WiMi Hologram Cloud Inc. announced a lightweight blockchain-based architecture to overcome the limitations of traditional network architectures and provide a more secure, efficient and trusted connectivity solution for the 5G Internet of Things (IoT). Conventional 5G networks use security measures such as encryption during data transmission, but there are still certain risks associated with data storage and authentication. Data may be tampered with or stolen during transmission or storage, a risk that becomes particularly acute in massively deployed IoT scenarios.

Therefore, there is an urgent need for a more secure and reliable network architecture to secure IoT devices and data. In addition, more and more applications are placing higher demands on real-time performance and reliability. Traditional network architectures may not be able to meet these demands, especially in the case of large-scale device connectivity and data exchange, where network latency and failure rates may increase significantly, affecting application performance and user experience.

Blockchain technology, as an emerging distributed ledger technology, has unique advantages in terms of data security and trusted transmission. Its decentralized, tamper-proof, and transparent nature makes it ideal for addressing data security and trustworthiness issues. Therefore, combining blockchain technology with 5G IoT can provide new solutions to address the challenges faced by current network architectures.

WiMi's new technology integrates 5G technology with lightweight blockchain consensus algorithms to provide an efficient, secure, and reliable way to connect IoT devices. The technology incorporates network architecture, blockchain structure and transaction types to provide a new connectivity solution to support 5G IoT. In this architecture, IoT devices are connected to the blockchain network via a 5G network, creating a distributed and secure communication environment.

Local transactions occur between devices within the same cellular, do not need to cross network boundaries, and are characterized by low latency and high reliability. Public transactions, on the other hand, involve data exchanges between different cellulars and need to be verified and stored by the public blockchain to ensure data security. The technology enables efficient, secure and reliable connectivity by combining 5G technology with lightweight blockchain unanimous algorithms with its technical advantages: Increased security: Through improved hashing and encryption protocols, the architecture outperforms traditional 5G networks in preventing data manipulation and fraud.

Blockchain technology's immutability and distributed storage ensure data security. Real-time data transmission: Combining the high-speed transmission of 5G technology and the real-time verification mechanism of blockchain, the architecture ensures the ability to transmit real-time data and meets the demand for immediacy in various application scenarios. Low-latency connectivity: Optimized for data transmission and consensus processing algorithms, the architecture ensures low-latency connectivity, providing faster response and more efficient interactions for communication between IoT devices.

High availability and reliability: With distributed storage and consensus mechanisms, the architecture ensures high reliability of the system, even in the case of partial node failure or network congestion. In the digital era, the rapid development of 5G IoT places higher demands on connectivity, security and reliability. By combining 5G technology with lightweight Blockchain consensus algorithms, WiMi provides a more secure, efficient, and trustworthy way for IoT devices to connect.

WiMi's technical architecture combines network architecture, blockchain structure, and transaction types designed to meet the needs of various application scenarios. An analysis of performance evaluation and technical benefits demonstrates the significant advantages of the architecture in terms of real-time data transfer, security and latency optimization.