physics which assumes a much stronger synergy between cosmology and quantum physics than exists in contemporary theory. In IST the (quasi-cyclic) universe is treated as a deterministic dynamical system evolving precisely on a measure-zero fractal invariant subset of its state space. In this approach, the geometry of , and not a set of differential evolution equations in space-time , provides the most primitive description of the laws of physics. As such, IST is non-classical. The geometry of is based on Cantor sets of space-time trajectories in state space, homeomorphic to the algebraic set of -adic integers, for large but finite . In IST, the non-commutativity of position and momentum observables arises from number theory - in particular the non-commensurateness of and . The complex Hilbert Space and the relativistic Dirac Equation respectively are shown to describe , and evolution on , in the singular limit of IST at ; particle properties such as de Broglie relationships arise from the helical geometry of trajectories on in the neighbourhood of . With the p-adic metric as a fundamental measure of distance on , certain key perturbations which seem conspiratorially small relative to the more traditional Euclidean metric, take points away from and are therefore unphysically large. This allows (the -epistemic) IST to evade the Bell and Pusey et al theorems without fine tuning or other objections. In IST, the problem of quantum gravity becomes one of combining the pseudo-Riemannian metric of with the p-adic metric of . A generalisation of the field equations of general relativity which can achieve this is proposed.
Cite
@article{arxiv.1605.01051,
title = {Invariant Set Theory},
author = {T. N. Palmer},
journal= {arXiv preprint arXiv:1605.01051},
year = {2016}
}
Comments
Phys Rev D In Review. supercedes arXiv:1502.06968