SYSTEMS, METHODS, AND DEVICES FOR SCHEDULING RESTRICTIONS BASED ON NEEDFORGAP CAPABILITIES OF USER EQUIPMENT

Organization Name

apple inc.

Inventor(s)

Jie Cui of San Jose CA (US)

Dawei Zhang of Saratoga CA (US)

Haitong Sun of Cupertino CA (US)

Hong He of San Jose CA (US)

Huaning Niu of San Jose CA (US)

Manasa Raghavan of Sunnyvale CA (US)

Qiming Li of Beijing (CN)

Xiang Chen of Campbell CA (US)

Yang Tang of San Jose CA (US)

Yushu Zhang of Beijing (CN)

SYSTEMS, METHODS, AND DEVICES FOR SCHEDULING RESTRICTIONS BASED ON NEEDFORGAP CAPABILITIES OF USER EQUIPMENT - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240178962 titled 'SYSTEMS, METHODS, AND DEVICES FOR SCHEDULING RESTRICTIONS BASED ON NEEDFORGAP CAPABILITIES OF USER EQUIPMENT

Simplified Explanation

The patent application describes a method for a user equipment (UE) to support concurrent synchronization signal block (SSB) inter-frequency measurement without a measurement gap. The UE can also support concurrent SSB inter-frequency measurement in intra-band and inter-band scenarios. The UE may report concurrent SSB-based inter-frequency measurement as a needforgap information element, which includes parameters regarding UE measurement capabilities. Scheduling restrictions are enabled based on UE measurement capabilities, including restrictions for frequency range 1 (FR1), frequency range 2 (FR2), and cross-frequency range scenarios.

• User equipment (UE) can perform concurrent synchronization signal block (SSB) inter-frequency measurement without a measurement gap.
• UE can support concurrent SSB inter-frequency measurement in intra-band and inter-band scenarios.
• The needforgap information element includes parameters regarding UE measurement capabilities.
• Scheduling restrictions are enabled based on UE measurement capabilities, including restrictions for different frequency ranges and scenarios.

Potential Applications

This technology can be applied in 5G networks, specifically in scenarios where seamless inter-frequency measurements are required for efficient handover procedures.

Problems Solved

This technology solves the issue of gaps in measurement during inter-frequency handover procedures, ensuring continuous and accurate measurements for improved network performance.

Benefits

The benefits of this technology include enhanced network efficiency, reduced handover delays, and improved user experience in mobile communication systems.

Potential Commercial Applications

Potential commercial applications of this technology include telecommunications equipment manufacturers, network operators, and providers of mobile communication services.

Possible Prior Art

One possible prior art could be methods for inter-frequency measurements in cellular networks, but without the specific focus on concurrent SSB-based measurements without a measurement gap.

Unanswered Questions

How does this technology impact battery life in mobile devices during inter-frequency measurements?

The article does not address the potential impact of this technology on battery life in mobile devices, which could be a crucial factor for user experience and device performance.

Are there any compatibility issues with existing network infrastructure when implementing this technology?

The article does not mention any potential compatibility issues with existing network infrastructure, which could be a concern for network operators and equipment manufacturers looking to adopt this technology.

Original Abstract Submitted

a user equipment (ue) may support concurrent synchronization signal block (ssb) inter-frequency measurement without a measurement gap (mg). the ue may also, or alternatively, support concurrent ssb inter-frequency measurement in intra-band scenarios (e.g., where a target inter-frequency cell and serving cell are on the same band) and/or inter-band scenarios (e.g., where a target inter-frequency cell and serving cell are on the same band). the ue may report concurrent ssb based inter-frequency measurement as a needforgap information element (ie), which may include one or more of a variety of parameters regarding ue measurement capabilities. scheduling restrictions (e.g., restrictions to downlink and uplink communications) are also enabled based on ue measurement capabilities, including scheduling restriction for frequency range 1 (fr1), frequency range 2 (fr2), and cross frequency range scenarios.