A method is provided for reconfiguring a vehicle for transfer from a first operator to a second operator. The method includes accessing first datasets that define an initial configuration of the vehicle, importing second datasets that describe maintenance, repair or service of the vehicle during in-service operation with the first operator, and generating a first composite dataset defining a current configuration of the vehicle. The method also includes accessing third datasets that define requirements of the vehicle for in-service operation with the second operator, and generating a second composite dataset that defines a target configuration of the vehicle from the first composite dataset and based on data of the third datasets. The method includes comparing the first and second composite datasets to identify modifications to reconfigure the vehicle from the current configuration to the target configuration, and generating a visual presentation of the modifications to facilitate reconfiguration of the vehicle.

An embodiment user equipment includes an image sensor configured to photograph a surrounding image, a display module, a communicator configured to communicate with a server, a database configured to store visual positioning system (VPS) map information based on augmented reality (AR) and two dimensional (2D) map information, and a controller configured to generate 2D route information based on the 2D map information and delivery information received from the server, generate three dimensional (3D) route information based on the delivery information and the VPS map information, and control the display module to display the 2D route information or the 3D route information based on a distance between the user equipment and a point of interest (POI) included in the delivery information, the 3D route information being based on augmented reality.

A illustrative method includes providing, for display by a display device, a first preview of a three-dimensional (3D) virtual reality video in a 3D object in a virtual reality menu user interface, the first preview of the 3D virtual reality video corresponding to a first location within the 3D object, receiving data describing a rotation of the 3D object in the virtual reality menu user interface, and providing, for display by the display device and based on the rotation of the 3D object, a second preview of the 3D virtual reality video in the 3D object in the virtual reality menu user interface, the second preview of the 3D virtual reality video corresponding to a second location within the 3D object.

An electronic device according to various embodiments may include: a housing, a flexible display having at least a partial area configured to be drawn out from the housing so that a size of a visible area of the flexible display can be changed, a sensor configured to measure a length of the flexible display, a memory, a processor operatively connected to the memory, the sensor, and the flexible display. The processor may be configured to control the electronic device to: display a first content including at least one image in a first area including a partial area of the flexible display in response to an input, measure a length of the flexible display drawn out from the housing using the sensor, based on the length of the flexible display measured using the sensor being a specified first length, determine that the electronic device is in a non-expanded state, and based on the length of the flexible display measured using the sensor being a second length longer than the first length, determine that the electronic device is in an expanded state. In addition, the processor may be configured to control the electronic device to: based on the electronic device being in an expanded state, display the first content in the first area, and display a user interface corresponding to at least one application and/or second content obtained by converting the first content into a form corresponding to a function provided by the at least one application in a second area including a partial area of the flexible display, drawn out from the housing to be visible, and transmit, in response to an input, data corresponding to the first content to a server connected to the at least one application.

The invention relates to devices and methods for co-browsing a web page, namely, to the field of data processing systems that allow multiple end users to simultaneously browse the same website from different locations and devices in a virtual room. A system for co-browsing a web page is proposed, comprising a sharing confirmation module; a platform login verification module; a virtual room creation module; a sharing determination module; a data communication module, configured to provide content to the shared platform for sharing; an event communication module; a module for executing and displaying events on the end-user device. The proposed method comprises the steps of: accepting the shared content selected by the user and the shared platform selected by the user; navigating to the unified verification interface so that a user can log into the shared platform through the unified verification interface; creating a virtual room for co-browsing, and assigning a unique room ID to it, and saving the room ID for all participants; receiving an instruction from the user to perform an action on the web page; capturing the action via browser event handler; transforming the action and its properties into a JSON message; sending the specified message to the system server via the WebSockets protocol; receiving the message by means of the room end-user device, and refreshing the web page to display the updated website state.

An apparatus and method for managing pipes and planes within a virtual graphics processing engine. For example, one embodiment of a graphics processing apparatus comprises: a graphics processor comprising one or more display pipes to render one or more display planes, each of the one or more display pipes comprising a set of graphics processing hardware resources for executing graphics commands and rendering graphics images in the one or more display planes; and pipe and plane management hardware logic to manage pipe and plane assignment, the pipe and plane management hardware logic to associate a first virtual machine (VM) with one or more virtual display planes and to maintain a mapping between the one or more virtual display planes and at least one physical display plane.

In some implementations, a user device can coordinate adjustments to a composite GUI generated in cooperation with an accessory device that presents the composite graphical user interface. For example, the user device can receive configuration data that defines the maximum GUI display area (e.g., size, dimensions) of the accessory device, various view areas within the GUI display area of the accessory device into which the user device can render GUIs, and/or transitions between the various view areas. The user device can generate a display buffer based on the maximum GUI display area, generate a graphical user interface in an area of the buffer corresponding to a current view area specified by the accessory device, and send to the accessory device video frames corresponding to the display buffer. The accessory device can generate a composite GUI based on the received video frames that include the user device generated GUI.

A method of casting a source device display screen to a target device includes, by an application on the source device, storing information about the target device in a shared memory and issuing a request to an operating system to initiate capturing and casting for the source device display screen. The operating system responds to the request by launching a casting extension and supplying a content stream containing content of the source device display screen. Upon being launched, the casting extension (1) obtains the information about the target device from the shared memory and uses the information to establish a display connection with the target device, and (2) forwards the content stream to the target device on the display connection.

The present disclosure describes techniques for generating, maintaining, and operating a cooperative virtual reality (VR) environment across multiple computing devices. By utilizing these techniques, disparate users are able to work independently or in collaboration on projects within a single VR environment without the latency issues that plague prior VR environments. That is, unlike prior systems which are plagued with latency issues that interrupt the user's VR experience, the techniques described in the present disclosure allow for cooperative VR environments to be rendered in real time across large numbers of computing devices while enabling each computing device to provide a smooth user experience. Additionally, the techniques described herein distribute the data processing and analysis between the VR server and the individual computing devices rendering the cooperative VR environment.

It is possible to optimize a mode of a screen for watching content. An image processing apparatus (10) according to the present disclosure includes: a shape determination unit (152) that determines a screen shape suitable for displaying content on the basis of an automated driving state of a vehicle and information regarding the content to be displayed on a screen provided in the vehicle; and an image creation unit (153) that creates an image of the content to be displayed on the screen according to the shape determined to be suitable for displaying the content by the shape determination unit (152).