Satellite-Based Quantum Key Distribution in the Presence of Bypass Channels

TL;DR

This paper investigates the security of satellite-based quantum key distribution when the eavesdropper has limited access due to bypass channels, revealing scenarios where system performance can be significantly improved under such restrictions.

Contribution

It introduces generic bounds on key rates considering bypass channels and demonstrates improved performance regimes for various QKD protocols under restricted eavesdropping.

Findings

Bypass channels can enhance key rates in certain regimes.

BB84 protocol can achieve positive key rates at high losses with restrictions on Eve.

Limiting Eve's access effectively reduces channel loss, improving security.

Abstract

The security of prepare-and-measure satellite-based quantum key distribution (QKD), under restricted eavesdropping scenarios, is addressed. We particularly consider cases where the eavesdropper, Eve, has limited access to the transmitted signal by Alice, and/or Bob's receiver station. This restriction is modeled by lossy channels between Alice/Bob and Eve, where the transmissivity of such channels can, in principle, be bounded by monitoring techniques. An artefact of such lossy channels is the possibility of having {\it bypass} channels, those which are not accessible to Eve, but may not necessarily be characterized by the users either. This creates interesting, unexplored, scenarios for analyzing QKD security. In this paper, we obtain generic bounds on the key rate in the presence of bypass channels and apply them to continuous-variable QKD protocols with Gaussian encoding with direct and reverse reconciliation. We find regimes of operation in which the above restrictions on Eve can considerably improve system performance. We also develop customised bounds for several protocols in the BB84 family and show that, in certain regimes, even the simple protocol of BB84 with weak coherent pulses is able to offer positive key rates at high channel losses, which would otherwise be impossible under an unrestricted Eve. In this case the limitation on Eve would allow Alice to send signals with larger intensities than the optimal value under an ideal Eve, which effectively reduces the effective channel loss. In all these cases, the part of the transmitted signal that does not reach Eve can play a non-trivial role in specifying the achievable key rate. Our work opens up new security frameworks for spaceborne quantum communications systems.