Techniques for wireless communications are described. A first device may receive first control signaling that may indicate a second device in a wireless communications system. The first device may then identify, based on the received first control signaling, a set of devices for tracking the second device in the wireless communications system. In some examples, the first device may then transmit second control signaling to the identified set of devices for tracking the second device in the wireless communications system. The first device may then receive, based on the transmitted second control signaling, coordination information from the set of devices. The received coordination information may be associated with the second device. The coordination information collected by the set of devices may be used to predict changes in an environment surrounding the second device. By predicting dynamic changes in the environment, disruptions in wireless communication may be prevented.

Techniques for wireless communications are described. A first device may receive first control signaling that may indicate a second device in a wireless communications system. The first device may then identify, based on the received first control signaling, a set of devices for tracking the second device in the wireless communications system. In some examples, the first device may then transmit second control signaling to the identified set of devices for tracking the second device in the wireless communications system. The first device may then receive, based on the transmitted second control signaling, coordination information from the set of devices. The received coordination information may be associated with the second device. The coordination information collected by the set of devices may be used to predict changes in an environment surrounding the second device. By predicting dynamic changes in the environment, disruptions in wireless communication may be prevented.

Systems and methods for an On-Demand Autonomy (ODA) service. The system includes a set of functional modules enabled for ODA service activities disposed in a follower vehicle (Fv) in communication with an ODA server that includes a user request module configured to receive request information from the Fv from the ODA server, and to process and communicate the request information to the schedule module; the schedule module configured to coordinate an arrival time information with the ODA server for pickup of the Fv based on the request information, and communicate the arrival time information to the schedule execution module; the schedule execution module configured to direct the Fv to a pickup point based on the arrival time information, and communicate the pickup point to the indication module; and the indication module configured to provide alerts to vehicles in the vicinity of the pickup of the Fv via the ODA service.

A method for delivering quality of service to a moving user equipment in a computer network, the method including: identifying a moving user equipment on the computer network; predicting a path of travel for the user equipment; determining a load of a cell in the path of travel; determining a traffic action response based on the load of the cell; and providing the traffic action. A system for delivering quality of service to a moving user equipment in a computer network, the system including: a location module configured to identify a moving user equipment on the computer network; an analysis module configured to predict a path of travel for the user equipment; a load module configured to determine a load of a cell in the path of travel; and a traffic action module configured to determine a traffic action response based on the load of the cell and provide for the traffic action.

A method for authenticating a user terminal as a transmitter of a message transmitted in a wireless communication network having a plurality of spatially distributed user terminals, The message is transmitted from a first user terminal to at least one second and/or one third user terminal with the aid of a wireless communications connection. The message includes useful data, first user-terminal-specific and second user-terminal-specific authentication data. The first user terminal is authenticated as the transmitter of the message based on the first user-terminal-specific authentication data with the aid of the second user terminal, and/or based on the second user-terminal-specific authentication data with the aid of the third user terminal.

A vehicle software management system includes a management controller mounted on a vehicle to perform an update of software of a performance controller, and an over-the-air (OTA) server for transmitting a software package for roll back and a software package for the update to the management controller based on whether the management controller has the software package for the roll back, and the management controller performs roll back of the software of the performance controller using the software package for the roll back when the update of the software of the performance controller using the software package for the update fails.

A vehicle software management system includes a management controller mounted on a vehicle to perform an update of software of a performance controller, and an over-the-air (OTA) server for transmitting a software package for roll back and a software package for the update to the management controller based on whether the management controller has the software package for the roll back, and the management controller performs roll back of the software of the performance controller using the software package for the roll back when the update of the software of the performance controller using the software package for the update fails.

A distributed data processing system includes a processing center or algorithm persistence system (“APS”), a series of remote caching nodes in electronic communication with the APS, and a series of remote computing or processing nodes in electronic communication with the remote caching nodes. Each remote caching node is mounted to a top surface of a mobile vehicle and includes a data transmitter/receiver (transceiver), computer hardware and software to operate the caching node, memory to transmit or transfer data from the APS to the remote processing nodes. The remote processing nodes include a series of electricity generating solar panels, a series of electronic data processing chips, electronic data memory, an electronic date transmitter/receiver (transceiver), and a motion sensor. The series of electronic data processing chips are preferably a tensor processing unit (TPU), which is an AI accelerator application-specific integrated circuit (ASIC) developed specifically for neural network machine learning.

A distributed data processing system includes a processing center or algorithm persistence system (“APS”), a series of remote caching nodes in electronic communication with the APS, and a series of remote computing or processing nodes in electronic communication with the remote caching nodes. Each remote caching node is mounted to a top surface of a mobile vehicle and includes a data transmitter/receiver (transceiver), computer hardware and software to operate the caching node, memory to transmit or transfer data from the APS to the remote processing nodes. The remote processing nodes include a series of electricity generating solar panels, a series of electronic data processing chips, electronic data memory, an electronic date transmitter/receiver (transceiver), and a motion sensor. The series of electronic data processing chips are preferably a tensor processing unit (TPU), which is an AI accelerator application-specific integrated circuit (ASIC) developed specifically for neural network machine learning.

A method by which a first device performs sidelink communication is provided. The method comprises the steps of: receiving, from a base station, a sidelink grant associated with a first retransmission resource and an initial transmission resource of a transport block; transmitting, to a second device, a PSCCH and a PSSCH associated with the PSCCH, on the basis of the initial transmission resource; determining a PSFCH resource for receiving a PSFCH from the second device, on the basis of the index of a slot and the index of a subchannel associated with the PSSCH; receiving, from the second device, the PSFCH on a first PSSCH, on the basis of the PSFCH resource; comparing a time interval between the PSFCH resource and the first retransmission resource with a minimum processing time required between the reception of the PSFCH and retransmission of the transport block.