An attraction system includes a sensor configured to emit an output signal toward a guest area and receive a reflected signal from the guest area and a control system communicatively coupled to the sensor. The control system is configured to receive data from the sensor, in which the data is indicative of a distance of signal travel based on the output signal and the reflected signal. The control system is also configured to compare the distance of signal travel with an unoccupied distance value corresponding to a distance between the sensor and the guest area being unoccupied, and determine whether the guest area is occupied based on comparing a difference between the distance of signal travel and the unoccupied distance value with a threshold.

An attraction system includes a sensor configured to emit an output signal toward a guest area and receive a reflected signal from the guest area and a control system communicatively coupled to the sensor. The control system is configured to receive data from the sensor, in which the data is indicative of a distance of signal travel based on the output signal and the reflected signal. The control system is also configured to compare the distance of signal travel with an unoccupied distance value corresponding to a distance between the sensor and the guest area being unoccupied, and determine whether the guest area is occupied based on comparing a difference between the distance of signal travel and the unoccupied distance value with a threshold.

There is provided an all-terrain amusement ride vehicle and control system. Specifically, there is provided and autonomous all-terrain amusement ride vehicle and control system therefore which is configured to use real terrain to create guest sensations. Whether indoors or outdoors, real terrain such as hills, bridges, bumpy roads, and stairs can be used to create sensations that have sustained gravitational forces (G-forces) wherein these G-forces are at least in part based on the terrain. By providing autonomous features and an overall fleet control system, guests can experience a safe operator-initiated ride but with a feeling of being in an unconstrained environment.

There is provided an all-terrain amusement ride vehicle and control system. Specifically, there is provided and autonomous all-terrain amusement ride vehicle and control system therefore which is configured to use real terrain to create guest sensations. Whether indoors or outdoors, real terrain such as hills, bridges, bumpy roads, and stairs can be used to create sensations that have sustained gravitational forces (G-forces) wherein these G-forces are at least in part based on the terrain. By providing autonomous features and an overall fleet control system, guests can experience a safe operator-initiated ride but with a feeling of being in an unconstrained environment.

A system for use in a park attraction to provide collaborative driving experiences. The system includes a vehicle including a body with passenger seats, including a user input assembly proximate to each of the passenger seats, and further including a holonomic drive system adapted to move the body in any direction while riding on a driving surface of the park attraction. The system also includes a system controller (running an attraction/game control module) that operates to: (a) receive user input from each of the user input assemblies; (b) process the user input from each of the user input assemblies to generate a control vector associated with each of the user input assemblies; (c) combine the control vectors from all of the user input assemblies to generate a resultant vector; (d) generate a drive control signal from the resultant vector; and (e) transmit the drive control signal to the vehicle.

A system for use in a park attraction to provide collaborative driving experiences. The system includes a vehicle including a body with passenger seats, including a user input assembly proximate to each of the passenger seats, and further including a holonomic drive system adapted to move the body in any direction while riding on a driving surface of the park attraction. The system also includes a system controller (running an attraction/game control module) that operates to: (a) receive user input from each of the user input assemblies; (b) process the user input from each of the user input assemblies to generate a control vector associated with each of the user input assemblies; (c) combine the control vectors from all of the user input assemblies to generate a resultant vector; (d) generate a drive control signal from the resultant vector; and (e) transmit the drive control signal to the vehicle.

An amusement park system in accordance with present embodiments includes multiple separated park areas, an autonomous vehicle configured to drive along ground surfaces within the multiple separated park areas, and a gondola system configured to transport the autonomous vehicle between the multiple separated park areas. The amusement park system further includes a control system configured to operate the autonomous vehicle to engage with and disengage from the gondola system to facilitate transport of the autonomous vehicle by the gondola system.

Drifting karts in accordance with embodiments of the invention are described that include a front wheel drive train and rear caster wheels that can be dynamically engaged to induce and control drift during a turn. One embodiment of the invention includes a chassis to which a steering column is mounted, where the steering column includes at least one front steerable wheel configured to be driven by an electric motor, a battery housing mounted to the chassis, where the battery housing contains a controller and at least one battery, wiring configured to provide power from the at least one battery to the electric motor, two caster wheels mounted to the chassis, where each caster wheel is configured to rotate around a rotational axis and swivel around a swivel axis, and a hand lever configured to dynamically engage the caster wheels to induce and control drift during a turn.

Drifting karts in accordance with embodiments of the invention are described that include a front wheel drive train and rear caster wheels that can be dynamically engaged to induce and control drift during a turn. One embodiment of the invention includes a chassis to which a steering column is mounted, where the steering column includes at least one front steerable wheel configured to be driven by an electric motor, a battery housing mounted to the chassis, where the battery housing contains a controller and at least one battery, wiring configured to provide power from the at least one battery to the electric motor, two caster wheels mounted to the chassis, where each caster wheel is configured to rotate around a rotational axis and swivel around a swivel axis, and a hand lever configured to dynamically engage the caster wheels to induce and control drift during a turn.

There is provided an all-terrain amusement ride vehicle and control system. Specifically, there is provided and autonomous all-terrain amusement ride vehicle and control system therefore which is configured to use real terrain to create guest sensations. Whether indoors or outdoors, real terrain such as hills, bridges, bumpy roads, and stairs can be used to create sensations that have sustained gravitational forces (G-forces) wherein these G-forces are at least in part based on the terrain. By providing autonomous features and an overall fleet control system, guests can experience a safe operator-initiated ride but with a feeling of being in an unconstrained environment.