Qualcomm incorporated (20240098779). RANDOM ACCESS MESSAGE FOR DEACTIVATED CELL TIMING ADJUSTMENTS simplified abstract
Contents
- 1 RANDOM ACCESS MESSAGE FOR DEACTIVATED CELL TIMING ADJUSTMENTS
- 1.1 Organization Name
- 1.2 Inventor(s)
- 1.3 RANDOM ACCESS MESSAGE FOR DEACTIVATED CELL TIMING ADJUSTMENTS - A simplified explanation of the abstract
- 1.4 Simplified Explanation
- 1.5 Potential Applications
- 1.6 Problems Solved
- 1.7 Benefits
- 1.8 Potential Commercial Applications
- 1.9 Possible Prior Art
- 1.10 Original Abstract Submitted
RANDOM ACCESS MESSAGE FOR DEACTIVATED CELL TIMING ADJUSTMENTS
Organization Name
Inventor(s)
Shanyu Zhou of San Diego CA (US)
Jelena Damnjanovic of Del Mar CA (US)
Ozcan Ozturk of San Diego CA (US)
RANDOM ACCESS MESSAGE FOR DEACTIVATED CELL TIMING ADJUSTMENTS - A simplified explanation of the abstract
This abstract first appeared for US patent application 20240098779 titled 'RANDOM ACCESS MESSAGE FOR DEACTIVATED CELL TIMING ADJUSTMENTS
Simplified Explanation
The abstract describes methods, systems, and devices for updating timing advance values for deactivated cells in a wireless communication network. A user equipment (UE) can transmit a random access message to a deactivated cell for a timing advance probing procedure. The UE may receive an activation command and a timing advance value for the cell from another cell, or monitor for a random access response message from the deactivated cell containing the same information. The UE can then communicate with the cell based on the received timing advance value.
- User equipment (UE) transmits random access message to deactivated cell for timing advance probing.
- UE receives activation command and timing advance value from another cell or from deactivated cell's response message.
- UE communicates with cell based on received timing advance value.
Potential Applications
This technology can be applied in various wireless communication networks to efficiently update timing advance values for deactivated cells, improving network performance and reliability.
Problems Solved
1. Updating timing advance values for deactivated cells in a wireless communication network. 2. Ensuring accurate timing advance values for optimal network performance.
Benefits
1. Improved network performance and reliability. 2. Efficient updating of timing advance values for deactivated cells. 3. Enhanced communication between user equipment and cells.
Potential Commercial Applications
Optimizing timing advance values in wireless communication networks can benefit telecommunications companies, network operators, and equipment manufacturers looking to enhance network efficiency and user experience.
Possible Prior Art
One possible prior art related to this technology is the use of timing advance values in cellular networks to synchronize transmissions between mobile devices and base stations. This technology builds upon existing methods by specifically focusing on updating timing advance values for deactivated cells in the network.
Unanswered Questions
How does this technology impact battery life of user equipment in wireless communication networks?
This article does not address the potential impact of updating timing advance values on the battery life of user equipment. Further research is needed to understand if this technology has any implications on power consumption.
What are the potential security implications of transmitting random access messages to deactivated cells in a wireless communication network?
The article does not discuss the security aspects of sending random access messages to deactivated cells. It would be important to investigate any potential vulnerabilities or risks associated with this process to ensure the integrity and confidentiality of communication in the network.
Original Abstract Submitted
methods, systems, and devices for updating timing advance values for deactivated cells are described. a user equipment (ue) may transmit, to a first cell that is deactivated, a random access message for a timing advance probing procedure. the ue may transmit the random access message to the first cell. in some examples, the ue may receive, from a second cell, an activation command that activates the first cell and an indication of a timing advance value for the first cell generated based on the random access message. in other examples, the ue may monitor for a random access response (rar) message from the first cell, the rar message including an activation command that activates the first cell and an indication of a timing advance value generated based on the random access message. the ue may communicate with the first cell based on the activation command and the timing advance value.