A method performed by a vehicle feature evaluation system (1) for enabling evaluation of a simulated vehicle-related feature. The vehicle feature evaluation system determines (1001) in relation to a road-driven vehicle (2), with support from a tracking system (5), an orientation of a head-mounted display (4), HMD, adapted to be worn by an occupant (3) on-board the road-driven vehicle. The vehicle feature evaluation system further determines (1002) a simulated vehicle design feature to be evaluated in the road-driven vehicle. Moreover, the vehicle feature evaluation system provides (1006) in real-time to a HMD display (41) of the HMD, taking into consideration the HMD orientation, a virtual representation (7) of the simulated vehicle design feature superimposed on a real-time surrounding-showing video stream (6) derived from real-world image data (211) captured with support from one or more vehicle-attached cameras (21) adapted to capture surroundings external of the road-driven vehicle.

A full motion racing simulator is configured based on a real motor vehicle and includes wheels, a vehicle frame, and an actuating system for pivotably supporting the vehicle frame on the wheels. The actuating system includes a plurality of actuating assemblies each including a connecting structure pivotably connecting the vehicle frame to a corresponding one of the wheels, an actuator pivotably mounted to the vehicle frame, a push element pivotably connected to the connecting structure, and a rocker arm rotatably mounted to the vehicle frame and pivotably connected to the actuator and the push element. Upon actuation of the actuator, the actuator causes the rocker arm to rotate relative to the vehicle frame and to push the push element such that the push element causes the connecting structure to pivot relative to the wheels and to move the vehicle frame.

A full motion racing simulator is configured based on a real motor vehicle and includes wheels, a vehicle frame, and an actuating system for pivotably supporting the vehicle frame on the wheels. The actuating system includes a plurality of actuating assemblies each including a connecting structure pivotably connecting the vehicle frame to a corresponding one of the wheels, an actuator pivotably mounted to the vehicle frame, a push element pivotably connected to the connecting structure, and a rocker arm rotatably mounted to the vehicle frame and pivotably connected to the actuator and the push element. Upon actuation of the actuator, the actuator causes the rocker arm to rotate relative to the vehicle frame and to push the push element such that the push element causes the connecting structure to pivot relative to the wheels and to move the vehicle frame.

The present disclosure relates to a system for digital support of a work process including: a database for accepting different data and data types; a means for planning a work process that has access to the database and is configured to store a work plan in the database; a means for analyzing the work plan that carries out an analysis using the present data of the database to carry out an optimization of the work plan; a means for simulating the work plan that has access to the database and that is configured to output data for simulating the work plan; and a means for navigation support and control support of a machine that has access to the database and that is configured to communicate specific data of the work plan from the database to an associated machine during and/or before the real implementation of the work plan.

The disclosed video processing device contains: a video acquisition unit that acquires surroundings information including video taken of the surroundings of a vehicle; a line-of-sight acquisition unit that acquires the origin and direction of the line of sight of the driver of the aforementioned vehicle; a line-of-sight video generation unit which generates, from the surroundings information, line-of-sight video corresponding to the origin of the line of sight; a blocking-information computation unit that computes, on the basis of the origin of the line of sight, blocking information including video or a region of the body of the aforementioned vehicle that blocks the driver's line of sight; and a display-video generation unit that generates display video on the basis of the line-of-sight video and the blocking information.

The disclosed video processing device contains: a video acquisition unit that acquires surroundings information including video taken of the surroundings of a vehicle; a line-of-sight acquisition unit that acquires the origin and direction of the line of sight of the driver of the aforementioned vehicle; a line-of-sight video generation unit which generates, from the surroundings information, line-of-sight video corresponding to the origin of the line of sight; a blocking-information computation unit that computes, on the basis of the origin of the line of sight, blocking information including video or a region of the body of the aforementioned vehicle that blocks the driver's line of sight; and a display-video generation unit that generates display video on the basis of the line-of-sight video and the blocking information.

Systems and methods for material handling vehicle simulation are provided. In one aspect, a material handling vehicle simulation system includes a material handling vehicle having a plurality of controls operable to manipulate the material handling vehicle to perform a desired operation, and a vehicle controller configured to selectively transition between a standard mode where the vehicle controller is configured to instruct the vehicle to perform standard operating tasks and a simulation mode. The material handling simulation system further includes a simulation kit having a simulation display, and a simulation controller in communication with the plurality of controls and the simulation display. When the vehicle controller is in the simulation mode, the simulation controller is configured to simulate operation of the material handling vehicle on the simulation display in response to manipulation of at least one of the plurality of controls.

Driving rating information for other vehicles in an external environment of a vehicle can be provided. The external environment of the vehicle can be sensed to detect the other vehicles. Driving rating information for the other vehicles can be received, such as directly from the other vehicles or from a remote driving ratings source. The driving rating information for the other vehicles can be presented within the vehicle. Based on such driving rating information, a vehicle occupant can decide whether or not to lead or follow a particular vehicle in the external environment. If a selection of one of the identified one or more vehicles is received from a vehicle occupant, the vehicle can be caused to implement one or more driving maneuvers relative to the selected vehicle.

A method and an apparatus for adjusting a driving training course, an electronic device, and a storage medium are provided, and relates to the field of driving information management, driving training course optimization, and the like. The method includes: collecting current training data in a current training course of a learner driver; acquiring historical training data of the learner driver; comparing the current training data and the historical training data with a corresponding evaluation criterion to obtain an evaluation result; and adjusting a subsequent training course of the learner driver according to the evaluation result.

An interaction test system provides a first virtual reality layer associated with a first test environment to a first test object and a second virtual reality layer associated with a second test environment to a second test object, such that a mixed reality perceived by the first and second test objects correspond. The system derives first object data including status information and/or actions of the first test object, provides first object behavior data to the second virtual reality layer such that status information and/or actions of the first object are included in the mixed reality perceived by the second object, derives second object data including status information and/or actions of the second test object, and provides second object behavior data to the first virtual reality layer such that status information and/or actions of the second object are included in the mixed reality perceived by the first object.