Systems and methods for handling of scheduling request collisions with an ACK/NACK repetition signal are provided. A pending scheduling request may be refrained from being transmitted due to the collision. The SR counter may be refrained from incrementing and the SR prohibit timer may be refrained from starting such that additional latency is not introduced into the scheduling request procedure. Alternatively, a pending scheduling request may be transmitted with the ACK/NACK repetition signal in the same subframe when the collision occurs. The ACK/NACK repetition signal may be transmitted on the SR PUCCH resource to indicate a positive scheduling request. If there is no pending scheduling request to be transmitted, the ACK/NACK repetition signal may be transmitted on the ACK/NACK PUCCH resource.

Systems and methods for handling of scheduling request collisions with an ACK/NACK repetition signal are provided. A pending scheduling request may be refrained from being transmitted due to the collision. The SR counter may be refrained from incrementing and the SR prohibit timer may be refrained from starting such that additional latency is not introduced into the scheduling request procedure. Alternatively, a pending scheduling request may be transmitted with the ACK/NACK repetition signal in the same subframe when the collision occurs. The ACK/NACK repetition signal may be transmitted on the SR PUCCH resource to indicate a positive scheduling request. If there is no pending scheduling request to be transmitted, the ACK/NACK repetition signal may be transmitted on the ACK/NACK PUCCH resource.

A method for operating a transmission-reception point (TRP) includes determining a first cycle of backhaul communications modes for the TRP, each backhaul communications mode of the first cycle is associated with a different time period and prompts the TRP to either transmit or receive using a subset of communications beams available to the TRP during an associated time period, wherein the communications beams used by the TRP and neighboring TRPs of the TRP in each associated time period are selected to prevent mutual interference, and wherein at least one backhaul communications mode of the first cycle prompts the TRP to either transmit or receive using all of the communications beams available to the TRP, determining a backhaul frame configuration for the TRP in accordance with the first cycle, the backhaul frame configuration specifying an arrangement of subframes of a frame used for backhaul communications.

A bidirectional time-division duplexing transceiver circuit includes a first and a second bidirectional phase-shift circuit, and a bidirectional amplifier circuit including a first amplifier circuit and a second amplifier circuit. The first amplifier circuit and the second amplifier circuit are coupled via double-pole-double-throw (DPDT) switches to radio-frequency (RF) antennas and the first and the second bidirectional phase-shift circuits. The (DPDT) switches enable the first amplifier circuit and the second amplifier circuit to be operable simultaneously as transmit (TX) path amplifiers in a first time slot and as a receive (RX) path amplifiers in a second time slot.

A bidirectional time-division duplexing transceiver circuit includes a first and a second bidirectional phase-shift circuit, and a bidirectional amplifier circuit including a first amplifier circuit and a second amplifier circuit. The first amplifier circuit and the second amplifier circuit are coupled via double-pole-double-throw (DPDT) switches to radio-frequency (RF) antennas and the first and the second bidirectional phase-shift circuits. The (DPDT) switches enable the first amplifier circuit and the second amplifier circuit to be operable simultaneously as transmit (TX) path amplifiers in a first time slot and as a receive (RX) path amplifiers in a second time slot.

Multiplexing architectures for wireless applications. In some embodiments, a front-end architecture can include a first power amplifier having an output coupled to a transmit filter through a path that is substantially free of a switch. The transmit filter can be configured for a first transmit band or a second transmit band, with the first and second transmit bands at least partially overlapping with each other. The front-end architecture can further include a receive filter configured for at least a first receive band corresponding to the first transmit band, and a second power amplifier having an output capable of being coupled to a first duplexer or a second duplexer through a selector switch. The first duplexer can include a receive portion configured for a second receive band corresponding to the second transmit band.

Multiplexing architectures for wireless applications. In some embodiments, a front-end architecture can include a first power amplifier having an output coupled to a transmit filter through a path that is substantially free of a switch. The transmit filter can be configured for a first transmit band or a second transmit band, with the first and second transmit bands at least partially overlapping with each other. The front-end architecture can further include a receive filter configured for at least a first receive band corresponding to the first transmit band, and a second power amplifier having an output capable of being coupled to a first duplexer or a second duplexer through a selector switch. The first duplexer can include a receive portion configured for a second receive band corresponding to the second transmit band.

The behavior of multiple users with access to a multi-tenant resource can be monitored and compliance enforced by monitoring state information for each user. The state information can be captured across a level of a network environment, such that any activity across that layer can be monitored and the data aggregated to give a global view of user behavior. If user behavior is determined to fall outside an acceptable range of behavior, any of a number of remedial actions can be taken, which can include notifying the user, billing the user for the inappropriate behavior, or modifying that behavior outside of the control of the user.

Various communication systems may benefit from codebook methods and devices for multiple transmitters. For example, a codebook for four transmitters (4Tx) may provide further enhancement for downlink multiple-input multiple-output (DL-MIMO) systems. A method can include weighting a signal for transmission based on a precoder selected according to a feedback from a codebook, such as codebooks A, B, C, D, or E, described herein. The method can also include sending the weighted signal.

In embodiments, apparatuses, methods, and storage media may be described for reducing the overhead associated with the transmission of channel training signals from an eNodeB (eNB) of a wireless network. Specifically, the eNB may receive feedback from a user equipment (UE) regarding the received signal energy of a first and second beamformed signal produced with a first and second beamforming vector, respectively. The eNB may identify, based on the feedback of the received signal energy, a signal subspace and a null subspace. The eNB may then transmit a channel training signal to the signal subspace.