Systems and methods are disclosed herein for monitoring a location of a client device associated with a transportation service and generating augmented reality images for display on the client device. The systems and methods use sensor data from the client device and a device localization process to monitor the location of the client device by comparing renderings of images captured by the client device to renderings of the vicinity of the pickup location. The systems and methods determine navigation instructions from the user's current location to the pickup location and select one or more augmented reality elements associated with the navigation instructions and/or landmarks along the route to the pickup location. The systems and methods instruct the client device to overlay the selected augmented reality elements on a video feed of the client device.

In one aspect, a computer-implemented method is disclosed for providing geographic imagery. The method may include receiving, at a computing device, a request for a geographic image, wherein the geographic image depicts at least a portion of a selected location within a geographic area. In addition, the method may include presenting, with the computing device, the geographic image and superimposing a map including normalized travel way data associated with the geographic area over at least a portion of the geographic image.

A device and a method are provided. The device includes a communication module, a memory, and a processor. The processor is configured to acquire position information of a vehicle via the communication module, determine whether high definition (HD) map information corresponding to the position information is acquired, display three-dimensional (3D) navigation information in augmented reality by using the HD map information when the HD map information is acquired, and display two-dimensional (2D) navigation information in augmented reality when the HD map information is not acquired. The 3D navigation information is information in which virtual 3D graphic information for driving guidance is spatially matched to and displayed on an actual object in the real world by using the HD map information, and the 2D navigation information is information in which virtual 2D graphic information for driving guidance is planarly matched to and displayed on an actual object in the real world.

A racing coach device stores a first path of travel along a racetrack over a first time period and a second path of travel along the racetrack over a second time period. The racing coach device identifies, for each of a plurality of geolocations along the racetrack, one of the first path of travel or the second path of travel that is associated with a shorter duration of time over which the user traversed a segment of the path of travel associated with each of the plurality of geolocations. The device determines an optimal path of travel along the racetrack based on the identified first and second path of travel for each segment of the path of travel at each of the plurality of geolocations that results in a calculated lap time to traverse the racetrack that is less than the first time period and the second time period.

A method, an apparatus, an electronic device and a storage medium for displaying an AR navigation are provided. The method may include: recognizing a navigation scene at a current moment during an AR navigation; determining, according to a preset mapping relationship between a navigation scene and a service function, a current service function corresponding to the navigation scene at the current moment; and displaying the current service function corresponding to the navigation scene at the current moment in the navigation scene at the current moment. According to embodiments of the present disclosure, different service functions may be flexibly displayed for different navigation scenes. Therefore, a multi-channel output in the different navigation scenes may be realized, thus saving maintenance time and a maintenance cost.

A motor vehicle has at least one driver assistance system and a navigation system that generates a three-dimensional map and a route-related navigation representation when route guidance is activated by the navigation system. When the at least one driver assistance system is activated, sensor data describing the surroundings of the motor vehicle are acquired by at least one sensor unit of the motor vehicle according to a data acquisition rule of the driver assistance system. The acquired sensor data is evaluated to generate at least one driver assistance related additional information representation. The map with the route-related navigation representation and the driver assistance related additional information representation are output by a display device in the motor vehicle.

A vehicular vision system includes a camera disposed at a vehicle, an electronic control unit, and a video display disposed in the vehicle. The system, responsive to processing of captured image data, displays video images on the video display. The system retrieves graphic overlay data from memory. The graphic overlay data represents a plurality of graphic overlay portions, with each graphic overlay portion being associated with a respective display portion of a plurality of display portions of the video display. Responsive to occurrence of a driving condition, the system retrieves graphic overlay data, displays the graphic overlay portions, and adjusts a transparency of one or more of the displayed graphic overlay portions such that at least one displayed graphic overlay portion is viewable by the driver and at least one other displayed graphic overlay portion is not viewable by the driver.

A method of obtaining a route from a point of departure to a destination includes providing route guidance through an augmented reality (AR) view including an image captured by a camera. To provide route guidance, as a user terminal moves toward a destination on the basis of an obtained route, when an interaction occurs between the user terminal and a node or a link in which predetermined information included in the route is registered, content associated with the predetermined information is augmented and displayed as guidance information on an image of an AR view.

A lifting gantry device for containers, in particular of the straddle carrier or sprinter carrier type, having four gantry supports spaced apart from one another and which by wheels of the lifting gantry device is floor-based and freely movable. A vehicle controller is provided such that the lifting gantry device can be controlled automatically. A sensor system is also provided and configured to determine sensor data on the surroundings of the lifting gantry device for automatically controlling the lifting gantry device. The sensor system comprises at least two, preferably four, sensor units for contactless object measurement and in particular object recognition, of which one sensor unit each is arranged on one of the four gantry supports and is configured to determine sensor data on the surroundings of the lifting gantry device for object measurement and in particular object recognition.

In accordance with an aspect of the present disclosure, there is provided a landmark position estimating method performed by a landmark position estimating apparatus. The method comprises, identifying a first type landmark and a second type landmark from an image, captured by an image capturing device of a vehicle, including various landmarks on a driving route, estimating a three-dimensional position of the identified first type landmark based on a plurality of the images on which the first type landmark is identified and a digital map including a driving area of the vehicle, and estimating a position of the identified second type landmark on a virtual plane including the three-dimensional position of the first type landmark.