Towards parallel Metaverse: Symbiosis of physical and virtual worlds based on Cybertwin-enabled 6G

Kaiyue Luo , Yumei Wang , Yu Liu , Jiake Li , Jishiyu Ding , Kewu Sun

›› 2025, Vol. 11 ›› Issue (6) : 1843 -1863.

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›› 2025, Vol. 11 ›› Issue (6) :1843 -1863. DOI: 10.1016/j.dcan.2025.05.011
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Towards parallel Metaverse: Symbiosis of physical and virtual worlds based on Cybertwin-enabled 6G
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Abstract

Metaverse, envisioned as the next evolution of the Internet, is expected to evolve into an innovative medium advancing information civilization. Its core characteristics, including ubiquity, seamlessness, immersion, interoperability and metaspatiotemporality, are catalyzing the development of multiple technologies and fostering a convergence between the physical and virtual worlds. Despite its potential, the critical concept of symbiosis, which involves the synchronous generation and management of virtuality from reality and serves as the cornerstone of this convergence, is often overlooked. Additionally, cumbersome service designs, stemming from the intricate interplay of various technologies and inefficient resource utilization, are impeding an ideal Metaverse ecosystem. To address these challenges, we propose a bi-model Parallel Symbiotic Metaverse (PSM) system, engineered with a Cybertwin-enabled 6G framework where Cybertwins mirror Sensing Devices (SDs) and serve a bridging role as autonomous agents. Based on this framework, the system is structured into two models. In the queue model, SDs capture environmental data that Cybertwins then coordinate and schedule. In the service model, Cybertwins manage service requests and collaborate with SDs to make responsive decisions. We incorporate two algorithms to address resource scheduling and virtual service responses, showcasing the synergistic role of Cybertwins. Moreover, our PSM system advocates for the participation of SDs from collaborators, enhancing performance while reducing operational costs for Virtual Service Operator (VSO). Finally, we comparatively analyze the efficiency and complexity of the proposed algorithms, and demonstrate the efficacy of the PSM system across multiple performance indicators. The results indicate our system can be deployed cost-effectively with Cybertwin-enabled 6G.

Keywords

Metaverse / Cybertwin-enabled 6G / Internet of Things (IoT) / Multiple-access Edge Computing (MEC) / Symbiosis of physical and virtual worlds

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Kaiyue Luo, Yumei Wang, Yu Liu, Jiake Li, Jishiyu Ding, Kewu Sun. Towards parallel Metaverse: Symbiosis of physical and virtual worlds based on Cybertwin-enabled 6G. , 2025, 11(6): 1843-1863 DOI:10.1016/j.dcan.2025.05.011

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