Systems, apparatus, articles of manufacture, and methods are disclosed for distributed and scalable high performance location and positioning. Disclosed example apparatus are to enqueue a data pointer associated with sounding reference signal (SRS) measurement data from a device into a first data queue associated with a first worker core. Disclosed example apparatus are also to generate, with the first worker core, at least one of a reception angle measurement dataset or a time-of-arrival measurement dataset based on the SRS measurement data and dequeue the data pointer associated with the at least one of the reception angle measurement dataset or the time-of-arrival measurement dataset from the first data queue into a second data queue associated with a second worker core. Disclosed example apparatus are further to determine, with the second worker core, a location of the device based on the at least one of the reception angle or time-of-arrival measurement dataset.

Systems and methods for provisioning and managing a network are disclosed. One method can comprise determining location information of one or more access points and selecting a routing device based upon the location information. Communication can be established between the one or more access points and the select routing device to define a mobility group comprising the one or more access points.

Embodiments of the present disclosure relate to methods and apparatuses for sidelink (SL) positioning. According to an embodiment of the present disclosure, a first user equipment (UE) may include: a receiver configured to receive SL positioning configuration information from a second UE, wherein the first UE helps the second UE to acquire its position; a transmitter configured to transmit a location information report to the second UE based on the positioning configuration information; and a processor coupled to the receiver and the transmitter.

One example transmission method includes receiving, by a network device, a first transmission parameter that is sent by a server and that is used to transmit assistance data, where the first transmission parameter includes configuration information and/or priority information, and the configuration information is used to indicate a transmission cycle of each of one or more system messages and/or a size of a data volume that can be carried in each of the one or more system messages, and sending, by the network device, first configuration information to the server according to the first transmission parameter, where the first configuration information is used to indicate a transmission cycle of a first system message and a size of a data volume that can be carried in the first system message, and the one or more system messages include the first system message.

An assistive navigational system for deployment in a facility having a global frame of reference includes: a server including a memory storing: a plurality of anchor definitions each containing (i) an anchor position in the global frame of reference, and (ii) a feature set corresponding to physical characteristics of the facility at the anchor position; and a task definition containing (i) a task position defined relative to the anchor position, and (ii) task overlay data; the server further including a communications interface, and a processor configured to: select one of the anchor definitions for association with the task definition; and transmit the selected anchor definition and the task definition to a mobile computing device, the mobile computing device configured to receive the selected anchor definition and the task definition; the mobile computing device further configured to present the task overlay data on a display.

Systems and methods are provided for reducing network traffic in a mesh network by reducing the number of status messages communicated over the network. The nodes of the network can provide status information to a gateway based on each node's distance from the gateway. The closer nodes respond to the request from the gateway first and then the farther nodes respond to the request. When a node is ready to transmit a status message with status information to the gateway, the node sends the message to the nodes in communication with the transmitting node. One of the closer nodes that receives the message then forwards the message to additional nodes in communication with the forwarding node, while the other nodes that received the message do not forward the message. The process of forwarding messages by a single closer node is repeated until the status information is received by the gateway.

The present invention discloses a capacity optimization method for a mobile optical wireless communication system and a communication method and system. The capacity optimization method includes the following steps: establishing a mobile channel impulse response model; calculating an electrical signal-to-noise ratio (SNR) of an output of a receiver; calculating bit error rate (BER) values of an optical wireless communication system in different candidate modulation formats according to the electrical SNR of the output of the receiver; selecting a first modulation format and a second modulation format from the different candidate modulation formats; determining quantities of chips in the first modulation format and the second modulation format in each data frame; and building a time domain hybrid modulation frame according to the quantities of chips in the first modulation format and the second modulation format, modulating data by using the time domain hybrid modulation frame, and performing data transmission.

A method, system and apparatus are disclosed. In one or more embodiments, a network node for communicating with a wireless device is provided. The network node includes processing circuitry configured to receive measurement capability information of a wireless device where the measurement capability information indicates an ability to perform a global navigation satellite system, GNSS, measurement. The processing circuitry is further configured to determine a GNSS measurement gap configuration during which the wireless device is to perform at least one GNSS measurement during at least one GNSS measurement gap where the GNSS measurement gap configuration is based at least in part on the received measurement capability information, and indicate the GNSS measurement gap configuration to the wireless device.

A method of arranging a plurality of devices whose arrangement is specified by an arrangement specifying system. The arrangement specifying system specifies a correspondence of an arrangement of the devices on a drawing based on information about a distance of any two of the devices and drawing information indicating the arrangement of the devices. The method of arranging the plurality of devices includes arranging the devices such that there is one or both of no symmetric axis and no symmetric point in the arrangement of the devices.

A communication apparatus detects a wireless device and calculates a relative position of the detected wireless device with respect to a reference wireless device to be a reference in identifying a position based on a movement amount of the communication apparatus from when the reference wireless device is detected by the communication apparatus. The communication apparatus associates the calculated relative position, identification information about the detected wireless device, and identification information about the reference wireless device.