Keywords :
conference key agreement; Integrated non-terrestrial and terrestrial network; quantum anonymous communication; quantum anonymous network; Anonymous broadcast; Anonymous Networks; Communications protocols; Conference key agreement; Integrated networks; Quantum anonymous communications; Quantum anonymous network; Quantum network; Terrestrial networks; Software; Information Systems; Hardware and Architecture; Computer Networks and Communications; Photonics; Satellites; Quantum entanglement; Protocols; Repeaters; Quantum repeaters; Computer architecture; Qubit; Quantum state; Optical fibers
Abstract :
[en] Due to optical fiber limitations for quantum communication, global-scale quantum networks are possible only by integrating non-terrestrial components in the overall network architecture. Quantum networks are expected to support distributed tasks for quantum information processing, such as quantum sensing, control, communication, and computing. These networks enable emerging applications that are uniquely quantum or augmented by quantum mechanics. Leveraging quantum resources, anonymous networking can be enhanced to such an extent that even an adversary with control over all network resources cannot trace the message source, achieving perfect untraceability. To provide this untraceable global connectivity, we demonstrate the integration of non-terrestrial networks (NTNs) and terrestrial networks (TNs) for quantum anonymous communication (QAC), highlighting possible architectures and key challenges in these integrated NTN-TN quantum anonymous networks (QANs). To illustrate and benchmark the design of QAC protocols within integrated networks, we present essential quantum protocols such as anonymous conference key agreement (CKA) and anonymous broadcast. In the first case study, we propose a satellite-to-ground quantum anonymous CKA (QA-CKA) protocol and assess the anonymous key exchange rate. This QA-CKA protocol utilizes low Earth orbit satellites to generate anonymous keys among two distinct TN nodes. In the second case study, we develop an air-to-ground quantum anonymous broadcast (QAB) protocol and examine the anonymous broadcast announcement rate. This QAB protocol exploits unmanned aerial vehicles to enable a broadcasting party to transmit classical information anonymously across two distinct TNs. These QAC protocols are simulated with realistic integrated network parameters to provide practical estimates of achievable performance. Furthermore, we discuss future research directions for enabling integrated NTN-TN QANs.
Funding text :
This work was supported in part by the Ministry of Science and ICT (MSIT), South Korea, through the Information Technology Research Center (ITRC) Support Program under Grant IITP-2025-2021-0-02046; in part by the Convergence Security Core Talent Training Business Support Program supervised by the Institute for Information and Communications Technology Planning and Evaluation (IITP) under Grant IITP-2025-RS-2023-00266615; in part by the Project Lux4QCI funded by the Digital Europe Program under Grant GA 101091508; in part by the Project LUQCIA funded by the Government of Luxembourg/SMC; in part by the Canada Excellence Research Chair (CERC) Program under Grant CERC-2022-00109; in part by the U.K. Engineering and Physical Sciences Research Council (EPSRC) through the EPSRC Hub on All Spectrum Connectivity under Grant EP/X040569/1 and Grant EP/ Y037197/1; and in part by the Canada Research Chairs Program under Grant CRC-2022-00187.
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