A variable vehicle ride switch in accordance with present embodiments includes a base configured to rotate with respect to a ride surface. The variable vehicle ride switch also includes a conveyor positioned on the base that can actuate relative to the base to move a ride vehicle towards or away from an outer edge of the base and to change an angle or orientation of the at least one conveyor within the base, e.g., to rotate within the base. The variable vehicle ride switch also includes a controller configured to receive an activation signal to cause the base to rotate and to actuate the conveyor.

A motion simulator ride assembly including a motion base and a rider support assembly positioned beneath and coupled to the motion base. The rider support assembly includes a plurality of rider support units each including a saddle having a leading end, a tail end, and a superior surface that may support a rider in a facedown position and a restraint system that may secure the rider onto the rider support. The restraint system includes a rotating restraint having an attachment point on the saddle, and the rotating restraint may move relative to the superior surface to move the rotating restraint from an unrestrained configuration to a restrained configuration, and the rotating restraint may abut against a posterior surface of a torso of the rider when the rotating restraint is in the restrained configuration. The motion simulator ride assembly also includes a display screen that may project a simulated environment. The display screen is positioned below the motion base.

A simulator ride may include an annular structure forming at least a partial annulus on which a path is implemented. Additionally, the simulator ride may include a headset with a display designed to be worn by a passenger. A passenger support system may be coupled to the path of the annular structure and designed to move along the path and rotate about a center axis of the annular structure when in operation. Additionally, the annular structure may be configured to be articulated in one or more degrees of freedom.

A motion simulator ride assembly includes a motion base and a rider support assembly positioned beneath and coupled to the motion base. The rider support assembly includes a plurality of rider support units, each rider support unit of the one or more rider support units having an inversion table having a surface that may abut a rider. The inversion table may rotate about an axis to transition between a loading configuration and a ride configuration and the ride configuration positions the rider in a substantially facedown position. Each rider support unit also includes a restraint system that may secure the rider onto the inversion table. The restraint system includes a first moveable restraint and a second moveable restraint that are each coupled to the inversion table and the first and second moveable restraints may move relative to the surface to move the first and second movable restraints from an unrestrained configuration to a restrained configuration. The motion simulator ride assembly also includes a display screen that may project a simulated environment. The display screen is positioned below the motion base.

Control system for carousels, which comprises a carousel provided with a control unit for detecting operative parameters of the carousel, and with a transmission unit for transmitting a succession of acquired values of the operative parameters. The control system also comprises a portable electronic device provided with a video camera for filming the carousel, and with a communication unit for receiving the acquired values of the operative parameters. The electronic device comprises a processing unit arranged for actuating the video camera to film the carousel and acquire a sequence of photograms. The processing unit synchronizes the acquired values of the operative parameters with the photograms generated by the video camera, and applies to the acquired values an interpolation function, which calculates interpolated values of the operative parameters that are then associated with corresponding photograms.

Control system for carousels, which comprises a carousel provided with a control unit for detecting operative parameters of the carousel, and with a transmission unit for transmitting a succession of acquired values of the operative parameters. The control system also comprises a portable electronic device provided with a video camera for filming the carousel, and with a communication unit for receiving the acquired values of the operative parameters. The electronic device comprises a processing unit arranged for actuating the video camera to film the carousel and acquire a sequence of photograms. The processing unit synchronizes the acquired values of the operative parameters with the photograms generated by the video camera, and applies to the acquired values an interpolation function, which calculates interpolated values of the operative parameters that are then associated with corresponding photograms.

A ride system includes a base, a ride vehicle, a platform assembly positioned between the base and the ride vehicle, and an extension mechanism coupled to the platform assembly and positioned between the base and the ride vehicle. The platform assembly includes a first platform, a second platform, and six legs extending between the first platform and the second platform, and the platform assembly is configured to actuate each of the six legs so as to move the first platform relative to the second platform in different configurations based on which of the six legs is actuated. The extension mechanism is configured to extend and contract so as to move the ride vehicle away from and toward, respectively, the base of the ride system.

A ride system includes a base, a ride vehicle, a platform assembly positioned between the base and the ride vehicle, and an extension mechanism coupled to the platform assembly and positioned between the base and the ride vehicle. The platform assembly includes a first platform, a second platform, and six legs extending between the first platform and the second platform, and the platform assembly is configured to actuate each of the six legs so as to move the first platform relative to the second platform in different configurations based on which of the six legs is actuated. The extension mechanism is configured to extend and contract so as to move the ride vehicle away from and toward, respectively, the base of the ride system.

A device for increasing the safety of amusement rides, in particular carousels, roller coasters or the like, and comprising at least one mechatronic system, characterized in that the mechatronic system comprises means for taking over completely or at least partially the function, in particular the support function, of a mechanic component in the event of a defect thereof and to detect said taking over and to provide an error signal.

There is provided a system for providing interactivity to a guest of an experiential venue, based on sensor measurement of the guest. The system comprises a sensor configured to sense a guest variable of the guest, where the sensor may be a biometric sensor, a facial recognition sensor, a voice stress analysis sensor, a gesture recognition sensor, a motion tracking sensor, or an eye tracking sensor, and may sense heart rate or another guest variable. The system also comprises a control system, which may be implemented as a computer, in communication with the sensor. The control system is configured to determine a guest state from the guest variable, and to modify a venue variable, for example by selecting a path a theme park ride follows. The control system modifies the venue variable according to the guest state to provide increased satisfaction to the guest of the experiential venue.