Abstract: A transmitter includes a plurality of user-specific channels, with each user specific channel associated with a different set of user equipment (UE) receive antennas. For precoding, the transmitter generates a baseline channel matrix reflecting the characteristics of the communication medium employed to transmit data to the different user equipment (UEs). For each user-specific channel, the transmitter generates a complementary channel matrix based on the baseline channel matrix, then performs matrix decomposition to eliminate selected terms of the complementary channel matrix that interfere from other communication channels of the transmitter. The transmitter can reuse portions of one rotational matrix set generated for one channel to generate the rotational matrix sets for one or more other channels.

Abstract: A transmitter includes a plurality of user-specific channels, with each user specific channel associated with a different set of user equipment (UE) receive antennas. For precoding, the transmitter generates a baseline channel matrix reflecting the characteristics of the communication medium employed to transmit data to the different user equipment (UEs). For each user-specific channel, the transmitter generates a complementary channel matrix based on the baseline channel matrix, then performs matrix decomposition (e.g., QR-Givens decomposition) to eliminate selected terms of the complementary channel matrix that interfere from other communication channels of the transmitter.

Abstract: A transmitter generates precoding matrices for communication channels of a transmitter, The transmitter includes a plurality of user-specific channels, with each user specific channel associated with a different set of user equipment (UE) receive antennas. For precoding, the transmitter generates a baseline channel matrix reflecting the characteristics of the communication medium employed to transmit data to the different user equipment (UEs). For each user-specific channel, the transmitter generates a set of null space vectors wherein only a subset of the generated null space vectors generated by the transmitter are used to precode the data. To identify the combination of null space vectors to be used for each channel, the transmitter calculates a quality score for each such combination of null space vectors. The transmitter uses the subset of null vectors that yields the highest score to precode the data.

Abstract: A transmitter includes a plurality of user-specific channels, with each user specific channel associated with a different set of user equipment (UE) receive antennas. For precoding, the transmitter generates a baseline channel matrix reflecting the characteristics of the communication medium employed to transmit data to the different user equipment (UEs). For each user-specific channel, the transmitter generates a complementary channel matrix based on the baseline channel matrix, then performs matrix decomposition to eliminate selected terms of the complementary channel matrix that interfere from other communication channels of the transmitter. The transmitter can reuse portions of one rotational matrix set generated for one channel to generate the rotational matrix sets for one or more other channels.

Abstract: A transmitter includes a plurality of user-specific channels, with each user specific channel associated with a different set of user equipment (UE) receive antennas. For precoding, the transmitter generates a baseline channel matrix reflecting the characteristics of the communication medium employed to transmit data to the different user equipment (UEs). For each user-specific channel, the transmitter generates a complementary channel matrix based on the baseline channel matrix, then performs matrix decomposition (e.g., QR-Givens decomposition) to eliminate selected terms of the complementary channel matrix that interfere from other communication channels of the transmitter.

Abstract: A converter unit for an M-order digital modulation to map L input binary sequences of N bits onto M complex values being transmitted through a communication channel, where M=2N and L and N are positive integers. The converter unit comprises an input to receive a respective input binary sequence. The converter unit is arranged to individually convert each N bits of the input binary sequence into a real number to obtain a sequence with N real numbers. The converter unit is arranged to execute complex arithmetic operations on the sequence of real numbers and to compute a respective complex value. The respective complex value corresponds to said respective input binary sequence.

Abstract: A converter unit for an M-order digital modulation to map L input binary sequences of N bits onto M complex values being transmitted through a communication channel, where M=2N and L and N are positive integers. The converter unit comprises an input to receive a respective input binary sequence. The converter unit is arranged to individually convert each N bits of the input binary sequence into a real number to obtain a sequence with N real numbers. The converter unit is arranged to execute complex arithmetic operations on the sequence of real numbers and to compute a respective complex value. The respective complex value corresponds to said respective input binary sequence.

Abstract: A processor unit used to determine a quality indicator, QI, of a communication channel. The processor unit receives received complex symbols at an input, executes a predetermined sequence of transformations on the received complex symbols and computes the error vector magnitude, EVM. The quality indicator, QI, of the communication channel is determined based on the determined error vector magnitude, EVM. Data representing the quality indicator, QI, is outputted at an output of the processor unit. The predetermined sequence of transformations transfers all the received complex symbols to a single predetermined region containing a single target location. The error vector magnitude, EVM, is then calculated as average distance of all the processed received complex symbols in the predetermined single region to the single target location.