A data transmission method is provided. Measurement information associated with an inter-frequency signal measurement is received. The measurement information is configured to indicate at least one measurement window. First scheduling information associated with a first semi-persistent scheduling (SPS) physical downlink shared channel (PDSCH) resource is received. The first scheduling information is configured to indicate the first SPS PDSCH resource configured with a first priority. On the basis of the measurement information and the first scheduling information, it is determined that the first SPS PDSCH resource overlaps the measurement window in the time domain. In response to determining that the first SPS PDSCH resource overlaps the measurement window in the time domain, downlink communication with a serving cell is kept during at least the window of the first SPS PDSCH resource.

Provided is a communication method and apparatus. The method includes obtaining measurement configuration information transmitted by a network device. The measurement configuration information includes a measurement gap, gap sharing information, and at least one measurement object. The gap sharing information indicates a proportion of measurement gap occupied by the at least one measurement object in relation to the measurement gap. Based on the gap sharing information, a mobility measurement is performed on the at least one measurement object in the measurement gap.

The embodiments of the disclosure provide a measurement method and apparatus for a terminal, as well as a terminal. The measurement method includes that: a terminal acquires first indication information, the first indication information being for determining a measurement parameter of a dedicated measurement frequency, the measurement parameter of the dedicated measurement frequency being a first measurement parameter and/or a second measurement parameter, and the first measurement parameter being greater than the second measurement parameter.

The present disclosure relates to performing measurement in wireless communications. According to an embodiment of the present disclosure, a method performed by a wireless device in a wireless communication system comprises: receiving, from a network, information for at least one of a first cell quality threshold or a second cell quality threshold, and information for at least one of a first triggering threshold or a second triggering threshold; identifying a representative cell of each of a plurality of frequencies for measurement; obtaining a representative cell quality for each of the plurality of frequencies based on a measurement on the representative cell of each of the plurality of frequencies; and performing a relaxed measurement on the plurality of frequencies based on a determination that a triggering condition for the relaxed measurement is satisfied, wherein the triggering condition comprises at least one of: a condition that a number of frequencies for which representative cell quality is higher than the first cell quality threshold among the plurality of frequencies is lower than the first triggering threshold; or a condition that a number of frequencies for which representative cell quality is lower than the second cell quality threshold among the plurality of frequencies is higher than the second triggering threshold.

The present application relates to devices and components including apparatus, systems, and methods to provide positional information for one or more NTN devices to a UE to be utilized for one or more UE operations.

Disclosed are systems and methods for providing a differentiated neighbor list that can be individually generated for a specific service (e.g., per service) based on network service information, which can include, but is not limited to, a user equipment (UE) group identifier (ID), network slicing and/or quality of service (QoS) flow, and the like. Neighbors within the differentiated list can be characterized based on, but not limited to, service types, distance to devices, transport costs, service locations, and the like, or some combination thereof. The disclosed framework can generate and dynamically update a differentiated neighbor list for specific types of services so that optimal neighbor selection is performed for the type of service a UE is operating within to ensure that a network connection is maintained at a threshold satisfying QoS.

An embodiment of the present disclosure may provide an inter-MeNB handover method in a small cell system, including: making, by a source MeNB and/or target MeNB, a determination as to whether to maintain a SeNB when handover is performed; and triggering different handover processes according to a result of the determination as to whether to maintain the SeNB. Another embodiment of the present disclosure may further provide an inter-MeNB handover device in a small cell system. With the inter-MeNB handover method and device in a small cell system provided by the present disclosure, unnecessary deletion and re-establishment of the bearers at the SeNB for the UE may be reduced. False bearer deletion may be avoided and data forwarding may be reduced. Furthermore, the SeNB may be maintained according to network deployment and SGW re-selection may be supported. Therefore, system capacity and transmission speed of the data may be improved.

A method for configuring a measurement gap is provided. The method is used in a first access network device of at least two access network devices that have established connections with a terminal. The method includes: when the first access network device is a configuration device among the at least two access network devices, the first access network device generates measurement gap configuration information; here, the configuration device is an access network device, that configures a measurement gap for the terminal, as a part of the at least two access network devices, and the measurement gap is used to indicate a period of time during which the terminal performs signal measurement at a frequency point except a present working frequency point; and the first access network device sends the measurement gap configuration information to the terminal.

A first computing device may receive an indication of user input that is at least a part of a conversation between a user and a first assistant executing at the first computing device. The first assistant and/or an assistant executing at a digital assistant system may determine whether to handoff the conversation from the first assistant executing at the first computing device to a second assistant executing at a second computing device. In response to determining to handoff the conversation to the second assistant executing at the second computing device, the first assistant and/or the assistant executing at the digital assistant system may send to the second computing device a request to handoff the conversation which includes at least an indication of the conversation.

When a downlink bandwidth part (BWP) is switched from a first BWP to a second BWP without a change of a cell defining synchronization signal block (SSB), if a reference signal type for Radio Link Monitoring (RLM) is set to an SSB type, a radio terminal (12) continues to use for RLM measurements a first SSB associated with the first BWP after switching of the downlink BWP to the second BWP. This for example enables the radio terminal to monitor a suitable Reference Signal (RS) for RLM measurements after switching of the DL active BWP.