18065618. SPACE TIME CODING FOR SIDELINK TRANSMISSIONS simplified abstract (QUALCOMM Incorporated)
Contents
- 1 SPACE TIME CODING FOR SIDELINK TRANSMISSIONS
- 1.1 Organization Name
- 1.2 Inventor(s)
- 1.3 SPACE TIME CODING FOR SIDELINK TRANSMISSIONS - A simplified explanation of the abstract
- 1.4 Simplified Explanation
- 1.5 Key Features and Innovation
- 1.6 Potential Applications
- 1.7 Problems Solved
- 1.8 Benefits
- 1.9 Commercial Applications
- 1.10 Prior Art
- 1.11 Frequently Updated Research
- 1.12 Questions about Multi-Rank Sidelink Communications
- 1.13 Original Abstract Submitted
SPACE TIME CODING FOR SIDELINK TRANSMISSIONS
Organization Name
Inventor(s)
Gideon Shlomo Kutz of Ramat Hasharon (IL)
Amit Bar-or Tillinger of Tel-Aviv (IL)
SPACE TIME CODING FOR SIDELINK TRANSMISSIONS - A simplified explanation of the abstract
This abstract first appeared for US patent application 18065618 titled 'SPACE TIME CODING FOR SIDELINK TRANSMISSIONS
Simplified Explanation
The patent application describes techniques to support multi-rank sidelink communications that can be simplified to single-rank communications in case of decoding failure. This involves transmitting messages with different precoding vectors for different layers, allowing for rank reduction if needed.
Key Features and Innovation
- Support for multi-rank sidelink communications
- Ability to reduce to single-rank communications in case of decoding failure
- Transmission of messages using different precoding vectors for different layers
- Derivation of new precoding vectors based on previous ones
- Effective rank reduction when the channel is rank deficient
Potential Applications
The technology could be applied in various communication systems where reliable and efficient data transmission is crucial. It may find use in 5G networks, Internet of Things (IoT) devices, and other wireless communication applications.
Problems Solved
The technology addresses the challenge of maintaining communication reliability in multi-rank sidelink scenarios. By allowing for rank reduction in case of decoding failure, it ensures that data can still be transmitted effectively even under adverse conditions.
Benefits
- Improved reliability in multi-rank sidelink communications
- Enhanced efficiency in data transmission
- Flexibility to adapt to varying channel conditions
- Potential for increased network performance and capacity
Commercial Applications
- Enhanced performance in 5G networks
- Improved connectivity for IoT devices
- Potential for use in smart city infrastructure
- Applications in industrial automation and remote monitoring systems
Prior Art
Further research can be conducted in the field of multi-rank communications and precoding techniques to explore existing technologies and innovations related to this patent application.
Frequently Updated Research
Stay informed about advancements in wireless communication technologies, particularly in the areas of multi-rank communications, precoding, and channel rank adaptation.
Questions about Multi-Rank Sidelink Communications
How does the technology ensure reliable data transmission in multi-rank sidelink scenarios?
The technology allows for rank reduction to single-rank communications if decoding failure occurs, ensuring that data can still be effectively transmitted even under adverse conditions.
What are the potential applications of this technology beyond 5G networks?
The technology could be applied in various wireless communication systems, including IoT devices, smart city infrastructure, and industrial automation, to improve reliability and efficiency in data transmission.
Original Abstract Submitted
The described techniques may support multi-rank sidelink communications that may be reduced to single rank communications if failure to decode the multi-rank sidelink communications occurs. A user equipment (UE) may transmit a first message including first data using a first precoding vector applied for a first layer and a second precoding vector applied for a second layer. If the first message is not decoded successfully, the UE may transmit a second message including second data using a third precoding vector applied for the first layer and a fourth precoding vector applied for the second layer, where the second data is derived from the first data, the third precoding vector is derived from the second precoding vector, and the fourth precoding vector is derived from the first precoding vector. The second message may effectively reduce a rank of the first message when the channel is rank deficient.