The present disclosure relates to positioning methods, systems, and apparatuses. One example method includes receiving, by a server, a first message from a first terminal device, where the first message includes first location information determined by the first terminal device, determining, by the server, a first reference object based on the first location information, and sending, by the server, a second message to the first terminal device, where the second message includes identification information of the first reference object, and the identification information of the first reference object is used by the first terminal device to update the first location information.

Provided are an in-vehicle wireless communication apparatus, a wireless communication system, a wireless communication apparatus, and a vehicle control method configured to realize prompt external control of a vehicle. An in-vehicle wireless communication apparatus according to the present embodiment includes a wireless communication unit configured to perform wireless communication with an out-of-vehicle apparatus installed outside the vehicle, and a processing unit configured to perform processing related to communication, and the processing unit transmits information regarding a data format of control data to be output to an in-vehicle network by an in-vehicle control apparatus that controls the vehicle, to the out-of-vehicle apparatus using the wireless communication unit, receives data transmitted from the out-of-vehicle apparatus using the wireless communication unit, the data including control data having the data format, and outputs the control data included in the received data to the in-vehicle network.

A method of controlling an autonomous vehicle and an electronic device are provided, which relate to a field of artificial intelligence technology, and in particular to a field of autonomous driving technology. The method includes: acquiring a vehicle state configuration information from a cloud; enabling a task receiving function of the vehicle, in response to the vehicle state configuration information indicating that the vehicle is in an automatic operation state; acquiring a task information from the cloud in response to the task receiving function being enabled; and controlling the vehicle according to the task information.

An emergency reporting system for a vehicle includes a server memory, an acquisition control processor, and first and second authentication processors. The server memory holds personalized emergency data regarding an occupant to be on board the vehicle or access data to the personalized emergency data. The acquisition control processor makes acquirable the personalized emergency data or the access data held in the server memory regarding the occupant on board the vehicle in which an emergency situation is detected by a detector of the vehicle, in a case where a server apparatus receives an emergency report from the vehicle in which the emergency situation is detected, and at least a combination of the occupant and the vehicle is authenticated by the second authentication processor.

An autonomous vehicle (AV) includes features that allows the AV to comply with applicable regulations and statues for performing safe driving operation. An example system for an AV includes a communications gateway device. The communications gateway device includes a plurality of modules each configured for different communication mediums or applications. In particular, the plurality of modules includes a first module for communicating with a remote computer. Via the first module, vehicle operational data is reported to the remote computer, and instructional data is received from the remote computer. The modules further include a second module for communicating with devices located within a vicinity external to the vehicle, and a third module configured to communicate with subsystems located within the vehicle. The example AV system includes a second communications gateway device that is configured to be redundant.

An embodiment wireless charging vehicle includes a secondary charging pad configured to generate an induced current by a magnetic field generated to a primary charging pad of a wireless charging station and to charge a battery, a plurality of ultra-wideband (UWB) tags disposed to surround the vehicle, and a UWB controller configured to perform a wireless charging arrangement mode for arranging the secondary charging pad on the primary charging pad by using a sensor value measured by the UWB tags, wherein the UWB controller is configured to calculate a coordinate of the primary charging pad by using a line of sight (LOS) sensor value of a UWB tag having a line of sight from among the UWB tags.

A vehicle setting system includes an occupant data acquisition processor, a server apparatus including a provisional generation processor, a provisional acquisition processor, and a setting processor. The occupant data acquisition processor acquires or estimates physical data regarding an occupant on board the vehicle, at least in a case with absence of a setting value for the occupant held in a vehicle memory of a vehicle. The provisional generation processor acquires the physical data regarding the occupant, and generates a provisional setting value for the relevant occupant. The provisional acquisition processor acquires the provisional setting value. The setting processor records, in a vehicle memory of the vehicle, the provisional setting value as the setting value for the occupant, and provides the vehicle with setting of the provisional setting value.

Disclosed is a system for controlling Classes of an eBike. The eBike having a motor and a motor controller. The system includes a server, a dashboard and an input unit. The server stores Classes instructions to operate the eBike in one of the one or more Classes. The dashboard includes a memory unit for storing motor instructions, a processing unit for processing the stored motor instructions to operate the motor under the instructions from the server, a display unit for displaying the processed instructions and the Classes instructions, and a bi-directional communication unit to communicate with the server. The input unit wirelessly communicates with the server. The Classes instructions includes a Classes display module to display the one or more Classes and a Classes module for allowing a user to select one of the one or more Classes via the input unit. The processed motor instructions are communicated to the motor via the motor controller to ride the eBike in the selected Class.

Disclosed is a system for controlling Classes of an eBike. The eBike having a motor and a motor controller. The system includes a server, a dashboard and an input unit. The server stores Classes instructions to operate the eBike in one of the one or more Classes. The dashboard includes a memory unit for storing motor instructions, a processing unit for processing the stored motor instructions to operate the motor under the instructions from the server, a display unit for displaying the processed instructions and the Classes instructions, and a bi-directional communication unit to communicate with the server. The input unit wirelessly communicates with the server. The Classes instructions includes a Classes display module to display the one or more Classes and a Classes module for allowing a user to select one of the one or more Classes via the input unit. The processed motor instructions are communicated to the motor via the motor controller to ride the eBike in the selected Class.

A wireless network association and authentication system includes an access point that is coupled to an authentication server via a first wireless network. The access point receives, from a first user device that associates with the access point, a first request for access to a second wireless network provided by the access point that is coupled to a wide area network through the first wireless network. The first request includes first authentication information. The access point provides the first request that includes the first authentication information to the authentication server via the first wireless network and receives a first authentication response from the authentication server via the first wireless network. In response to the first authentication response indicating that the first user device is authenticated, the access point provides the first user device access to the second wireless network.