A quick positioning method and a vehicle-mounted system are disclosed. The quick positioning method includes: acquiring position information from an external positioning terminal the same time when the vehicle-mounted system is started, and determining continuously whether position information is available from a local GPS positioning module; and using the position information acquired from the external positioning terminal until position information is available from the local GPS positioning module. By the above method, there would be available position information before the GPS module of the vehicle-mounted system is fully activated, thus effectively enhancing the positioning efficiency of the vehicle-mounted system.

Disclosed are methods and systems for obtaining measurements of a range between devices based on a Round Trip Time (RTT) for an exchange messages. In particular, described are techniques for sharing channel parameters between or among wireless transceiver devices to assist in initiating exchange of signals between neighboring wireless transceiver devices.

Disclosed are methods and systems for obtaining measurements of a range between devices based on a Round Trip Time (RTT) for an exchange messages. In particular, described are techniques for sharing channel parameters between or among wireless transceiver devices to assist in initiating exchange of signals between neighboring wireless transceiver devices.

The travel control system includes: a travel zone holding unit configured to hold a travel zone which is set in a particular travel area set beforehand and over which a dump truck is to autonomously travel; a target position setting unit configured to set, on an outer side of the particular travel area, a target position that the dump truck is to reach; a distance measurement unit configured to measure a traveling distance of the dump truck from a position of the dump truck as acquired using a position acquisition device provided in the dump truck to the target position set by the target position setting unit; and an autonomous travel control unit configured to control the dump truck so that the dump truck moves to an outer side of a travel zone held by the travel zone holding unit and autonomously travels the traveling distance.

Various embodiments relate to creating and utilizing a vehicle surveillance network to monitor objects and/or events. Messages may be broadcasted from at least one communication system of a surveillance network which is communicating with one or more vehicles of the surveillance network and received in a vehicle. Instructions may be transmitted to at least one vehicle camera to capture one or more images of objects or events outside of the vehicle in response to receiving the at least one broadcasted message. At least one vehicle camera in each of the vehicles of the surveillance network may capture the images of the object and/or events. Further instructions may include transmitting the captured images from the one or more vehicles to one or more event responders.

Various embodiments relate to creating and utilizing a vehicle surveillance network to monitor objects and/or events. Messages may be broadcasted from at least one communication system of a surveillance network which is communicating with one or more vehicles of the surveillance network and received in a vehicle. Instructions may be transmitted to at least one vehicle camera to capture one or more images of objects or events outside of the vehicle in response to receiving the at least one broadcasted message. At least one vehicle camera in each of the vehicles of the surveillance network may capture the images of the object and/or events. Further instructions may include transmitting the captured images from the one or more vehicles to one or more event responders.

Disclosed is a technology for increasing a positioning success rate and reducing a positioning error with high reliability by proposing an improved positioning scheme based on virtual satellites capable of improving DOP and removing an error in a satellite measurement value when a location of a terminal in an inadequate environment such as downtown/indoors near a window is measured.

Disclosed is a technology for increasing a positioning success rate and reducing a positioning error with high reliability by proposing an improved positioning scheme based on virtual satellites capable of improving DOP and removing an error in a satellite measurement value when a location of a terminal in an inadequate environment such as downtown/indoors near a window is measured.

The present disclosure relates generally to satellite communication systems, and, more particularly, to trilateration-based satellite location accuracy for improved satellite-based geolocation are provided. In one embodiment, a method comprises: determining, by a processing device, a location of each of a plurality of reference antennas with known locations; obtaining a plurality of distances between a communication satellite and the plurality of reference antennas, each distance of the plurality of distances corresponding to a respective reference antenna of the plurality of reference antennas, at least one distance of the plurality of distances based on an echo message communicated between a particular reference antenna of the plurality of reference antennas and the communication satellite; determining an accurate location of the communication satellite based on trilateration of the plurality of distances from the known locations of the plurality of reference antennas; and utilizing the accurate location of the communication satellite.

A method includes when a first mobile station uploads an observation value, determining whether a tracking station for performing Real-Time Kinematic (RTK) resolution on the first mobile station is included; otherwise, determining a second mobile station that obtains an RTK fixed solution and satisfies a preset condition as a temporary base station; selecting one of the determined temporary base stations as the tracking station for performing RTK resolution on the first mobile station; and performing RTK resolution according to the selected tracking station for performing RTK resolution on the first mobile station. The second mobile station is another mobile station other than the first mobile station. When the tracking station for performing RTK resolution on the first mobile station is not included, a temporary base station is selected for RTK resolution, and the coverage of an RTK service is expanded without adding the tracking station.