A decoder circuit includes first and second decoders. The first decoder is a first type of decoder configured to receive data encoded with an error correction code and decode and eliminate errors from a first subset of codewords of the data. The second decoder is a second type of decoder configured receive the data encoded with the error correction code and decode and eliminate errors from a second subset of codewords of the data, different from the first subset of the codewords, without attempting to decode and eliminate errors from the first subset of the codewords.

A method and apparatus for decoding are disclosed. The method includes receiving a first Forward Error Correction (FEC) block of read values, starting a hard-decode process in which a number of check node failures is identified and, during the hard-decode process comparing the identified number of check node failures to a decode threshold. When the identified number of check node failures is not greater than the decode threshold the hard-decode process is continued. When the identified number of check node failures is greater than the decode threshold, the method includes: stopping the hard-decode process prior to completion of the hard-decode process; generating output indicating that additional reads are required; receiving one or more additional FEC blocks of read values, mapping the first FEC block of read values and the additional FEC blocks of read values into soft-input values; and performing a soft-decode process on the soft-input values.

A device includes a data path, a first interface configured to receive a first memory access request from a first peripheral device, and a second interface configured to receive a second memory access request from a second peripheral device. The device further includes an arbiter circuit configured to, in a first clock cycle, a pre-arbitration winner between a first memory access request and a second memory access request based on a first number of credits allocated to a first destination device and a second number of credits allocated to a second destination device. The arbiter circuit is further configured to, in a second clock cycle select a final arbitration winner from among the pre-arbitration winner and a subsequent memory access request based on a comparison of a priority of the pre-arbitration winner and a priority of the subsequent memory access request.

A method for constructing parity-check concatenated polar codes and an apparatus therefor are disclosed. According to an embodiment of the inventive concept, a method for constructing a polar code includes receiving a code length, a message length, and channel information, generating an information set and a parity set of polar codes based on the received code length, the received message length, and the received channel information, and generating a parity node including the information set of elements based on the generated information set and the generated parity set.

A method for constructing parity-check concatenated polar codes and an apparatus therefor are disclosed. According to an embodiment of the inventive concept, a method for constructing a polar code includes receiving a code length, a message length, and channel information, generating an information set and a parity set of polar codes based on the received code length, the received message length, and the received channel information, and generating a parity node including the information set of elements based on the generated information set and the generated parity set.

Techniques related to a QoS-aware decoder architecture for data storage are described. In an example, QoS specifications include a QOS latency specification indicative of an acceptable latency for completing the processing of a data read command. The decoder may store this QOS latency specification. In operation, the decoder generates a latency measurement indicative of the actual latency for the processing. If a comparison of the latency measurement and QOS latency specification indicates a violation of the QOS latency specification, the decoder can terminate the decoding and generate a decoding failure.

Techniques related to a QoS-aware decoder architecture for data storage are described. In an example, QoS specifications include a QOS latency specification indicative of an acceptable latency for completing the processing of a data read command. The decoder may store this QOS latency specification. In operation, the decoder generates a latency measurement indicative of the actual latency for the processing. If a comparison of the latency measurement and QOS latency specification indicates a violation of the QOS latency specification, the decoder can terminate the decoding and generate a decoding failure.

Methods and systems for analyzing data are disclosed. An example method can comprise receiving a first data signal, decoding the first data signal, determining a second data signal based on the decoded first data signal, and determining a modulation error ratio based on a difference between the first data signal and the second data signal.

The present technique relates to a transmission apparatus, a transmission method, a reception apparatus, and a reception method that can ensure favorable communication quality in data transmission using an LDPC code. LDPC coding is performed based on a check matrix of an LDPC code with a code length N of 69120 bits and a code rate r of 13/16 or 14/16. The LDPC code includes information bits and parity bits, and the check matrix includes an information matrix corresponding to the information bits and a parity matrix corresponding to the parity bits. The information matrix is represented by a check matrix initial value table. The check matrix initial value table is a table indicating positions of elements of 1 in the information matrix on the basis of 360 columns and is a predetermined table. The present technique can be applied to, for example, data transmission using the LDPC code.

An apparatus and method for optimizing a physical layer parameter is provided. According to one embodiment, an apparatus includes a first neural network configured to receive a transmission environment and a block error rate (BLER) and generate a value of a physical layer parameter; a second neural network configured to receive the transmission environment the BLER and generate a signal to noise ratio (SNR) value; and a processor connected to the first neural network and the second neural network and configured to receive the transmission environment, the generated physical layer parameter, and the generated SNR, and to generate the BLER.