Quantum Keyless Private Communication with Decoy States for Space Channels

TL;DR

This paper introduces a secure quantum communication protocol using decoy states for space channels, enhancing security against eavesdroppers and applicable to inter-satellite links without needing eavesdropper location knowledge.

Contribution

It presents a novel keyless quantum private communication protocol with decoy states, improving security in space optical channels and applicable to current space technology.

Findings

Guarantees positive secrecy capacity against high photon energy eavesdroppers

Applicable to optical inter-satellite links with secure link margin

Potential advantage using future squeezed quantum states

Abstract

With the increasing demand for secure communication in optical space networks, it is essential to develop physical-layer scalable security solutions. In this context, we present the asymptotic security analysis of a keyless quantum private communication protocol that transmits classical information over quantum states. Different from the previous literature, our protocol sends dummy (decoy) states optimally obtained from the true information to deceive the eavesdropper. We analyze optical on-off keying (OOK) and binary phase shift keying (BPSK) for several detection scenarios. Our protocol significantly improves the protocol without decoy states whenever Bob is at a technological disadvantage with respect to Eve. Our protocol guarantees positive secrecy capacity when the eavesdropper gathers up to $90-99.9\%$ (depending on the detection scenario) of the photon energy that Bob detects, even when Eve is only limited by the laws of quantum mechanics. We apply our results to the design of an optical inter-satellite link (ISL) study case with pointing losses, and introduce a new design methodology whereby the link margin is guaranteed to be secure by our protocol. Hence, our design does not require knowing thr location of the eavesdropper and or channel state: the protocol aborts whenever the channel drops below the secured margin. Our protocol can be implemented with the state of the art space proof technology. Finally, we also show the potential secrecy advantage when using (not yet available) squeezed quantum states technology.