Abstract: Briefly, according to embodiments of the invention, there is provided a wireless communication system and a method to receive by a base station from a first mobile station a first chain of data symbols transmitted by at least two antennas and having a first transmit diversity, to receive from a second mobile station a second chain of data symbols transmitted by at least two antennas and having a second transmit diversity. Both first and second chains of data symbols are transmitted from the first and second mobile stations at the same time, are modulated according to an Orthogonal Frequency Division Multiplexing (OFDM) scheme and encoded by a space time block codes scheme.

Abstract: Briefly, according to embodiments of the invention, there is provided a wireless communication system and a method to receive by a base station from a first mobile station a first chain of data symbols transmitted by at least two antennas and having a first transmit diversity, to receive from a second mobile station a second chain of data symbols transmitted by at least two antennas and having a second transmit diversity. Both first and second chains of data symbols are transmitted from the first and second mobile stations at the same time, modulated according to an Orthogonal Frequency Division Multiplexing (OFDM) scheme and encoded by a space time block codes scheme.

Abstract: Bidirectional iterative beam forming techniques are described. An apparatus may include a wireless device having an antenna control module operative to initiate beam formation operations using an iterative training scheme to form a pair of communications channels for a wireless network, the antenna control module to communicate training signals and feedback information with a peer device via the transceiver and phased antenna array using partially or fully formed high rate channels, and iteratively determine antenna-array weight vectors for a directional transmit beam pattern for the phased antenna array using feedback information from the peer device. Other embodiments are described and claimed.

Abstract: Briefly, in accordance with one or more embodiments, parallel DFE processing may be utilized for single carrier systems that employ cyclic prefixes. The achieved parallelism allows working at contemporary clock rates that are significantly lower than the required sampling rate at high bandwidth systems such as 60 GHz transmissions.

Abstract: An embodiment of the present invention provides an apparatus, comprising a digital television (DTV) receiver including at least a one-bit-flag such that when the flag is “on”, the DTV receiver is not allowed to start an initial acquisition process, and at least one additional receiver sharing part of a receive chain of the DTV receiver and wherein the additional receiver is capable of turning the one-bit-flag “on”. The flag may be set through communication between the drivers of the DTV receiver and the at least one additional receiver.

Abstract: Briefly, according to embodiments of the invention, there is provided a wireless communication system and a method to schedule a wireless system resource. The wireless communication resource is being used by both first and second wireless communication devices. The first and second communication devices are able to transmit space time block codes according to a predetermined diversity scheme on substantially the same Time-Frequency resources.

Abstract: Beamforming is provided for a wireless MIMO device by using antenna puncturing to reduce the number of transmit antennas that are used to transmit data for certain subcarriers. In a conventional approach, if N spatial streams are being used to provide spatial multiplexing, then N transmit antennas would be used to transmit for each subcarrier. In at least one embodiment of the invention, enhancements in channel capacity are achieved by using less than N transmit antennas for one or more subcarriers.

Abstract: In a structure having a fractional-N synthesizer driven by a voltage controlled oscillator, frequency accuracy is maintained by first using the fractional-N synthesizer to correct large frequency errors and then slowly transferring correction from the fractional-N synthesizer to the voltage controlled oscillator a little at a time.

Abstract: Methods and apparatuses for schedule transmissions between a base station and multiple user stations includes dividing a transmit time interval (TTI), in some embodiments referred to as a “frame,” into a plurality of portions or subchannel sets. The scheduler may optimize the assignment of users to spectrum within each subchannel set, per-user power and/or beamforming coefficients for each subchannel set only once over a limited number of contiguous TTIs. A next subchannel set may then be optimized at the next TTI. However, optimization of the modulation and coding scheme (MCS) for each subchannel set may be performed more often, for example, every TTI. Additional embodiments and variations are also disclosed.

