Dark ride system 1 typically comprises a ride space; a set of wirelessly-controlled and tracklessly-guided passenger vehicle platforms 10 dispatchable within the ride space; a set of wirelessly-controlled and tracklessly-guided themed scenery vehicle platforms dispatchable within the ride space; a load and unload area for passengers disposed proximate the ride space; and a control system. A predetermined set of passengers is allowed to board a predetermined subset of the set of wirelessly-controlled and tracklessly-guided passenger vehicle platforms at the load and unload area and the set of wirelessly-controlled and tracklessly-guided themed scenery vehicle platforms dispatched in an initial spatial arrangement at one or more predetermined times. During a ride show, the control system choreographs and changes a predetermined subset of the set of wirelessly-controlled and tracklessly-guided themed scenery vehicle platforms. At a conclusion of the ride show, the predetermined set of passengers are allowed to exit.

An amusement ride system includes a ride vehicle configured to carry a passenger, one or more sensors configured to detect a face and a body of the passenger while the passenger is in the ride vehicle, and a display assembly configured to be viewable by the passenger while the passenger is in the ride vehicle. The amusement ride system also includes a controller configured to generate an animation based on signals received from the one or more sensors and to instruct display of the animation on the display assembly. The signals are indicative of movement of the face and the body of the passenger, and the animation mimics the movement of the face and the body of the passenger.

A video stream management system includes a video controller that live renders video. Moreover, the video stream management system also includes a display that is communicatively coupled to the video controller and displays a primary video feed that includes the live rendered video. The video controller, the display, or a combination thereof, embeds a pixel pattern in the primary video feed. Additionally, the video feed management system monitors one or more displayed images on the display to identify an error in the primary video feed.

A brake cylinder includes a brake cylinder housing having a master chamber, a slave chamber, and a wall disposed there between. The wall defines at least one opening configured to provide fluid communication between the master chamber and the slave chamber. The brake cylinder also includes a master piston configured to pressurize fluid in the master chamber when a brake pedal is pressed. The brake cylinder further includes a slave piston and a pressure sensor disposed in fluid communication with the slave chamber. The pressure sensor is configured to measure pressure in the slave chamber and send a signal to a processor indicating of movement of the brake pedal. When pressurizing fluid in the master chamber, the master piston is configured to drive fluid from the master chamber to the slave chamber via the at least one opening to increase pressure in the slave chamber.

A method provides a virtual reality experience for at least one passenger of an amusement ride, in particular a water ride, with at least two spaced-apart and stationary UWB antennas. The at least one passenger is able to move in the ride and is provided with VR goggles and a UWB tag. The VR goggles can present the virtual reality experience in the field of vision of the at least one passenger. The method includes the steps: establishing a wireless connection and transmitting at least one signal between the at least two stationary UWB antennas and the UWB tag; calculating the position of the UWB tag based on the at least one received signal; generating a virtual reality according to the calculated position; reproducing the virtual reality experience through the VR goggles according to the calculated position and the viewing direction of the VR goggles.

A method provides a virtual reality experience for at least one passenger of an amusement ride, in particular a water ride, with at least two spaced-apart and stationary UWB antennas. The at least one passenger is able to move in the ride and is provided with VR goggles and a UWB tag. The VR goggles can present the virtual reality experience in the field of vision of the at least one passenger. The method includes the steps: establishing a wireless connection and transmitting at least one signal between the at least two stationary UWB antennas and the UWB tag; calculating the position of the UWB tag based on the at least one received signal; generating a virtual reality according to the calculated position; reproducing the virtual reality experience through the VR goggles according to the calculated position and the viewing direction of the VR goggles.

A modular experiential water tunnel comprises a plurality of arches and experiential modules adapted to be configured and installed onto any conventional water ride. The modular tunnel may further comprise a controller in communication with a server, the controller being adapted to adjust the experience provided by the modular tunnel.

A gaming device for use with an interactive gaming system. The gaming device is carried by a gamer and provides a direct view of a destination part, where the destination is implementing the gaming system. The destination part may emit or reflect light comprising a combination of public images and video perceivable with the naked eye and private images and video only perceivable when looking through the gaming device. The device comprises front and back facing cameras for capturing images transmitted to the gaming system as game information, where the back facing camera is optionally adapted to filter the emitted or reflected light to reveal the private image. Further adaptations allow for the spatially aligned augmentation of the direct view with respect to a destination part. The gaming device is usable as a summoning device including providing movement directions to the gamer with respect to the destination parts.

A gaming device for use with an interactive gaming system. The gaming device is carried by a gamer and provides a direct view of a destination part, where the destination is implementing the gaming system. The destination part may emit or reflect light comprising a combination of public images and video perceivable with the naked eye and private images and video only perceivable when looking through the gaming device. The device comprises front and back facing cameras for capturing images transmitted to the gaming system as game information, where the back facing camera is optionally adapted to filter the emitted or reflected light to reveal the private image. Further adaptations allow for the spatially aligned augmentation of the direct view with respect to a destination part. The gaming device is usable as a summoning device including providing movement directions to the gamer with respect to the destination parts.

The present invention relates to an amusement ride (1), having a frame (10) that can be rotated about a vertical axis (Z), with at least one first seat row arrangement (20) with a linkage (30), at least one row of seats (40), each with at least one seat (41) for a passenger, and a lifting device (50), the at least one row of seats (40) being connected to the linkage (30) via a joint (45), the linkage (30) connecting the joint (45) to the frame (10), and the lifting device (50) being able to lift the row of seats (40) in the orientation of the vertical axis (Z).