An apparatus and method for transmitting an indicator of channel quality while minimizing the use of a broadcast channel is described. A metric of forward link geometry of observed transmission signals is determined. An indicator of channel quality value is determined as a function of the observed transmission signals. An access sequence is selected, randomly, from one group of a plurality of groups of access sequences, wherein each of the plurality of groups of access sequences correspond to different ranges of channel quality values.

A method and an apparatus for receiving a signal by a terminal in a wireless communication system according to an embodiment of the present invention comprises the steps of: establishing an RNTI associated with an MCS by a terminal; receiving a control channel for scheduling transmission of an uplink data channel or reception of a downlink data channel; and transmitting the uplink data channel or receiving the downlink data channel on the basis of one MCS table of a plurality of MCS tables, wherein the uplink data channel or the downlink data channel has been scheduled by the control channel and the one MCS table is determined on the basis of an RNTI associated with the MCS and an RNTI associated with the control channel.

Disclosed are a method and apparatus for generating a short training field (STF) sequence that can be used in a wireless LAN system. The STF signal is included in a field used to improve AGC estimation of MIMO transmission. Some of the STF signals may be used for uplink transmission and may be used for uplink MU PPDU transmitted from a plurality of STAs. For example, the STF signal is used for an 80 MHz band or a 160 MHz band and may be generated based on a sequence having a preset repeated M sequence. The preset M sequence may represent a binary sequence of a length having 15 bits.

In an embodiment, a receiver detects a timing error between a transmitter clock at a transmitter and a receiver clock at a receiver associated with an exchange of CPM signals. The receiver phase aligns input samples of a candidate received signal over a time window based on a rotating signal corresponding to a phase progression of the candidate received signal. The receiver generates first and second partial sums of the phase-aligned input samples that are accumulations of phase-aligned input samples corresponding to modulation symbols that contribute positive and negative phases, respectively, to the phase progression. The receiver determines a phase difference between the first and second partial sums, and generates a timing-error metric that is indicative of a timing error between the transmitter clock and the receiver clock based at least in part upon the determined phase difference.

A method at a mobile device for increasing measurement gaps to facilitate inter-radio access technology measurements is provided. The method at the mobile device: receiving inter-radio access technology (RAT) measurement configuration information from the network; when the device is actively connected, determining whether a triggering criterion is met, based on the received information; and if the triggering criterion is met, increasing the time available for measurements.

Embodiments of this application disclose communication methods and apparatuses related to the field of communication technologies. One method comprises: obtaining, by a first device, first indication information; and sending, by the first device, the first indication information and first data to a second device, wherein the first indication information comprises first information indicating the second device to feed back hybrid automatic repeat request (HARQ) information for the first data based on information about a distance or a signal quality.

Aspects of the present disclosure relate to wireless communications, and more particularly, to techniques for allowing for the coexistence of legacy and non-legacy PUCCH formats. An example method generally includes generating a first orthogonal sequence for a first payload for a physical uplink control channel (PUCCH) to be transmitted; generating a second orthogonal sequence for a second payload for the PUCCH to be transmitted; mapping the first orthogonal sequence to a first set of virtual resources and the second orthogonal sequence to a second set of virtual resources; mapping the first set of virtual resources to a first set of physical resources and the second set of virtual resources to a second set of physical resources; and transmitting the first and second payloads for the PUCCH on the first and second sets of physical resources.

Method performed by a network node (210) to indicate a first and a second set of antenna ports. The network node (210) indicates (803) to a wireless device (250) at least one of: a) a first indication of a first set (M′) of antenna ports for first measurements on first radio signals, the first measurements associated with periodic reporting, and b) a second indication of a second set (M) of antenna ports for second measurements on second radio signals, the second measurements associated with aperiodic reporting. The first set is different than the second set. The periodic and the aperiodic reporting are by the wireless device (250) and correspond to a same Channel State Information, CSI, process. The network node (210) also transmits (804), to the wireless device (250), the first radio signals, periodically, over the first set and the second radio signals over the second set.

A method and apparatus for enhanced multimedia broadcast/multicast service (MBMS) ingestion. A network device includes a memory configured to store a memory and one or more processors operably connected to the memory. The one or more processors configured to receive, from a content provider, signaling concerning a payload for MBMS. The one or more processors are further configured to receive, from the content provider, the payload, process the payload based on the signaling, and transmit, to an MBMS gateway, the processed payload.

A network of handling uplink (UL) transmission comprises instructions of configuring a maximum retransmission attempt to a communication device; configuring a UL transmission skipping mechanism to the communication device; transmitting a UL grant comprising a first modulation and coding scheme (MCS) and an allocation of a first resource to the communication device for performing the UL transmission; receiving the UL transmission generated according to the first MCS in the first resource according to the UL transmission skipping mechanism; decoding the UL transmission for a plurality of times according to an error control coding (ECC) scheme, wherein the UL transmission is a first redundant version (RV) corresponding to a new transmission with a first RV index or a second RV corresponding to a retransmission with a second RV index; and transmitting an acknowledgment indicating whether the UL transmission is decoded successfully to the communication device.