Towards Quantifying Complexity with Quantum Mechanics
Abstract
While we have intuitive notions of structure and complexity, the formalization of this intuition is non-trivial. The statistical complexity is a popular candidate. It is based on the idea that the complexity of a process can be quantified by the complexity of its simplest mathematical model - the model that requires the least past information for optimal future prediction. Here we review how such models, known as -machines can be further simplified through quantum logic, and explore the resulting consequences for understanding complexity. In particular, we propose a new measure of complexity based on quantum -machines. We apply this to a simple system undergoing constant thermalization. The resulting quantum measure of complexity aligns more closely with our intuition of how complexity should behave.
Cite
@article{arxiv.1404.6255,
title = {Towards Quantifying Complexity with Quantum Mechanics},
author = {Ryan Tan and Daniel R. Terno and Jayne Thompson and Vlatko Vedral and Mile Gu},
journal= {arXiv preprint arXiv:1404.6255},
year = {2014}
}
Comments
10 pages, 6 figure, Published in the Focus Point on Quantum information and complexity edition of EPJ Plus