Quantum Spread-Spectrum CDMA Communication Systems: Mathematical Foundations

TL;DR

This paper establishes the mathematical foundations of quantum spread spectrum CDMA systems, introducing a novel operator decomposition method to analyze quantum signals and their interference in quantum communication networks.

Contribution

It presents a new chip-time decomposition approach for quantum signals, enabling closed-form analysis of quantum spread spectrum systems and their interference effects.

Findings

Decomposition of quantum signals into chip-time operators

Closed-form relations for quantum signals at the receiver

Analysis of interference and entanglement effects in quantum systems

Abstract

This paper describes the fundamental principles and mathematical foundations of quantum spread spectrum code division multiple access (QCDMA) communication systems. The evolution of quantum signals through the direct-sequence spread spectrum multiple access communication system is carefully characterized by a novel approach called the decomposition of creation operators. In this methodology, the creation operator of the transmitted quantum signal is decomposed into the chip-time interval creation operators each of which is defined over the duration of a chip. These chip-time interval creation operators are the invariant building blocks of the spread spectrum quantum communication systems. With the aid of the proposed chip-time decomposition approach, we can find closed-form relations for quantum signals at the receiver of such a quantum communication system. Further, the paper details the principles of narrow-band filtering of quantum signals required at the receiver, a crucial step in designing and analyzing quantum communication systems. We show that by employing coherent states as the transmitted quantum signals, the inter-user interference appears as an additive term in the magnitude of the output coherent (Glauber) state, and the output of the quantum communication system is a pure quantum signal. On the other hand, if the transmitters utilize particle-like quantum signals (Fock states) such as single photon states, entanglement and a spread spectrum version of the Hong-Ou-Mandel effect can arise at the receivers. The important techniques developed in this paper are expected to have far-reaching implications for various applications in the exciting field of quantum communication and signal processing.