Effective Simulation of Quantum Entanglement using Classical Fields Modulated with Pseudorandom Phase Sequences

TL;DR

This paper demonstrates how classical fields modulated with pseudorandom phase sequences can effectively simulate quantum entanglement, including Bell and GHZ states, with results aligning with quantum criteria.

Contribution

The study introduces a novel classical simulation method for quantum entanglement using pseudorandom phase modulated fields, extending to multi-particle systems.

Findings

Successfully simulated Bell and GHZ states

Results strictly comply with quantum entanglement criteria

Applicable to systems with multiple quantum particles

Abstract

An effective simulation of quantum entanglement is presented using classical fields modulated with n pseudorandom phase sequences (PPSs) that constitute a n2^n-dimensional Hilbert space with a tensor product structure. Applications to classical fields are examplied by effective simulation of both Bell and GHZ states, and a correlation analysis was performed to characterize the simulation. Results that strictly comply with criteria of quantum entanglement were obtained and the approach was also shown to be applicable to a system consisting of n quantum particles.