A driving guidance system that provides a driving guidance to a driver when the driver makes operations to remotely control a vehicle in a driving route. The driving guidance system includes at least one driving guidance equipment, an analytic engine, a control platform. The driving guidance equipment is distributed along the driving route for recording data of the vehicle. The analytic engine receives and analyzes the data of the vehicle to generate a plurality of features of the vehicle. The control platform further includes a real virtuality objects generator and a display. The real virtuality objects generator generates a plurality of real virtuality objects based on the features of the vehicle and the display shows the real virtuality objects to the driver of the vehicle for providing the driving guidance.

A driving guidance system that provides a driving guidance to a driver when the driver makes operations to remotely control a vehicle in a driving route. The driving guidance system includes at least one driving guidance equipment, an analytic engine, a control platform. The driving guidance equipment is distributed along the driving route for recording data of the vehicle. The analytic engine receives and analyzes the data of the vehicle to generate a plurality of features of the vehicle. The control platform further includes a real virtuality objects generator and a display. The real virtuality objects generator generates a plurality of real virtuality objects based on the features of the vehicle and the display shows the real virtuality objects to the driver of the vehicle for providing the driving guidance.

A heavy equipment simulation system for simulating an operation of a heavy equipment vehicle in a virtual environment is described herein. The heavy equipment simulation system includes a support frame, an operator input control assembly coupled to the support frame for receiving input from a user, a motion actuation system coupled to the support frame for adjusting an orientation of the support frame with respect to a ground surface, a display device assembly configure to display the virtual environment including the simulated heavy equipment vehicle, a virtual reality (VR) headset unit adapted to be worn by the user, and a control system.

A heavy equipment simulation system for simulating an operation of a heavy equipment vehicle in a virtual environment is described herein. The heavy equipment simulation system includes a support frame, an operator input control assembly coupled to the support frame for receiving input from a user, a motion actuation system coupled to the support frame for adjusting an orientation of the support frame with respect to a ground surface, a display device assembly configure to display the virtual environment including the simulated heavy equipment vehicle, a virtual reality (VR) headset unit adapted to be worn by the user, and a control system.

A heavy equipment simulation system for simulating an operation of a heavy equipment vehicle in a virtual environment is described herein. The heavy equipment simulation system includes a support frame, an operator input control assembly coupled to the support frame for receiving input from a user, a motion actuation system coupled to the support frame for adjusting an orientation of the support frame with respect to a ground surface, a display device assembly configure to display the virtual environment including the simulated heavy equipment vehicle, a virtual reality (VR) headset unit adapted to be worn by the user, and a control system.

A heavy equipment simulation system for simulating an operation of a heavy equipment vehicle in a virtual environment is described herein. The heavy equipment simulation system includes a support frame, an operator input control assembly coupled to the support frame for receiving input from a user, a motion actuation system coupled to the support frame for adjusting an orientation of the support frame with respect to a ground surface, a display device assembly configure to display the virtual environment including the simulated heavy equipment vehicle, a virtual reality (VR) headset unit adapted to be worn by the user, and a control system.

Systems and methods for providing driver situational awareness recovery training in a virtual reality environment are disclosed. According to some aspects, a virtual reality driving simulation may be determined based on one or more input parameters. The virtual reality driving simulation may include: i) an autonomous vehicle for executing a transition from a first level of vehicle control to a second level of vehicle control, and (ii) a driving scenario for the user to practice situational awareness recovery in response to the transition. The first level requires an automated driving system to monitor the driving environment and control the autonomous vehicle, and the second level requires a human driver to monitor the driving environment and control the autonomous vehicle. While the virtual reality driving simulation is rendered, user performance data may be recorded. Based on an analysis of the user performance data, a driving competency score may be determined.

A system and method for generating simulated vehicles with configured behaviors for analyzing autonomous vehicle motion planners are disclosed. A particular embodiment includes: obtaining configuration instructions and data for each of a plurality of simulated vehicles, a specific driving behavior for each of the plurality of simulated vehicles corresponding to perception data obtained from perception data sensors; and generating a plurality of trajectories and acceleration profiles to transition each of the plurality of simulated vehicles from a current position and speed to a corresponding target position and target speed, the target position and the target speed corresponding to the specific driving behavior for each of the plurality of simulated vehicles.

A system and method for generating simulated vehicles with configured behaviors for analyzing autonomous vehicle motion planners are disclosed. A particular embodiment includes: obtaining configuration instructions and data for each of a plurality of simulated vehicles, a specific driving behavior for each of the plurality of simulated vehicles corresponding to perception data obtained from perception data sensors; and generating a plurality of trajectories and acceleration profiles to transition each of the plurality of simulated vehicles from a current position and speed to a corresponding target position and target speed, the target position and the target speed corresponding to the specific driving behavior for each of the plurality of simulated vehicles.

A heavy equipment simulation system for simulating an operation of a heavy equipment vehicle in a virtual environment is described herein. The heavy equipment simulation system includes a support frame, an operator input control assembly coupled to the support frame for receiving input from a user, a motion actuation system coupled to the support frame for adjusting an orientation of the support frame with respect to a ground surface, a display device assembly configure to display the virtual environment including the simulated heavy equipment vehicle, a virtual reality (VR) headset unit adapted to be worn by the user, and a control system.