REPORTING AND TRIGGERING FOR LOW-POWER WAKE-UP SIGNAL MONITORING

Organization Name

Apple Inc.

Inventor(s)

Sigen Ye of Whitehouse Station NJ (US)

Seyed Ali Akbar Fakoorian of San Diego CA (US)

Wei Zeng of Saratoga CA (US)

Ankit Bhamri of Bad Nauheim (DE)

Dawei Zhang of Saratoga CA (US)

Hong He of San Jose CA (US)

Chunxuan Ye of San Diego CA (US)

Weidong Yang of San Diego CA (US)

Huaning Niu of San Jose CA (US)

Chunhai Yao of Beijing (CN)

Oghenekome Oteri of San Diego CA (US)

REPORTING AND TRIGGERING FOR LOW-POWER WAKE-UP SIGNAL MONITORING - A simplified explanation of the abstract

This abstract first appeared for US patent application 18218497 titled 'REPORTING AND TRIGGERING FOR LOW-POWER WAKE-UP SIGNAL MONITORING

Simplified Explanation

The patent application describes techniques for monitoring wake-up signals in a radio resource control connected mode. The method involves a user equipment (UE) determining its capability for wake-up signal monitoring, transmitting this capability to a base station, and then monitoring for wake-up signals while in a sleep state. The UE transitions to an awake state upon detecting a trigger and monitors for downlink transmissions in this state.

• User Equipment (UE) determines capability information for wake-up signal monitoring
• UE transmits capability information to a base station
• UE monitors for wake-up signals while in a sleep state
• UE transitions to an awake state upon detecting a trigger
• UE monitors for downlink transmissions in the awake state

Potential Applications

The technology described in this patent application could be applied in various industries such as telecommunications, Internet of Things (IoT), and smart devices for efficient power management and network connectivity.

Problems Solved

This technology solves the problem of efficiently monitoring wake-up signals in a radio resource control connected mode, allowing devices to conserve power while still being able to quickly respond to triggers and downlink transmissions.

Benefits

The benefits of this technology include improved power efficiency, reduced latency in responding to triggers, and enhanced network connectivity in devices supporting wake-up signal monitoring in a radio resource control connected mode.

Potential Commercial Applications

One potential commercial application of this technology could be in the development of IoT devices that require low power consumption and fast response times to triggers and downlink transmissions.

Possible Prior Art

One possible prior art for this technology could be related to existing methods for power management and network connectivity in wireless devices, but with a specific focus on wake-up signal monitoring in a radio resource control connected mode.

Unanswered Questions

How does this technology impact battery life in devices supporting wake-up signal monitoring?

The patent application does not provide specific details on the impact of this technology on battery life in devices. Further research or testing may be needed to determine the exact effects on battery consumption.

What are the potential security implications of wake-up signal monitoring in a radio resource control connected mode?

The patent application does not address the potential security implications of wake-up signal monitoring. It would be important to consider any vulnerabilities or risks associated with this technology and implement appropriate security measures to mitigate them.

Original Abstract Submitted

Techniques are provided for Wake up signal monitoring in a radio resource control connected (RRC) mode. An example method can include a user equipment (UE) determining capability information associated with wake-up signal (WUS) monitoring, the capability information to include an indication that the UE supports WUS monitoring in a radio resource control (RRC) connected mode. The UE can transmit, to a base station, an indication of the capability. The UE can perform, while in a sleep state in which transmitting and receiving by a main radio is suspended, WUS monitoring to detect a trigger. The UE can transition from the sleep state to the awake state based on the trigger. The UE can monitor for a downlink (DL) transmission in the awake state.