An air amplifier utilizes a high-pressure input stream of air to accelerate a low-velocity input stream of air to provide a high-velocity, high-volume output stream of air. A coupled air amplifier array includes multiple air amplifiers which couple their respective output streams of air to one another to form a single collective output stream of air. Multiple coupled air amplifier arrays can be utilized to form coupled air amplifier array systems to provide multiple collective output streams of air which can be focused toward to an audience within a venue. The coupled air amplifier array system can be implemented within atmospheric effects systems to provide atmospheric effects, such as wind, scent, and/or temperature to provide some examples, relating to an event. These atmospheric effects systems can present these atmospheric effects to the audience to enhance the immersion of the audience as they are viewing the event. These atmospheric effects systems can include multiple portable mobile effects pods that are situated within different locations within the venue to present these atmospheric effects to different locations with the venue.

Systems and method for generating a vanishing illusion special effect are provided. One approach involves two rooms that mirror each other and are separated by a wall. The wall includes a frame through which the transition glass is configured to move. The transition glass includes a mirrored portion and a transparent portion. A controller may instruct an actuator to move the transition glass such that the mirrored portion is in alignment or out of alignment relative to the frame. In a further embodiment, a first ride vehicle and a second ride vehicle mirror each other and are separated by a transition glass that also includes a mirrored portion and a transparent portion. A controller may regulate the movement of the first ride vehicle and the second ride vehicle from a position in alignment to a position out of alignment relative to the mirrored portion or the transparent portion.

An attraction system includes at least one detector, the attraction apparatus, and a controller. The at least one detector detects blood flow information of a user, the attraction apparatus provides at least one stimulus to the user, and the controller is connected to the at least one detector and the attraction apparatus to control the attraction apparatus based on the blood flow information. A control method for the attraction apparatus is executed by the controller and includes: obtaining, from the at least one detector, an amount of change in the blood information before and after the at least one stimulus is provided to the user; and controlling an operation of the attraction apparatus, based on a result of comparison of the amount of change with a threshold.

An aerial navigation system comprises four anchor points mounted on top of four upright members respectively at substantially same height from a ground, a carrier device coupled to a first set of four electric motors mounted at the four anchor points through a set of first wires. The set of first wires, the four upright members and the ground effectively define a volume. The carrier device is moveable in a bounded horizontal plane defined by the four anchor points. A robotic device is suspended from the carrier device using a second wire and moves vertically relative to the carrier device through activation of a fifth electric motor. A control unit is coupled to the first set of four electric motors and the fifth electric motor for controlling the three-dimensional movement of the robotic device to permit navigation from a current location to a target location inside the defined volume.

A navigation control system for an aerial robotic device suspended from a carrier device in an aerial movement volume of an aerial module. The navigation control system is configured to detect one or more stationary obstacles located in corresponding Aerial Movement Volume, create a 3D map representing the Aerial Movement Volume together with one or more bounding boxes enclosing each stationary obstacle in the Aerial Movement Volume, use an optimisation algorithm to compute an optimal route for the aerial robotic device, determine control parameters for a plurality of electric stepper motors driving the carrier device and the aerial robotic device based on the computed optimal route for the aerial robotic device, and navigate the aerial robotic device in accordance with the computed optimal route to enable the aerial robotic device to reach the required destination while avoiding intervening stationary obstacles.

The invention relates to an immersive device (1) comprising a screen (2) and at least two multisensory cases (4), each case comprising at least one device (32) for generating an air flow and a sound-generating device (34), as well as a control device designed to manage the emission of sound and air by independently controlling each case.

A multi-platform vibro-kinetic system comprises a plurality of motion platforms each having actuators to be displaceable to produce vibro-kinetic effects. The system may obtain movements of one or more operator(s), interpret the movements of the operator and identifying from the movements an operator instruction for effect generation, and output a motion signal containing instructions for producing a vibro-kinetic effect on at least one of the motion platforms as a response to the operator instruction.

A multi-platform vibro-kinetic system comprises a plurality of motion platforms each having actuators to be displaceable to produce vibro-kinetic effects. The system may obtain movements of one or more operator(s), interpret the movements of the operator and identifying from the movements an operator instruction for effect generation, and output a motion signal containing instructions for producing a vibro-kinetic effect on at least one of the motion platforms as a response to the operator instruction.

A resistance control system of an amusement attraction includes a support assembly having a base, a pivot joint, and a support beam extending between the base and the pivot joint. The resistance control system includes a spring plate coupled to the pivot joint of the support assembly, and includes at least one spring engaged with the spring plate. Additionally, the resistance control system includes an actuator plate positioned between the spring plate and the base of the support assembly, as well as at least one actuator coupled between the actuator plate and the base. The at least one actuator is configured to move and secure the actuator plate relative to the pivot joint to adjust a resistance to movement about the pivot joint.

A resistance control system of an amusement attraction includes a support assembly having a base, a pivot joint, and a support beam extending between the base and the pivot joint. The resistance control system includes a spring plate coupled to the pivot joint of the support assembly, and includes at least one spring engaged with the spring plate. Additionally, the resistance control system includes an actuator plate positioned between the spring plate and the base of the support assembly, as well as at least one actuator coupled between the actuator plate and the base. The at least one actuator is configured to move and secure the actuator plate relative to the pivot joint to adjust a resistance to movement about the pivot joint.