METHOD AND DEVICE FOR QUASI-STATIC SCHEDULING IN WIRELESS COMMUNICATION SYSTEM

Organization Name

SAMSUNG ELECTRONICS CO., LTD.

Inventor(s)

Suha Yoon of Suwon-si (KR)

Seho Myung of Suwon-si (KR)

Jeongho Yeo of Suwon-si (KR)

Euichang Jung of Suwon-si (KR)

METHOD AND DEVICE FOR QUASI-STATIC SCHEDULING IN WIRELESS COMMUNICATION SYSTEM - A simplified explanation of the abstract

This abstract first appeared for US patent application 18154420 titled 'METHOD AND DEVICE FOR QUASI-STATIC SCHEDULING IN WIRELESS COMMUNICATION SYSTEM

Simplified Explanation

The present disclosure is about a communication system that supports higher data transmission rates than 4G systems, such as LTE. The system is specifically designed for 5th generation (5G) or pre-5G networks.

• The method described in the patent involves a terminal in the communication system.
• The terminal receives configuration information about semi-static scheduling.
• It also receives downlink control information (DCI) through a physical downlink control channel (PDCCH).
• The terminal checks if the DCI activates the semi-static scheduling.
• It further checks if the semi-static scheduling is configured in a specific bandwidth part (BWP) indicated by a BWP indicator included in the DCI.
• If the semi-static scheduling is not configured in the BWP, the terminal discards the DCI.

Potential Applications

This technology can be applied in various industries and scenarios where high-speed data transmission is required. Some potential applications include:

• Telecommunications: This technology can be used to enhance the performance and capacity of 5G networks, enabling faster and more reliable communication.
• Internet of Things (IoT): With higher data transmission rates, IoT devices can transmit and receive data more efficiently, enabling seamless connectivity and improved IoT applications.
• Autonomous Vehicles: The technology can support the high-speed data requirements of autonomous vehicles, enabling real-time communication and data exchange between vehicles and infrastructure.
• Virtual Reality (VR) and Augmented Reality (AR): Higher data transmission rates are crucial for delivering immersive VR and AR experiences, and this technology can help in achieving that.

Problems Solved

This technology addresses several problems in communication systems:

• Higher Data Transmission Rates: The technology enables higher data transmission rates compared to 4G systems, meeting the increasing demand for faster and more reliable communication.
• Efficient Resource Allocation: The semi-static scheduling and BWP configuration ensure efficient allocation of network resources, optimizing the use of available bandwidth.
• Reduced Interference: By discarding DCIs that are not configured in the BWP, the technology helps in reducing interference and improving overall network performance.

Benefits

The benefits of this technology are:

• Faster Data Transmission: The higher data transmission rates supported by this technology enable faster communication, improving user experience and enabling new applications.
• Improved Network Efficiency: The efficient resource allocation and reduced interference contribute to improved network efficiency, allowing more users and devices to connect simultaneously.
• Enhanced Reliability: The technology ensures that DCIs are only processed when they are configured in the BWP, reducing errors and improving the reliability of the communication system.

Original Abstract Submitted

The present disclosure relates to a 5th generation (5G) or pre-5G communication system for supporting higher data transmission rates than 4th generation (4G) communication systems such as Long Term Evolution (LTE). According to an embodiment according to the present disclosure, provided is a method performed in a communication system by a terminal. The method performed by the terminal operation may include receiving configuration information about semi-static scheduling; receiving downlink control information (DCI) through a physical downlink control channel (PDCCH); checking whether the DCI activates the semi-static scheduling; checking whether the semi-static scheduling is configured in a bandwidth part (BWP), indicated by a BWP indicator included in the DCI, when the semi-static scheduling is activated; and discarding the DCI when the semi-static scheduling is not configured in the BWP.