A base station may utilize frequency division multiplexing (FDM) techniques to signal synchronization signal (SS) blocks and downlink transmissions (e.g., data/control transmissions). The base station may configure a configuration for a bandwidth part (BWP) of a carrier for downlink transmissions. The BWP configuration may include a transmission attribute (e.g., a subcarrier spacing (SCS)) for downlink transmissions within the BWP. The base station may transmit a grant for a downlink transmission to a user equipment (UE). In some cases, the downlink transmission may be scheduled for a set of resources that overlap in time with a SS block for the carrier. The base station may transmit downlink transmissions within the BWP using transmission attributes configured for the BWP and/or using SS block transmission attributes, depending on capabilities of the UE, on whether the time resources of the downlink transmission that are FDMed with the SS block, etc.

A vehicular autonomous driving system includes a time division multiplexed (TDM) bus, an autonomous driving (AD) controller coupled to the TDM bus, and a plurality of AD sensors coupled to the TDM bus. The AD sensors are configured to collect AD data and transmit collected AD data to the AD controller on the TDM bus in an assigned time slot at a first power level. A first

AD sensor of the plurality of AD sensors is configured to, based upon collected AD data, detect an AD emergency event. In response to the detection, the first AD sensor is configured to transmit an AD emergency message on the TDM bus in a non-assigned time slot and at a second power level that exceeds the first power level. The AD sensor may transmit the AD emergency message in a particular sub-slot of the non-assigned time slot.

A communication system of the present disclosure includes one or more communication apparatuses, each of which includes: a transmission circuit including a transmission unit and a signal generator, the transmission unit that selectively transmits, via an antenna unit, one of a first transmission signal including first transmission data or a second transmission signal including at least one of a periodic signal with a constant frequency or a narrow band modulation signal by data having lower speed than the first transmission data, and the signal generator that generates the second transmission signal; and a reception circuit including a reception unit, a narrow band detector, and a determination unit, the reception unit that receives the first transmission signal and the second transmission signal via the antenna unit, the narrow band detector that outputs a narrow band detection signal through detecting the second transmission signal in a narrow band, and the determination unit that determines presence or absence of a significant signal or presence or absence of significant signal change in the narrow band detection signal and outputs a determination signal.

An embodiment of a communication system for transmitting and receiving data across an isolation barrier may include a communication circuit connected to an isolator at a first side of the isolation barrier, the communication circuit having a transmit circuit to drive a first data signal onto the isolator based on input data received by the communication circuit, a receive circuit to receive a second data signal from the isolator and produce output data based on the received second data signal, and a control circuit to control the transmit and receive circuits to provide time division multiplexing of the first and second data signals. The control circuit may transition to a transmit state in which the transmit circuit drives the first data signal onto the isolator from a receive state in which the receive circuit receives the second data signal from the isolator in response to detecting a condition as a function of receiving a predetermined number of bits of the second data signal and passage of a predetermined time period.

In a switched digital video content-based network, wherein a head end obtains a first group of program streams and sends to a client only a subset of the program streams selected by subscribers in a neighborhood of the client, imminence and/or presence of a condition of inadequate bandwidth is determined. Responsive to the determining, a bit rate of at least one of the subset of the program streams selected by the subscribers in the neighborhood of the client is dynamically decreased by adjusting encoding thereof, while maintaining adequate quality for the at least one of the subset of the program streams selected by the subscribers in the neighborhood of the client, based on an objective quality measure, in order to address the imminence and/or presence of the condition of inadequate bandwidth.

A method is disclosed of a first device for wireless communication adapted to communicate with a second device for wireless communication over a communication channel in accordance with a hybrid automatic repeat request (HARQ) protocol. The method comprises receiving a first signal from the second device over the communication channel, estimating a first quality of the communication channel based on the received first signal, and transmitting a HARQ packet to the second device over the communication channel, wherein a transmission format of the HARQ packet is based on the estimation of the first quality. The method also comprises receiving a second signal from the second device over the communication channel, estimating a second quality of the communication channel based on the received second signal, and determining whether a deterioration between the first quality and the second quality exceeds a quality deterioration threshold. If the deterioration exceeds the quality deterioration threshold, the method comprises retransmitting the HARQ packet to the second device over the communication channel before reception of a response message associated with the HARQ packet is expected. Corresponding computer program product, arrangement and wireless communication device are also disclosed.

Embodiments of the present invention provide a mobile device comprising a slave clock, a receiver unit for receiving one or more frames from a remote device including a master system clock, a transmitter unit for transmitting one or more frames to the remote device, and a clock error correction unit. The clock error correction unit is configured to maintain clock synchronization between the slave clock and the master system clock, and maintain frame alignment for frames transmitted from the transmitter unit.

A device, method and system of handling in-device coexistence (IDC) interference in a wireless network, may comprise detecting the IDC interference between a first communication module operating over a first protocol and a second communication module operating over a second protocol; generating an IDC indication having a bit string comprising four bits, wherein the four bits correspond to a subframe pattern comprising four subframes, a value of a bit of the bit string indicates whether an enhanced node B (eNB) is requested to abstain from using a subframe of the four subframes of the subframe pattern; and transmit the IDC indication to the eNB via a wireless network.

A device, method and system of handling in-device coexistence (IDC) interference in a wireless network, may comprise detecting the IDC interference between a first communication module operating over a first protocol and a second communication module operating over a second protocol; generating an IDC indication having a bit string comprising four bits, wherein the four bits correspond to a subframe pattern comprising four subframes, a value of a bit of the bit string indicates whether an enhanced node B (eNB) is requested to abstain from using a subframe of the four subframes of the subframe pattern; and transmit the IDC indication to the eNB via a wireless network.

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.