An apparatus for simulating a vehicle traveling on a road and towing a trailer, wherein the apparatus includes a scale model towing vehicle and trailer combination positioned on a moving belt of a treadmill. The apparatus has a speed control and a remote control steering mechanism to demonstrate how the vehicle/trailer towing combination will react to vehicle operator inputs under varying conditions, including variations in weight distribution of the trailer load.

A modular multi-axis simulator system for use in concert with a graphical display, gaming console/computer at an affordable scale is described. The simulator is equipped with at least one modular seat, which may be easily interchanged by the owner for differing seats which correspond to the programmed experience. The seat is disposed within a set of rings, which are configured to rotate, facilitating shift and rotation of the seat(s) about multiple axes. The shifting, rotating, and vibrating of the seat(s) occurs such that the movements correspond to visual stimuli presented via the computer/console and graphical display. Additional features such as wind simulation, a odor emission, a solenoid-equipped body suit, and a VR headset may be added to further enhance the experience, providing enhanced realistic simulation within one's home.

A modular multi-axis simulator system for use in concert with a graphical display, gaming console/computer at an affordable scale is described. The simulator is equipped with at least one modular seat, which may be easily interchanged by the owner for differing seats which correspond to the programmed experience. The seat is disposed within a set of rings, which are configured to rotate, facilitating shift and rotation of the seat(s) about multiple axes. The shifting, rotating, and vibrating of the seat(s) occurs such that the movements correspond to visual stimuli presented via the computer/console and graphical display. Additional features such as wind simulation, a odor emission, a solenoid-equipped body suit, and a VR headset may be added to further enhance the experience, providing enhanced realistic simulation within one's home.

A non-transitory computer readable medium contains an evaluation program that causes a computer to perform steps of obtaining a vehicle stability score of vehicle driving skills based on measured data, obtaining a turning performance score of the vehicle driving skills based on the measured data, obtaining an overall evaluation result of the vehicle driving skills based on the vehicle stability score and the turning performance score using conversion information, and conveying the overall evaluation result to an output unit. The conversion information defines the overall evaluation result such that the overall evaluation result decreases as the turning performance score increases if the vehicle stability score is lower than a threshold and such that the overall evaluation result increases as the turning performance score increases if the vehicle stability score is higher than the threshold.

A non-transitory computer readable medium contains an evaluation program that causes a computer to perform steps of obtaining a vehicle stability score of vehicle driving skills based on measured data, obtaining a turning performance score of the vehicle driving skills based on the measured data, obtaining an overall evaluation result of the vehicle driving skills based on the vehicle stability score and the turning performance score using conversion information, and conveying the overall evaluation result to an output unit. The conversion information defines the overall evaluation result such that the overall evaluation result decreases as the turning performance score increases if the vehicle stability score is lower than a threshold and such that the overall evaluation result increases as the turning performance score increases if the vehicle stability score is higher than the threshold.

The invention relates to a method the assessing the controllability of a vehicle by a driver in a risky or problematic situation. In order to carry out assessment of the controllability of a vehicle early, the following steps are provided: a. modelling the drive train and the movement dynamics of the vehicle, b. modelling situation conditions and environmental conditions, c. selecting a risky or problematic situation, d. selecting a driver capability type, e. modelling the driver's reaction as a function of the selected driver capability type. f. simulating the dynamic vehicle behaviour in the longitudinal and transverse directions of a planned trajectory on the basis of the drive train model and movement dynamics model for the predefined situation and environmental conditions when the selected risky or problematic situation occurs, g. calculating the maximum lateral and longitudinal deviation from the planned trajectory between the occurrence of the risky or problematic situation and the regaining of complete control by the driver, h. evaluating the controllability of the vehicle by the driver in the risky or problematic situation on the basis of the maximum lateral and/or longitudinal deviation.

The invention relates to a method the assessing the controllability of a vehicle by a driver in a risky or problematic situation. In order to carry out assessment of the controllability of a vehicle early, the following steps are provided: a. modelling the drive train and the movement dynamics of the vehicle, b. modelling situation conditions and environmental conditions, c. selecting a risky or problematic situation, d. selecting a driver capability type, e. modelling the driver's reaction as a function of the selected driver capability type. f. simulating the dynamic vehicle behaviour in the longitudinal and transverse directions of a planned trajectory on the basis of the drive train model and movement dynamics model for the predefined situation and environmental conditions when the selected risky or problematic situation occurs, g. calculating the maximum lateral and longitudinal deviation from the planned trajectory between the occurrence of the risky or problematic situation and the regaining of complete control by the driver, h. evaluating the controllability of the vehicle by the driver in the risky or problematic situation on the basis of the maximum lateral and/or longitudinal deviation.

The present disclosure is directed to wheel-based human-powered spinning system comprising: a chassis configured to secure a user; a track surrounding said chassis; and at least one omni wheels attached to said chassis, wherein said chassis spins with unlimited range of motion, along pitch, yaw and roll axes, inside the track while supported by said at least one omni wheels, said track being independent of contact from said chassis.

A target vehicle, for example a two-wheeled vehicle, for mounting onto an ADAS (Advanced Driver Assistance System) testing platform is provided. The target vehicle comprises one or more sensors and an actuation assembly comprising an actuator. The sensors are arranged to measure a parameter relating to the dynamics of the target vehicle and may for example comprise accelerometers. The actuation assembly adjusts the tilt of the target vehicle in dependence on the output of the sensor(s), for example by means of a control unit. The tilting of the vehicle during cornering may thus be simulated. The measuring of such a parameter and the adjusting of the tilt may be conducted remotely from the testing platform. The sensor(s), control unit and actuator assembly may be self-contained within the target vehicle. A method of modeling a VRU (Vulnerable Road User) for ADAS testing is also provided.

A motion simulator for imposing loads on an occupant, the simulator having: a movable carrier for supporting the occupant; a first drive mechanism for moving the carrier; multiple loading elements configured for attachment to the occupant when the occupant is supported by the carrier; a second drive mechanism for actuating the loading elements to apply loads to the occupant; and a controller, the controller being configured to implement a simulation of a motion event by: (i) estimating a motion of the carrier consistent with the motion event and controlling the first drive mechanism to cause the carrier to adopt the estimated motion; (ii) estimating a first load on the occupant consistent with the motion event; (iii) estimating a second load on the occupant due to the motion adopted by the carrier and (iv) controlling the second drive mechanism to cause the second drive mechanism to apply to the occupant a load that is the difference between the first estimated load and the second estimated load.