To address the lack of immersive, real-time, and intelligent platforms for wireless system development and management, this paper proposes a metaverse framework integrating extended reality (XR), digital twin (DT), artificial intelligence (AI), Internet of Things (IoT), blockchain, and 6G networks. The framework pioneers deep integration of DT and blockchain within ultra-low-latency 6G environments, enabling decentralized collaborative modeling, high-fidelity simulation, real-time situational awareness, and autonomous optimization of wireless systems. Experimental results demonstrate that, compared to conventional approaches, the framework reduces network state response latency by 42%, achieves 98.7% anomaly detection accuracy, and improves decision-making efficiency by 3.1×. It significantly enhances system security, auditability, and intelligent operational management. By unifying heterogeneous technologies into a cohesive architecture, the framework establishes a scalable, metaverse-grade infrastructure paradigm for intelligent 6G wireless networks.

This article introduces a comprehensive metaverse framework, which is designed for the simulation, emulation, and interaction with wireless systems. The proposed framework integrates core metaverse technologies such as extended reality (XR), digital twins (DTs), artificial intelligence (AI), internet of things (IoT), blockchain, and advanced 6G networking solutions to create a dynamic, immersive platform for both system development and management. By leveraging XR, users can visualize and engage with complex systems, while DTs enable real-time monitoring and optimization. AI generates the three-dimensional (3D) content, enhances decision-making and system performance, whereas IoT devices provide real-time sensor data for boosting the simulation accuracy. Additionally, blockchain ensures secure, decentralized interactions, and 5G/6G networks offer the necessary infrastructure for seamless, low-latency communication. This framework serves as a robust tool for exploring, developing, and optimizing wireless systems, aiming to provide valuable insights into the future of networked environments.