Abstract: An embodiment of the present invention provides an apparatus, comprising a base station employing a duplexing technique that allows simultaneous transmission and reception on a plurality of frequency such that in each transmit time interval downlink transmission is carried over a frequency band used for uplink reception in a contiguously preceding transmit time interval.

Abstract: A communication system includes a lattice interfered channel to transmit data from a transmitter to a receiver. In one embodiment, an encoding-modulation scheme having a rich signal constellation is used to encode data at a total rate of 0.7 bit/dimension or less before transmission into the lattice interfered channel. In another embodiment, decoding metric approximation techniques are used to process signals received from the lattice interfered channel. In still another embodiment, multilevel code (MLC) decoding is used to jointly decode an error correction code component and a lattice/MLC component of a received signal. The error correction code component may then be extracted from the decoded signal.

Abstract: Some embodiments of the present invention include a decoding system in which the decoding system uses iterative decoding techniques to decode signals encoded with lattice codes and/or multilevel coset codes. The decoding techniciucs according to some embodiments of the invention may be less complex than some decoding techniciues such as maximum likelihood decoding techniciues. Other embodiments of the prevent invention are described and claims.

Abstract: Method and apparatus to perform channel estimation for a wireless communication system are described.

Abstract: Briefly, a method to transmit over an uplink channel a training signal having a power level which varies according to a parameter related to downlink channel characteristics is provided. Communication system that includes communication devices to transmit and receive the training signal is further provided.

Abstract: Interference mitigation strategies are presented for use within a transmitter in a wireless system. In at least one embodiment, one or more transmit signals may be generated that are capable of suppressing common channel interference effects within an associated receiver. In other embodiments, one or more transmit signals may be generated that are capable of suppressing dedicated channel interference effects within an associated receiver.

Abstract: A code designer unit may dynamically determine an error correction code having a performance for current conditions of a communication channel that substantially matches a current desired performance. The code designer unit may dynamically determine the error correction code at least by automatically estimating the performance of the code for the current channel conditions. Information relating to the error correction code may be provided to a transmitter code generator to generate a representation of the error correction code for encoding, and information relating to the error correction code may be provided to a receiver code generator to generate a representation of the error correction code for decoding. In the example of low-density parity-check codes, the information relating to the error correction code may be a common randomness source and definition of an ensemble of low-density parity-check codes an average performance of which substantially matches the current desired performance.

Abstract: A method and apparatus for image interpolation provides a simple method that can up-scale an image in various scale ratios, including fractional scaling ratios, and can yield a sharp image with reduced unpleasant visual artifacts. An embodiment uses a power weight function that is gradient dependent and uses a function that has a linear dependence on the distance to compute interpolated pixels. A further embodiment uses a power that can be adapted according to the local contrast of edges.

Abstract: Briefly, a method of encoding a linear block code including receiving an input word and computing at least a significant portion of a codeword of the linear block code by applying a sequence of operations including at least one forward substitution using a lower triangular matrix derived from a sub-matrix of a parity check matrix of the linear block code and at least one backward substitution using an upper triangular matrix derived from the sub-matrix.

Abstract: A signal encoded with a linear block code is iteratively decoded using a sequential updating method. The sequential updating method calculates check-to-variable messages and variable-to-check messages such that intra-iteration information is exchanged. In some embodiments, a partial horizontal pass of a column of the matrix is followed by a vertical pass of the column using the results of the partial horizontal pass. In other embodiments, a partial vertical pass of a row of the matrix is followed by a horizontal pass of the row using the results of the partial vertical pass.

Abstract: A communication system includes a lattice interfered channel to transmit data from a transmitter to a receiver. In one embodiment, an encoding-modulation scheme having a rich signal constellation is used to encode data at a total rate of 0.7 bit/dimension or less before transmission into the lattice interfered channel. In another embodiment, decoding metric approximation techniques are used to process signals received from the lattice interfered channel. In still another embodiment, multilevel code (MLC) decoding is used to jointly decode an error correction code component and a lattice/MLC component of a received signal. The error correction code component may then be extracted from the decoded signal.