A device includes a transceiver, a receiver, and a processor. The transceiver is configured to receive feedback data from an unmanned aerial vehicle (UAV) and transmit control data to the UAV via a first communication link. The receiver is configured to receive the control data from a controlling terminal via a second communication link. The second communication link does not interfere with the first communication link. The processor is configured to determine whether the feedback data and the control data are being simultaneously transmitted via the first communication link.

A method by which a first device performs wireless communication is presented. The method can comprise the steps in which: a first device performs at least one sidelink transmission to a second device; negative acknowledgement (NACK) information related to the at least one sidelink transmission is received from the second device; and whether to transmit a message for requesting a retransmission resource is determined on the basis of a preset latency time threshold value and a remaining latency budget related to the at least one sidelink transmission.

This application provides a coding method and a communication apparatus, which may be applied to wireless data transmission. The method includes: A sending apparatus sends indication information to a receiving apparatus, where the indication information indicates first information and second information. The first information indicates a coding scheme of to-be-encoded data, and the coding scheme includes a coding matrix for channel coding and a channel coding mode. The second information indicates a distribution feature of the to-be-encoded data. The sending apparatus performs channel coding on the to-be-encoded data based on the coding scheme, to obtain encoded data. The receiving apparatus receives the indication information sent by the sending apparatus, and the receiving apparatus performs channel decoding on received data based on the indication information, to obtain decoded data.

A device includes a transmitter coupled to a node, where the node is to couple to a wired link. The transmitter has a plurality of modes of operation including a calibration mode in which a range of communication data rates over the wired link is determined in accordance with a voltage margin corresponding to the wired link at a predetermined error rate. The range of communication data rates includes a maximum data rate, which can be a non-integer multiple of an initial data rate.

An Ethernet transceiver includes physical-layer (PHY) circuitry and a signal-loss detector. The PHY circuitry is configured to receive a signal from a peer transceiver, to process the received signal in a series of digital PHY-level processing operations, and to output the processed signal for Medium Access Control (MAC) processing. The signal-loss detector is configured to receive, from the PHY circuitry, a digital version of the received signal, and to detect a signal-loss event based on an amplitude of the digital version of the received signal.

A data transmission method based on a mobile network, applied to a terminal configured with a primary card link for a primary subscriber identity module (SIM) card and a secondary card link for a secondary SIM card, includes: performing transmission quality evaluation on the primary card link when the primary card link is applied to perform data transmission of the mobile network to obtain a first transmission quality evaluation value; and compensating the data transmission of the mobile network performed by the primary card link through the secondary card link in response to that the first transmission quality evaluation value is lower than a transmission quality evaluation threshold.

Embodiments herein relate to, e.g., a method performed by a communication node for controlling one or more communication parameters of a channel between a first communication device and a second communication device in a wireless communication network. The communication node, upon obtaining an indication of a channel quality of the channel to the second communication device, uses a correction value and the indication when determining the one or more communication parameters. The correction value is based on a decoding success of one or more previous transmissions, which one or more previous transmissions are based on an obtained previous indication of a previous channel quality from the second communication device, and wherein a change of the correction value relative a previous correction value is limited.

Systems and methods for grouping client devices for uplink multi-user transmission are provided. Client device groups may be determined based on at least one of traffic compatibility/similarity, client device class compatibility/similarity, and uplink pathloss similarity. A target received signal strength measured by an AP with which client devices in the client device groups communicate and an appropriate modulation coding scheme rate to be used by the client devices may be determined and set for the client devices. The modulation coding scheme rate can be adjusted based on feedback regarding successful data packet reception at the AP from each of the client devices.

In one embodiment, a method includes sending SRS received from a plurality of UEs associated with the base station to a DU associated with the base station, receiving information regarding a subset of the plurality of UEs selected for downlink data transmissions for an RBG, multi-user data to be transmitted to UEs in the subset, and identities of selected beams among a plurality of pre-determined beams to be associated with the UEs in the subset from the DU, where each of the plurality of pre-determined beams corresponds to a DFT vector, computing a precoding matrix for the RBG based on IDFT vectors corresponding to the selected beams, preparing pre-coded multi-user data by applying the precoding matrix to the multi-user data, and transmitting the pre-coded multi-user data to the UEs in the subset for the RBG using MIMO technologies.

Methods and systems are provided for dynamically capping an MCS index. A determination that one or more user devices are serviced by a sector of a cell site that has a Sector Power Ratio (SPR) above a threshold is made. Based on the SPR being above the threshold, the MCS index of the one or more user devices is capped. In response to the capped MCS index, a first Quadrature Amplitude Modulation (QAM) value is assigned to at least one of the one or more user devices based on a triangulation area corresponding to a location of the at least one of the one or more user devices.