A calling system for off-road vehicles includes processing circuitry. The processing circuitry is configured to: obtain location information indicating a location of a first off-road vehicle; obtain a specific state signal indicating that the first off-road vehicle is in a given specific state; and cause a first wireless communicator of the first off-road vehicle to, based on the specific state signal, wirelessly transmit a calling signal containing the location information, wherein the wireless transmission of the calling signal by the first wireless communicator is performed using a wireless communication technology in which the calling signal transmitted from the first wireless communicator is received directly by a second wireless communicator of a second off-road vehicle.

The invention discloses a method (700) for a cellular system (100), in which traffic can be exchanged between first (110, 120) and second (110, 120) transceivers. The traffic is sent in data units, each of which is given an identifier, and which data units may be divided into segments. A receiving transceiver (110, 120) may send status information in data frames or data units (200, 300) about properly received, partially received, or non-received data units to a sending transceiver, i.e. the transceiver from which the data was sent. In the case (705) of partially or non-received data units, the status information includes (710) information about whether the data unit or units were non-received or partially received, and in the case of one or more partially received data units, which (715) parts of those data units that were not received.

In an example, a User Equipment (UE) operates with shared spectrum channel access on a carrier and/or a cell. The UE receives a configuration for configuring configured grants for uplink transmission in a bandwidth part (BWP). The configured grants include a first configured grant and a second configured grant. The UE configures a first minimum Downlink Feedback Indication (DFI) time delay for the first configured grant according to the configuration. The first minimum DFI time delay is for validation of Hybrid Automatic Repeat Request (HARQ) information in response to one or more first uplink transmissions. The UE configures a second minimum DFI time delay for the second configured grant according to the configuration. The second minimum DFI time delay is for validation of HARQ information in response to one or more second uplink transmissions. The UE does not expect the second minimum DFI time delay to have a different value than the first minimum DFI time delay.

Methods, apparatus, and systems for providing deterministic network experience to application-level services are disclosed. In one example aspect, a method includes providing a set of interfaces to an application-level service deployed in part on a user device. The set of interfaces is configured to provide a notification to the application-level service regarding a real-time change in network conditions relevant to the application-level service. The method also includes receiving a registration request from the application-level service to register for the notification, estimating the network conditions based on physical layer information, and notifying the registered application-level service of the change in the network conditions based on the estimated network conditions.

Methods, apparatus, and systems for providing deterministic network experience to application-level services are disclosed. In one example aspect, a method includes providing a set of interfaces to an application-level service deployed in part on a user device. The set of interfaces is configured to provide a notification to the application-level service regarding a real-time change in network conditions relevant to the application-level service. The method also includes receiving a registration request from the application-level service to register for the notification, estimating the network conditions based on physical layer information, and notifying the registered application-level service of the change in the network conditions based on the estimated network conditions.

A receiver circuitry configured to receive, from infrastructure equipment of the wireless telecommunications network, a signal comprising positioning information for allowing a spatial position of the terminal device to be determined using the positioning information and a predetermined positioning scheme associated with the positioning information, the positioning scheme comprising one or more of instructions and additional information for determining the position of the terminal device using the positioning information, wherein the positioning information is comprised within a system information block (SIB) of the received signal; and processing circuitry configured: to determine, based on a characteristic of the SIB, a temporal validity of the received positioning information, and to determine, at a time at which the received positioning information is temporally valid, the spatial position of the terminal device using the received positioning information and the predetermined positioning scheme.

A receiver circuitry configured to receive, from infrastructure equipment of the wireless telecommunications network, a signal comprising positioning information for allowing a spatial position of the terminal device to be determined using the positioning information and a predetermined positioning scheme associated with the positioning information, the positioning scheme comprising one or more of instructions and additional information for determining the position of the terminal device using the positioning information, wherein the positioning information is comprised within a system information block (SIB) of the received signal; and processing circuitry configured: to determine, based on a characteristic of the SIB, a temporal validity of the received positioning information, and to determine, at a time at which the received positioning information is temporally valid, the spatial position of the terminal device using the received positioning information and the predetermined positioning scheme.

A method, an apparatus, an electronic device, and a storage medium for network communication are provided. A first network entity sends a first request message to a second network entity. The first request message includes at least one piece of first network parameter type information, and is used to enable the second network entity to be triggered to send a first message to a third network entity according to a preset event. The first message includes at least one portion of network parameter information corresponding to the first network parameter type information. The first network entity receives a first reply message returned by the second network entity in response to the first request message. Using the present disclosure, the first network entity can dynamically manage an instantiation of the third network entity, and the authority of the third network entity to obtain network parameters.

Example systems, devices, media, and methods are described for presenting a virtual experience using the display of an eyewear device in augmented reality. A content delivery application implements and controls the detecting of beacons broadcast from beacon transmitters deployed at fixed locations and determining the current eyewear location based on the detected beacons. The method includes retrieving content and presenting a virtual experience based on the retrieved content, the beacon data, and a user profile. The virtual experience includes playing audio messages, presenting text on the display, playing video segments on the display, and combinations thereof. In addition to wireless detection of beacons, the method includes scanning and decoding a beacon activation code positioned near the beacon transmitter to access a beacon.

A method of a service enabler architecture layer (SEAL) can include receiving a location reporting configuration at a first user equipment (UE) from a location management server of the SEAL. The location reporting configuration can indicate at least one location reporting event for triggering a first location information report from a first location management client at the first UE to the location management server. The first location information report can be transmitted to the location management server from the first location management client at the first UE in response to the at least one location reporting event occurring. The first location information report can include an identity of the first UE, an identity of the at least one location reporting event that triggers the first location information report, first location information of the first UE, and a first timestamp corresponding to the first location information of the first UE.