BEAM BASED MEASUREMENT AND RESOURCE MANAGEMENT TECHNIQUES FOR WIRELESS COMMUNICATIONS SYSTEMS

Organization Name

QUALCOMM Incorporated

Inventor(s)

Anantharaman Balasubramanian of San Diego CA (US)

Shuanshuan Wu of San Diego CA (US)

Kapil Gulati of Belle Mead NJ (US)

Navid Abedini of Basking Ridge NJ (US)

Junyi Li of Fairless Hills PA (US)

Sourjya Dutta of San Diego CA (US)

Hui Guo of Beijing (CN)

BEAM BASED MEASUREMENT AND RESOURCE MANAGEMENT TECHNIQUES FOR WIRELESS COMMUNICATIONS SYSTEMS - A simplified explanation of the abstract

This abstract first appeared for US patent application 18257563 titled 'BEAM BASED MEASUREMENT AND RESOURCE MANAGEMENT TECHNIQUES FOR WIRELESS COMMUNICATIONS SYSTEMS

Simplified Explanation

The abstract describes methods, systems, and devices for wireless communications, specifically focusing on full-duplex communications between two user equipment (UE) devices. The first UE receives sidelink control information from the second UE, which includes information about reserved resources and transmit beam directions. Based on this information, the first UE can receive and transmit messages using specific beams.

• Wireless communications system enabling full-duplex communications between user equipment (UE) devices
• Sidelink control information exchanged between UEs to facilitate communication
• Information includes reserved resources and transmit beam directions
• First UE receives and transmits messages using specific beams for efficient communication

Potential Applications

This technology could be applied in various industries and scenarios, including:

• Internet of Things (IoT) devices communication
• Vehicle-to-vehicle communication for autonomous driving
• Emergency communication systems for first responders

Problems Solved

This technology addresses several challenges in wireless communications, such as:

• Efficient use of resources for full-duplex communications
• Minimizing interference between UEs in close proximity
• Enhancing reliability and speed of data transmission

Benefits

The benefits of this technology include:

• Improved communication reliability and speed
• Enhanced spectrum efficiency
• Better utilization of resources for wireless networks

Potential Commercial Applications

This technology has potential commercial applications in:

• Telecommunications industry for 5G and beyond
• Smart city infrastructure for connected devices
• Military and defense applications for secure communications

Possible Prior Art

One possible prior art for this technology could be the use of beamforming techniques in wireless communications to improve signal quality and coverage.

Unanswered Questions

How does this technology impact battery life in user equipment devices?

The abstract does not mention the impact of this technology on the battery life of user equipment devices. It would be important to understand if the use of specific beams and reserved resources affects the power consumption of the devices.

What is the scalability of this technology for large-scale deployments?

The abstract does not provide information on the scalability of this technology for large-scale deployments. It would be crucial to know how well this system can handle a high volume of user equipment devices communicating simultaneously.

Original Abstract Submitted

Methods, systems, and devices for wireless communications are described. A first user equipment (UE) may receive, from a second UE, sidelink control information for performing full-duplex communications with the second UE. The sidelink control information may include an indication of resources reserved by the second UE, an indication of one or more transmit beam directions associated with the resources reserved by the second UE, or both. The first UE may receive, via the resources reserved by the second UE, a first message using a first receive beam based on the sidelink control information. The first UE may transmit, via the resources reserved by the second UE, a second message using a first transmit beam of the first UE, a direction of the first transmit beam being different from a direction of the first receive beam.