A high-frequency front-end module includes transmission amplifier circuits, a transmission filter that is connected between a common terminal and the transmission amplifier circuit and has a transmission band of a band A as a pass band, a reception filter that is connected to the common terminal and has a reception band of a predetermined communication band as a pass band, in which a frequency of an intermodulation distortion generated by a transmission signal from the transmission amplifier circuit and a transmission signal from the transmission amplifier circuit overlaps the pass band, and a band elimination filter that is disposed in a signal path connecting an output terminal of the transmission amplifier circuit and the transmission filter, and has a transmission band of the band A as a pass band and a transmission band of a band B as an attenuation band.

High-performance filter bank channelizers are provided. In one embodiment, a heterodyne signal shifts an input spectrum of the input signal by an offset between input and output centers, and operates at a high input sample rate. In another embodiment, the channelizer includes an input commutator receiving and commutating an input signal, an M-path polyphaser filter in communication with the commutator, and an M-path inverse discrete Fourier transform module processing outputs of the polyphaser filter, wherein the M-path polyphaser filter introduces a plurality of phase rotations in a time domain resulting in a workload reduction for a processor on which the channelizer is implemented. Still other embodiments includes a resampling channelizer, a half-band filter, and a cascaded half-band filter.

High-performance filter bank channelizers are provided. In one embodiment, a heterodyne signal shifts an input spectrum of the input signal by an offset between input and output centers, and operates at a high input sample rate. In another embodiment, the channelizer includes an input commutator receiving and commutating an input signal, an M-path polyphaser filter in communication with the commutator, and an M-path inverse discrete Fourier transform module processing outputs of the polyphaser filter, wherein the M-path polyphaser filter introduces a plurality of phase rotations in a time domain resulting in a workload reduction for a processor on which the channelizer is implemented. Still other embodiments includes a resampling channelizer, a half-band filter, and a cascaded half-band filter.

Adaptive RF filters based on modulated resonators are provided. The filter architecture is based on time-interleaved commutation of passive RF resonators. The architecture can behave as a two-port filter network, with a fully tunable instantaneous filter bandwidth. The filters are applicable as miniaturized, environment-aware RF signal processing components and can be used in mobile communications.

Adaptive RF filters based on modulated resonators are provided. The filter architecture is based on time-interleaved commutation of passive RF resonators. The architecture can behave as a two-port filter network, with a fully tunable instantaneous filter bandwidth. The filters are applicable as miniaturized, environment-aware RF signal processing components and can be used in mobile communications.

An apparatus may be configured to receive a polar-encoded transmission comprising at least one intermediate node associated with a first configuration of frozen leaf nodes and information leaf nodes. The apparatus may further be configured to apply an FHT to a first set of values associated with a first intermediate node of the at least one intermediate node to generate a second set of values associated with the first intermediate node. The apparatus may also be configured to select, based on the second set of values, one or more paths associated with the first intermediate node for a SSCL decoding. The apparatus may further be configured to calculate a path metric for each of the selected one or more paths associated with the first intermediate node.

An apparatus may be configured to receive a polar-encoded transmission comprising at least one intermediate node associated with a first configuration of frozen leaf nodes and information leaf nodes. The apparatus may further be configured to apply an FHT to a first set of values associated with a first intermediate node of the at least one intermediate node to generate a second set of values associated with the first intermediate node. The apparatus may also be configured to select, based on the second set of values, one or more paths associated with the first intermediate node for a SSCL decoding. The apparatus may further be configured to calculate a path metric for each of the selected one or more paths associated with the first intermediate node.

One embodiment can provide a method and a system for performing multiple radio frequency allocation. During operation, the system including a controller can receive, a Wi-Fi channel allocation and a filter bank configuration associated with a Wi-Fi radio transceiver. The system can determine one or more Internet of things (IoT) radio transceivers operating with the Wi-Fi radio transceiver. For a respective IoT radio transceiver, the system can perform the following operations: determining a set of scores based on a set of constraints associated with an application type for the IoT radio transceiver; and computing a weighted average score based on the set of scores; and determining a channel allocation for the IoT radio transceiver based on the weighted average score and the Wi-Fi channel allocation.

One embodiment can provide a method and a system for performing multiple radio frequency allocation. During operation, the system including a controller can receive, a Wi-Fi channel allocation and a filter bank configuration associated with a Wi-Fi radio transceiver. The system can determine one or more Internet of things (IoT) radio transceivers operating with the Wi-Fi radio transceiver. For a respective IoT radio transceiver, the system can perform the following operations: determining a set of scores based on a set of constraints associated with an application type for the IoT radio transceiver; and computing a weighted average score based on the set of scores; and determining a channel allocation for the IoT radio transceiver based on the weighted average score and the Wi-Fi channel allocation.

This invention presents a repeater enhanced MU-MIMO wireless communication system comprising a BS, a plural of repeaters, and a plural of UEs, where a repeater estimates the channel between itself and its upper communication node in the system, a repeater computes equalization coefficients based on the estimation of the channel coefficients, and a repeater applies the equalization coefficients to reduce the channel delay spread or increase the coherence bandwidth of the channel between communication nodes containing the BS, the UEs, or the repeaters.