Shenzhen Xunxiao Technology Applies for Patent on "Transaction Data Verification Method and System" to Enhance Blockchain Throughput and Transaction Confirmation Speed

Shenzhen Xunxiao Technology Applies for Patent on "Transaction Data Verification Method and System" to Enhance Blockchain Throughput and Transaction Confirmation SpeedOn December 18, 2024, the State Intellectual Property Office of China revealed that Shenzhen Xunxiao Technology Co., Ltd

Shenzhen Xunxiao Technology Applies for Patent on "Transaction Data Verification Method and System" to Enhance Blockchain Throughput and Transaction Confirmation Speed

On December 18, 2024, the State Intellectual Property Office of China revealed that Shenzhen Xunxiao Technology Co., Ltd. submitted a patent application for a "Transaction Data Verification Method and System," with publication number CN119128991A and an application date of November 2024. This patent aims to significantly improve the performance of blockchain systems, particularly focusing on increasing throughput and transaction confirmation speed.

The patent abstract details this innovative transaction data verification method and system. The core of the method lies in a series of steps designed to efficiently process and verify large volumes of transaction data, thereby avoiding the bottlenecks encountered by traditional blockchain systems when handling high-concurrency transactions. Specifically, the method includes the following key steps:

Step 1: Transaction Data Acquisition

First, the system collects transaction data from various nodes in the blockchain network, compiling all raw transaction data into a complete dataset. This step ensures that all transaction information is included in the verification process, preventing data omission. The integrity and accuracy of this data are fundamental to subsequent verification steps. An efficient data acquisition mechanism is crucial for the overall system performance.

Step 2: Adaptive Heterogeneous Sharding

To address the challenges of processing large-scale transaction data, the patent proposes an adaptive heterogeneous sharding technique. The raw transaction dataset is divided into smaller, more manageable sharded datasets. "Heterogeneous" signifies that the size and content of these shards can be dynamically adjusted based on actual conditions to adapt to varying transaction loads and network conditions. This adaptability is a core advantage of the patented technology, enabling automatic adjustment of sharding strategies based on network load to maximize efficiency. Adaptive sharding avoids the efficiency losses associated with fixed shard sizes, offering greater flexibility.

Step 3: Verification Weight Coefficient Allocation

After sharding the transaction data, the system assigns a verification weight coefficient to each shard. This is not a simple average allocation but is dynamically adjusted based on shard importance, transaction amount, or other relevant factors. The weight coefficient allocation ensures that the system prioritizes more important transactions, improving overall efficiency and security. This weighted allocation mechanism effectively optimizes resource allocation, prioritizing transactions that significantly impact overall system stability.

Step 4: Multi-level Verification Engine Deployment

The patent proposes a multi-level verification engine deployment scheme. This organizes verification nodes into a hierarchical network, with each layer responsible for different verification tasks. This layered structure effectively reduces the risk of single points of failure and enhances the system's fault tolerance. The multi-level architecture also better accommodates different types of verification tasks, improving verification efficiency. This hierarchical deployment model offers greater reliability and scalability.

Step 5: Asynchronous Message Queue Mechanism Configuration

To further enhance efficiency, the system employs an asynchronous message queue mechanism. Verification nodes communicate via message queues rather than synchronous waiting. This allows nodes to concurrently process different verification tasks, significantly reducing overall verification time. The asynchronous message queue mechanism effectively avoids efficiency bottlenecks caused by synchronous waiting, making full use of network resources and efficiently managing task distribution to improve system throughput.

Step 6: Load Balancing Scheduling

Finally, the system allocates the weighted sharded transaction datasets to various nodes in the parallel verification network cluster based on a load balancing strategy. This ensures that the load on each node is as evenly distributed as possible, preventing some nodes from becoming overloaded while others remain idle. Load balancing scheduling is a crucial component for ensuring the stable operation of the system. Optimizing the load balancing algorithm can further improve system stability and reliability.

Through these six steps, Shenzhen Xunxiao Technology's patented "Transaction Data Verification Method and System" is expected to significantly improve blockchain system performance. It can effectively increase blockchain throughput and transaction confirmation speed, which is crucial for the wider adoption of blockchain technology. The innovation of this patented technology lies in its adaptability and multi-level architecture, achieving efficient parallel verification and solving the bottlenecks encountered by blockchain technology when processing large amounts of transaction data. This technology has broad application prospects and is expected to drive further development and application of blockchain technology. We can expect this technology to achieve significant results in practical applications, bringing new breakthroughs to blockchain technology. This will significantly impact the efficiency and security of blockchain, further promoting its application across various industries. Shenzhen Xunxiao Technology's patent application undoubtedly injects new vitality into the future development of blockchain technology.