Abstract: A radio receiver is disclosed, comprising: a receiving stage configured to receive a multi-layered signal comprising a plurality of layers; a division stage configured to divide the plurality of layers into a first subset and a second subset; a first whitening filter configured to filter the multi-layered signal based on a noise and interference covariance measure derived from the second subset to provide a first filtered multi-layered signal; and a first detection stage configured to detect at least one layer of the first subset based on the first filtered multi-layered signal.

Abstract: The disclosure relates to a radio receiver, comprising: a receiving stage configured to receive a multi-layered signal comprising a plurality of layers; a division stage configured to divide the plurality of layers into a first subset and a second subset (206); a first whitening filter configured to filter the multi-layered signal based on a noise and interference covariance measure derived from the second subset to provide a first filtered multi-layered signal; and a first detection stage configured to detect at least one layer of the first subset based on the first filtered multi-layered signal.

Abstract: A method for symbol detection includes assigning a received symbol to at least one particular candidate symbol of a set of candidate symbols of a finite candidate symbol alphabet based on a metric between the received symbol and the at least one particular candidate symbol, the metric comprising contributions with respect to channel-based information and contributions with respect to a priori information.

Abstract: A method for symbol detection includes assigning a received symbol to at least one particular candidate symbol of a set of candidate symbols of a finite candidate symbol alphabet based on a metric between the received symbol and the at least one particular candidate symbol, the metric comprising contributions with respect to channel-based information and contributions with respect to a priori information.

Abstract: A method for decoding a wireless channel includes generating hypotheses of how many antennas each of at least two base stations have in a synchronized network and how received signals are being transmitted for each of the at least two base stations, detecting a MIMO signal using the hypotheses and signal components received from the at least two base stations, decoding the signal, and determining whether the decoded signal is valid by performing a cyclical redundancy check calculation.

Abstract: A method for decoding a wireless channel includes generating hypotheses of how many antennas each of at least two base stations have in a synchronized network and how received signals are being transmitted for each of the at least two base stations, detecting a MIMO signal using the hypotheses and signal components received from the at least two base stations, decoding the signal, and determining whether the decoded signal is valid by performing a cyclical redundancy check calculation.