Abstract: Methods and apparatuses for coding a codeword. An apparatus for decoding the codeword includes a memory configured to receive the codeword encoded based on a low-density parity check (LDPC) code H-matrix and a two-step lifting matrix and processing circuitry configured to decode the received codeword. An apparatus for encoding the codeword includes memory configured to store information bits to be encoded into the codeword and processing circuitry configured to encode the codeword based on based on a LDPC code H-matrix and a two-step lifting matrix. A code length of the LDPC code H-matrix lifted by the two-step lifting matrix is an integer multiple of 672 bits. The LDPC code block H-matrix may be an IEEE 802.11ad standard LDPC coding matrix. The two-step lifting matrix can be one of a plurality of two-step lifting matrices to generate a family of LDPC codes.

Abstract: Methods and apparatuses for coding a codeword. An apparatus for decoding the codeword includes a memory configured to receive the codeword encoded based on a low-density parity check (LDPC) code H-matrix and a two-step lifting matrix and processing circuitry configured to decode the received codeword. An apparatus for encoding the codeword includes memory configured to store information bits to be encoded into the codeword and processing circuitry configured to encode the codeword based on based on a LDPC code H-matrix and a two-step lifting matrix. A code length of the LDPC code H-matrix lifted by the two-step lifting matrix is an integer multiple of 672 bits. The LDPC code block H-matrix may be an IEEE 802.11ad standard LDPC coding matrix. The two-step lifting matrix can be one of a plurality of two-step lifting matrices to generate a family of LDPC codes.

Abstract: A receiver in a communication system is provided that includes a synchronization module and a channel estimator. The synchronization module is configured to identify an end of a cyclic prefix (CP) in a received signal using slope detection by monitoring a detection metric threshold in the received signal. The channel estimator is configured to estimate a complex noise variance using guard band subcarriers.

Abstract: A receiver in a communication system is provided that includes a synchronization module and a channel estimator. The synchronization module is configured to identify an end of a cyclic prefix (CP) in a received signal using slope detection by monitoring a detection metric threshold in the received signal. The channel estimator is configured to estimate a complex noise variance using guard band subcarriers.

Abstract: A receiver capable of decoding encoded transmissions. The receiver includes a number of receive antennas for receiving data; a plurality of memory units for storing the received data; and a number of decoders configured to perform a Low Density Parity Check (LDPC) decoding operation. Each of the decoders further is configured to independently decode at least a portion of the received data using a portion of a decoding matrix. Each of the number of decoders coordinates the low density parity check decoding operation with other decoders. The decoders can use a parallel process, a pipeline process or a combination of a parallel and pipeline process.

Abstract: A receiver capable of decoding encoded transmissions. The receiver includes a number of receive antennas for receiving data; a plurality of memory units for storing the received data; and a number of decoders configured to perform a Low Density Parity Check (LDPC) decoding operation. Each of the decoders further is configured to independently decode at least a portion of the received data using a portion of a decoding matrix. Each of the number of decoders coordinates the low density parity check decoding operation with other decoders. The decoders can use a parallel process, a pipeline process or a combination of a parallel and pipeline process.

Abstract: A software-defined radio (SDR) system that operates under a plurality of wireless communication standards. The SDR system comprises a reconfigurable maximum aposteriori probability (MAP) decoder capable of being configured under software control to decode a received data block according to a select wireless communication standard and a reconfigurable interleaver associated with the reconfigurable MAP decoder. The reconfigurable interleaver comprises a reconfigurable interleaver core circuitry capable of being configured under software control to operate according to the selected wireless communication standard and a unified interleaver interface for coupling a defined set of control and bus signals from the reconfigurable MAP decoder to the reconfigurable interleaver core circuitry.

Abstract: A decoder comprising a demodulator operable to receive a plurality of encoded data bits and generate a demodulated output, a channel decoder coupled to the demodulator operable to receive the demodulated output and generate decoded data bits, an encoder coupled to the channel decoder operable to receive the decoded data bits and re-encode the decoded data bits and generate re-encoded data bits, a comparator coupled to the demodulator and the encoder and operable to compare the demodulated output and the re-encoded data bits and generate an error rate, and wherein the error rate from the comparator is used to modify an operating parameter of the channel decoder.