Code Block Segmentation and Configuration for Concatenated Turbo and RS Coding

Organization Name

TEXAS INSTRUMENTS INCORPORATED

Inventor(s)

June Chul Roh of Allen TX (US)

Pierre Bertrand of Antibes (FR)

Code Block Segmentation and Configuration for Concatenated Turbo and RS Coding - A simplified explanation of the abstract

This abstract first appeared for US patent application 18527738 titled 'Code Block Segmentation and Configuration for Concatenated Turbo and RS Coding

Simplified Explanation

The abstract describes a method for performing code block segmentation for wireless transmission using concatenated forward error correction encoding. This method involves receiving a transport block of data for transmission with a specified size and target code rate, determining the number of inner code blocks needed to transmit the data, calculating the number of outer code blocks based on encoding parameters, and segmenting and encoding the transport block accordingly.

• The method involves receiving a transport block of data for wireless transmission.
• The transport block has a specified size and target code rate.
• The number of inner code blocks needed to transmit the data is determined.
• The number of outer code blocks is calculated based on encoding parameters.
• The transport block is segmented and encoded according to the calculated encoding parameters.

Potential Applications

This technology can be applied in wireless communication systems, such as 5G networks, to improve the reliability and efficiency of data transmission.

Problems Solved

This technology solves the problem of ensuring reliable and error-free transmission of data over wireless networks by using concatenated forward error correction encoding.

Benefits

The benefits of this technology include improved data transmission reliability, increased efficiency in wireless communication systems, and enhanced error correction capabilities.

Potential Commercial Applications

One potential commercial application of this technology is in the development of advanced wireless communication systems for various industries, including telecommunications, IoT, and autonomous vehicles.

Possible Prior Art

One possible prior art for this technology could be existing methods for error correction coding in wireless communication systems, such as Turbo codes or LDPC codes.

Unanswered Questions

How does this technology compare to existing error correction coding methods in terms of performance and efficiency?

This article does not provide a direct comparison between this technology and existing error correction coding methods.

What are the specific encoding parameters used in the calculation of outer code blocks, and how do they impact the overall performance of the system?

The article does not delve into the specific encoding parameters used in the calculation of outer code blocks and their impact on system performance.

Original Abstract Submitted

A method for performing code block segmentation for wireless transmission using concatenated forward error correction encoding includes receiving a transport block of data for transmission having a transport block size, along with one or more parameters that define a target code rate. A number N of inner code blocks needed to transmit the transport block is determined. A number M—outer code blocks may be calculated based on the number of inner code blocks and on encoding parameters for the outer code blocks. The transport block may then be segmented and encoded according to the calculated encoding parameters.