A water rollover simulation system includes a simulation training device. The simulation training device is connected to a track, wherein one end of the track is submerged in water. The simulation training device begins a simulation on another portion of the track not submerged in water, moves toward the end of the track, and completes the simulation by allowing one or more trainees to escape the simulation training device while the simulation training device is submerged under water. The water rollover simulation system includes various safety features. The safety features can be activated automatically after a predetermined amount of time, or manually via a remote control system.

A water rollover simulation system includes a simulation training device. The simulation training device is connected to a track, wherein one end of the track is submerged in water. The simulation training device begins a simulation on another portion of the track not submerged in water, moves toward the end of the track, and completes the simulation by allowing one or more trainees to escape the simulation training device while the simulation training device is submerged under water. The water rollover simulation system includes various safety features. The safety features can be activated automatically after a predetermined amount of time, or manually via a remote control system.

A system may include a housing that may hold a body of water, an inflatable assembly disposed within the body of water, and a processor. The processor may receive an indication related to a speed of a flow of the body of water and send a signal to at least one valve coupled between the inflatable assembly and a fluid source in response to the indication. The signal may cause the at least one valve to fluidly couple the inflatable assembly to the fluid source to cause the inflatable assembly to expand to an inflated configuration.

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 method for determining an attenuation of a wind caused by a simulated obstacle and experienced by a simulated vehicle in a simulation, comprising: receiving a wind direction and an initial speed for a simulated wind; generating a line of sight vector having a source position, a given direction and a given length, the given direction being one of opposite to the wind direction and identical to the wind direction; determining a distance between the simulated obstacle and the simulated vehicle using the line of sight vector, the distance being at most equal to the given length of the line of sight vector; determining a wind attenuation gain using the distance between the simulated obstacle and the simulated vehicle; determining an actual speed for the simulated wind using the initial speed of the simulated wind and the gain for the wind attenuation; and outputting the actual speed.

The present invention relates to an experience apparatus including: an avatar configured to move in a first space; and a simulator configured to provide stimuli an experiencing person in a second space and enable the experiencing person to undergo experience as being aboard the avatar. Therefore, reality may be improved and the experiencing person may undergo various situations with relatively lesser time and costs.

A profile comparator for comparing between a human operator and a clone including a storage device, a simulation processor and a parameter comparator, the storage device including a recording of at least one parameter during an activity session of a platform, the platform including at least one control system, the parameter being at least one of a parameter of the platform and an action of an operator of the platform during the activity session, and a predetermined profile, the simulation processor configured to generate a virtual clone of the platform according to at least one of the recorded parameter, the simulation processor being further configured to manage the virtual clone according to the predetermined profile, the parameter comparator configured to compare at least one comparison parameter relative to the comparison parameter of the virtual clone and configured to determine at least one deviation wherein the comparison parameter deviates from the comparison parameter of the virtual clone.

A profile comparator for comparing between a human operator and a clone including a storage device, a simulation processor and a parameter comparator, the storage device including a recording of at least one parameter during an activity session of a platform, the platform including at least one control system, the parameter being at least one of a parameter of the platform and an action of an operator of the platform during the activity session, and a predetermined profile, the simulation processor configured to generate a virtual clone of the platform according to at least one of the recorded parameter, the simulation processor being further configured to manage the virtual clone according to the predetermined profile, the parameter comparator configured to compare at least one comparison parameter relative to the comparison parameter of the virtual clone and configured to determine at least one deviation wherein the comparison parameter deviates from the comparison parameter of the virtual clone.

A system may include a housing that may hold a body of water, an inflatable assembly disposed within the body of water, and a processor. The processor may receive an indication related to a speed of a flow of the body of water and send a signal to at least one valve coupled between the inflatable assembly and a fluid source in response to the indication. The signal may cause the at least one valve to fluidly couple the inflatable assembly to the fluid source to cause the inflatable assembly to expand to an inflated configuration.

A system may include a virtual reality system configured to present one or more virtual objects via an electronic display. The system may also include one or more inflatable objects that correspond to the one or more virtual objects, such that the one or more inflatable objects matches one or more shapes of the one or more virtual objects. The system may also include a processor configured to cause at least one of the one or more inflatable objects to inflate based on feedback from the virtual reality system.