METHOD FOR WIRELESS COMMUNICATION USING BEAMFORMED PHYSICAL DOWNLINK CONTROL CHANNEL (PDCCH)

Organization Name

INDIAN INSTITUTE OF TECHNOLOGY HYDERABAD (IITH)

Inventor(s)

Pavan Kumar Reddy Manne of Kandi (IN)

Harish Kumar Dureppagari of Kandi (IN)

Saidhiraj Amuru of Madinaguda (IN)

Kiran Kumar Kuchi of Madinaguda (IN)

METHOD FOR WIRELESS COMMUNICATION USING BEAMFORMED PHYSICAL DOWNLINK CONTROL CHANNEL (PDCCH) - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240244619 titled 'METHOD FOR WIRELESS COMMUNICATION USING BEAMFORMED PHYSICAL DOWNLINK CONTROL CHANNEL (PDCCH)

The method described in the patent application involves optimizing wireless communication by efficiently allocating resources based on channel estimates and metrics calculated for each user equipment (UE) and beam associated with a base station (BS).

• Receiving signals from multiple UEs and obtaining channel estimates for each UE.
• Calculating metrics for each UE and beam associated with the BS.
• Determining the best beams for each UE based on the calculated metrics.
• Segregating UEs into groups based on the best beams and additional metrics.
• Performing beamforming and resource allocation for the control channel based on the segregated groups.

Potential Applications: - Enhanced wireless communication in cellular networks. - Improved network efficiency and capacity. - Enhanced user experience through optimized resource allocation.

Problems Solved: - Efficient resource allocation in wireless communication networks. - Optimization of beamforming for improved signal quality. - Enhanced network performance and user satisfaction.

Benefits: - Increased network capacity and throughput. - Enhanced signal quality and coverage. - Improved user experience and satisfaction.

Commercial Applications: Title: "Optimized Resource Allocation for Enhanced Wireless Communication" This technology can be applied in telecommunications companies, network equipment manufacturers, and wireless service providers to improve network performance and user experience. It can lead to more efficient use of resources, increased network capacity, and enhanced signal quality, ultimately benefiting both service providers and end-users.

Prior Art: Readers interested in prior art related to this technology can explore research papers, patents, and industry publications on beamforming, resource allocation in wireless networks, and optimization techniques for cellular communication systems.

Frequently Updated Research: Researchers in the field of wireless communication are constantly exploring new methods to optimize resource allocation, improve network efficiency, and enhance user experience. Stay updated on the latest advancements in beamforming technology and network optimization techniques to leverage the full potential of this innovation.

Questions about Wireless Communication Optimization: 1. How does this method improve network efficiency compared to traditional resource allocation techniques? - The method optimizes resource allocation by considering channel estimates and metrics for each UE and beam, leading to more efficient use of resources and improved network performance.

2. What are the key benefits of segregating UEs into groups based on the best beams and additional metrics? - Segregating UEs into groups allows for targeted resource allocation and beamforming, resulting in enhanced signal quality, coverage, and overall network efficiency.

Original Abstract Submitted

embodiments of the present disclosure are related a method for wireless communication. the method comprises receiving by a base station (bs), signals from a plurality of user equipment's (ues) and obtaining channel estimates associated with each ue using the received signals. next. calculating a first metric for each ue, and each of the plurality of beams associated with the bs using the obtained channel estimates and determining one or more best beams from a plurality of beams associated with the bs. and a second metric for each ue using the first metric. further, segregating the ues into groups based on the determined one or more best beams and the second metric. thereafter. performing beamforming on control channel based on the one or more best beams, and performing allocation of at least one of resources, modulation and coding scheme for a control channel based on the segregated groups.