A theater area includes audience seating that faces outwardly in an “inverted-theater-in-the-round” arrangement towards a ring-shaped performance stage. The performance stage is designed to rotate around the audience area so that each section of the audience can see each part of the stage at different times.

An amusement attraction provides a reactive game experience to a guest. The amusement attraction includes a robot control system having a show robot and a robot controller communicatively coupled to the show robot. The robot controller is configured to instruct the show robot to execute a baseline performance, which is predetermined and stored within the robot controller. The robot controller is configured to receive game input from an input device and instruct the show robot to interrupt the baseline performance by executing a reactive performance comprising a sequence of reactive actions that is responsive to the game input. Additionally, the robot controller is configured to instruct the show robot to execute a connective performance that links an end of the sequence of the reactive actions back to the baseline performance.

An amusement attraction provides a reactive game experience to a guest. The amusement attraction includes a robot control system having a show robot and a robot controller communicatively coupled to the show robot. The robot controller is configured to instruct the show robot to execute a baseline performance, which is predetermined and stored within the robot controller. The robot controller is configured to receive game input from an input device and instruct the show robot to interrupt the baseline performance by executing a reactive performance comprising a sequence of reactive actions that is responsive to the game input. Additionally, the robot controller is configured to instruct the show robot to execute a connective performance that links an end of the sequence of the reactive actions back to the baseline performance.

A ride attraction system includes a tower track and a ride vehicle configured to accommodate one or more riders. The ride vehicle is coupled to and configured to move relative to the tower track and the ride vehicle includes one or more user input devices. The ride attraction system further includes an image system configured to display a ride environment, wherein the user input devices are configured to enable the one or more riders to interact with elements of the ride environment via the one or more user input devices. The ride attraction system further includes a controller communicatively coupled to the ride vehicle and the image system and configured to control movement of the ride vehicle relative to the tower track based on signals from the one or more user input devices.

A ride attraction system includes a tower track and a ride vehicle configured to accommodate one or more riders. The ride vehicle is coupled to and configured to move relative to the tower track and the ride vehicle includes one or more user input devices. The ride attraction system further includes an image system configured to display a ride environment, wherein the user input devices are configured to enable the one or more riders to interact with elements of the ride environment via the one or more user input devices. The ride attraction system further includes a controller communicatively coupled to the ride vehicle and the image system and configured to control movement of the ride vehicle relative to the tower track based on signals from the one or more user input devices.

A motion simulation apparatus includes a motion platform. A carrier for carrying a user is mounted on the motion platform. The apparatus has a drive arm with a lower end that is pivotally mounted on a substrate to pivot relative to the substrate with two degrees of freedom of movement and an upper end that is pivotally connected to the motion platform to pivot with respect to the motion platform with two degrees of freedom of movement. The apparatus has two guide arms, each guide arm having a lower end that is pivotally mounted on the substrate to pivot relative to the substrate with three degrees of freedom of movement and an upper end that is pivotally connected to the motion platform to pivot relative to the motion platform with three degrees of freedom of movement. The drive arm, the guide arms and the motion platform define a dynamic frame that can pivot with respect to the substrate such that a resultant movement of the motion platform can be imparted to the carrier.

A motion simulation apparatus includes a motion platform. A carrier for carrying a user is mounted on the motion platform. The apparatus has a drive arm with a lower end that is pivotally mounted on a substrate to pivot relative to the substrate with two degrees of freedom of movement and an upper end that is pivotally connected to the motion platform to pivot with respect to the motion platform with two degrees of freedom of movement. The apparatus has two guide arms, each guide arm having a lower end that is pivotally mounted on the substrate to pivot relative to the substrate with three degrees of freedom of movement and an upper end that is pivotally connected to the motion platform to pivot relative to the motion platform with three degrees of freedom of movement. The drive arm, the guide arms and the motion platform define a dynamic frame that can pivot with respect to the substrate such that a resultant movement of the motion platform can be imparted to the carrier.

A suspension training based functional fitness element (11, 31) comprising: an essentially planar element (22) having an upper edge, a lower edge and two side edges, said planar element (22) being designed to form a pivotable connection to a support element (32) along said upper edge of the planar element (22), a first elongated element (23, 32, 52) connected to said planar element (22) at a first connection point at said lower edge of the planar element (22), a second elongated element (23, 32, 52) connected to said planar element (22) at a second connection point at said lower edge of the planar element (22), and a first and second handle (24), said first and second handle (24) being connected to said first and second elongated elements (23) respectively, whereby that said first and second connection points are arranged such that there is a horizontal offset between the first and second connection points and such that there is a vertical offset between the first connection point and the pivotable connection and a vertical offset between the second connection point and the pivotable connection.

A suspension training based functional fitness element (11, 31) comprising: an essentially planar element (22) having an upper edge, a lower edge and two side edges, said planar element (22) being designed to form a pivotable connection to a support element (32) along said upper edge of the planar element (22), a first elongated element (23, 32, 52) connected to said planar element (22) at a first connection point at said lower edge of the planar element (22), a second elongated element (23, 32, 52) connected to said planar element (22) at a second connection point at said lower edge of the planar element (22), and a first and second handle (24), said first and second handle (24) being connected to said first and second elongated elements (23) respectively, whereby that said first and second connection points are arranged such that there is a horizontal offset between the first and second connection points and such that there is a vertical offset between the first connection point and the pivotable connection and a vertical offset between the second connection point and the pivotable connection.

A restraint system for a ride vehicle includes a rigid restraint configured to extend across a passenger to secure the passenger within a seat of the ride vehicle and a soft restraint coupled to the rigid restraint. The soft restraint includes a pliable material configured to conform to a substantial portion of a torso of the passenger and a haptic feedback system integrated with the soft restraint. The haptic feedback system is configured to generate vibrational forces and impart the vibrational forces to the torso of the passenger.