NETWORK OPTIMIZATION METHOD AND COMMUNICATION APPARATUS

Organization Name

huawei technologies co., ltd.

Inventor(s)

Xingxing Hu of Shanghai (CN)

Xudong Yang of Shanghai (CN)

NETWORK OPTIMIZATION METHOD AND COMMUNICATION APPARATUS - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240163719 titled 'NETWORK OPTIMIZATION METHOD AND COMMUNICATION APPARATUS

Simplified Explanation

The abstract of the patent application describes a network optimization method involving the exchange of information between a first access network device and a terminal device. The first information sent includes application layer measurement configuration information, network slice scope information, or a service type. The network slice scope information contains at least one network slice identifier. The second information received includes a first application layer measurement result and identification information related to the measurement result, which includes an identifier of a protocol data unit (PDU) session.

• Explanation of the patent/innovation:
• The method involves optimizing network performance by exchanging specific information between network devices and terminal devices.
• The information exchanged includes details about application layer measurements, network slice scope, and service types.
• Network slice scope information helps identify specific network slices for targeted optimization.
• The received information includes measurement results and identification data for tracking and analysis.

Potential Applications

The technology can be applied in various industries and scenarios, including:

• Telecommunications for improving network performance and quality of service.
• Internet of Things (IoT) for optimizing connectivity and data transmission.
• Cloud computing for enhancing data processing and communication efficiency.

Problems Solved

The technology addresses several challenges, such as:

• Ensuring optimal network performance and resource allocation.
• Enhancing the user experience by improving service quality.
• Streamlining network management and monitoring processes.

Benefits

The technology offers the following benefits:

• Improved network efficiency and reliability.
• Enhanced data transmission and communication capabilities.
• Better resource utilization and allocation.

Potential Commercial Applications

The technology can be utilized in various commercial applications, including:

• Network service providers for offering enhanced services to customers.
• IoT companies for optimizing device connectivity and data transfer.
• Cloud service providers for improving data processing and storage efficiency.

Possible Prior Art

One possible prior art related to this technology is the use of network slicing in 5G networks to optimize network resources and provide customized services to users.

Unanswered Questions

How does the technology handle security and privacy concerns in data exchange between network devices and terminal devices?

The patent abstract does not provide details on the security measures implemented in the network optimization method. It would be essential to understand how the technology ensures data confidentiality and integrity during information exchange.

What are the scalability limitations of the network optimization method in handling a large volume of data traffic?

The abstract does not mention the scalability aspects of the technology. It would be crucial to investigate how the method copes with increasing data traffic and network complexity to maintain optimal performance.

Original Abstract Submitted

a network optimization method includes sending, by a first access network device, first information to a terminal device, and receiving, by the first access network device, second information from the terminal device. the first information includes application layer measurement configuration information, network slice scope information or a service type. the network slice scope information includes at least one network slice identifier. the second information includes a first application layer measurement result corresponding to the first information and identification information corresponding to the first application layer measurement result. the identification information includes an identifier of a protocol data unit (pdu) session.