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.

A ride system includes at least one ride vehicle. The at least one ride vehicle is configured to receive a ride passenger. The ride system includes electronic goggles configured to be worn by the ride passenger. The electronic goggles include a camera and a display. The ride system includes a computer graphics generation system communicatively coupled to the electronic goggles, and configured to generate streaming media of a real world environment based on image data captured via the camera of the electronic goggles, generate one or more virtual augmentations superimposed on the streaming media of the real world environment, and to transmit the streaming media of the real world environment along with the one or more superimposed virtual augmentations to be displayed on the display of the electronic goggles.

A ride system includes at least one ride vehicle. The at least one ride vehicle is configured to receive a ride passenger. The ride system includes electronic goggles configured to be worn by the ride passenger. The electronic goggles include a camera and a display. The ride system includes a computer graphics generation system communicatively coupled to the electronic goggles, and configured to generate streaming media of a real world environment based on image data captured via the camera of the electronic goggles, generate one or more virtual augmentations superimposed on the streaming media of the real world environment, and to transmit the streaming media of the real world environment along with the one or more superimposed virtual augmentations to be displayed on the display of the electronic goggles.

A play structure having one or more monolith structures for the connection of other surfaces (e.g., deckings, water-based elements, interactive elements, etc.). Each of the monolith structures may be adjustably connected with a ground surface such that a variety of possible angles may be obtained by the monolith whit respect to the ground surface. After the desired orientation of the monolith is obtained to the ground surface via the adjustable connection, the monolith may be secured in such position. Water or fluid may be provided to the monolith structures via piping that interfaces with the monolith structures by a fluid connection that is in communication with piping disposed within the monolith structures. A fluid damping or delivery system (e.g., based upon a tipping element that provides water to a fluid flowing surface and/or other water diversion element) may be provided as part of be play structure.

A hotel or motel room incorporates special effects in accordance with a particular theme (e.g., haunted room). A control room provides a concealed area for personnel and/or automated systems to trigger the special effects which may include, but are limited to shaking, rattling, rumbling, pepper ghosts, water fixtures being activated, thunder and lightning, swapping tiles with digital graphics, turning on a TV, clock or light, etc. Heat sensors, weight sensors, floor mats and/or other sensors determine positions of guests in the hotel and hotel rooms thereby allowing the automatic or manual triggering of the special effects.

A roller coaster track may comprise a laminate and a metal bearing layer. A method of manufacturing a roller coaster track may comprise manufacturing a laminate, manufacturing a metal bearing layer, and assembling the laminate and bearing layer. The bearing layer may be at least partially filled with grout. A method of repairing a wood roller coaster track may comprise removing a layer of laminate, and replacing the layer with a metal bearing layer.

A swingset has a swingset frame. A horizontal member has a first horizontal section, and a second horizontal section. The first horizontal section has a swaged connection to the second horizontal section. The first horizontal section and the second horizontal section are formed of tube metal. A first horizontal section swaged portion fits within the second horizontal section. A pair of first legs support the first horizontal section, and a pair of second legs support the second horizontal section. The pair of first legs engage to a pair of first leg sockets formed on the first horizontal section. The pair of second legs engage to second leg sockets formed on the second horizontal section. A swing is suspended from the horizontal member. A lower tension bracket is mounted on a lower wall of the first horizontal section.

An escape chute, including: an upper straight chute, a lower straight chute, a turning chute, a first rotating axle, and a second rotating axle. The turning chute includes a front section, a middle section, and a rear section. The upper straight chute and the lower straight chute are connected via the turning chute. Each chute includes: a chute base; a guard rail including a top and a bottom; and a handrail. The chute base of the upper straight chute and the chute base of the lower straight chute are connected through the chute bases of the front, the middle, and the rear sections of the turning chute. Each hinge joint between the chute bases of the corresponding chutes is provided with a hinge roller. Each butt joint is provided with a combined pulley.

An escape chute, including: an upper straight chute, a lower straight chute, a turning chute, a first rotating axle, and a second rotating axle. The turning chute includes a front section, a middle section, and a rear section. The upper straight chute and the lower straight chute are connected via the turning chute. Each chute includes: a chute base; a guard rail including a top and a bottom; and a handrail. The chute base of the upper straight chute and the chute base of the lower straight chute are connected through the chute bases of the front, the middle, and the rear sections of the turning chute. Each hinge joint between the chute bases of the corresponding chutes is provided with a hinge roller. Each butt joint is provided with a combined pulley.

The mobile sheet flow water ride apparatus of the present invention utilizes a rigid inclined structure. Ride surfaces, aisle surfaces, and surround fences are covered with protective inflatable air cushions. The ride apparatus of the present invention has non-retractable transport wheels and uses a multitude of adjustable jacks to take the load off the transport wheels and support the ride apparatus. The ride apparatus utilizes a 15,000 gpm double-suction pump driven by a 460-horsepower diesel engine that is transported in its own trailer. Water is pumped from a main storage tank through a horizontally-oriented nozzle that 2.438 meters wide and 6.35 cm high at supercritical speed. The water rushes up the slope, over a berm at the top of the slope, and back into the main storage tank through a square main return grate.