A connector system, ride system and method for connecting and supporting a suspended load. The system includes a suspended carrier having a first connector part and a suspended load support, arranged and disposed to support a suspended load, the suspended load support having a second connector part. A first magnetic coupler is affixed to the suspended carrier and a second magnetic coupler is affixed to the suspended load support. The first magnetic coupler includes a first arrangement of magnets and the second magnetic coupler includes a second arrangement of magnets. The first arrangement of magnets is selectively arranged and disposed to provide alignment and detachable engagement to the magnets of the second arrangement of magnets. The first connector part and the second connector part releasably engage to connect the suspended carrier to the suspended load support and permit transmission of motion, power, signal and at least one utility from the suspended carrier to the suspended load support.

A connector system, ride system and method for connecting and supporting a suspended load. The system includes a suspended carrier having a first connector part and a suspended load support, arranged and disposed to support a suspended load, the suspended load support having a second connector part. A first magnetic coupler is affixed to the suspended carrier and a second magnetic coupler is affixed to the suspended load support. The first magnetic coupler includes a first arrangement of magnets and the second magnetic coupler includes a second arrangement of magnets. The first arrangement of magnets is selectively arranged and disposed to provide alignment and detachable engagement to the magnets of the second arrangement of magnets. The first connector part and the second connector part releasably engage to connect the suspended carrier to the suspended load support and permit transmission of motion, power, signal and at least one utility from the suspended carrier to the suspended load support.

Techniques for improving ride experience provided by a virtual reality ride system, which includes an electronic display that presents virtual reality image content to a rider of a ride vehicle, sensors that measure sensor data indicative of movement characteristics of the ride vehicle, and virtual reality processing circuitry. The virtual reality processing circuitry determines a predicted movement profile of the ride vehicle based on the sensor data, in which the predicted movement profile indicates that the ride vehicle is expected to move a predicted movement magnitude during a predicted movement duration, determines a target perceived movement magnitude greater than the predicted movement magnitude by applying a movement-exaggeration factor to the predicted movement magnitude, and determines movement-exaggerated virtual reality image content to be presented on the electronic display at least in part by adapting default virtual reality image content to incorporate the target perceived movement magnitude.

Techniques for improving ride experience provided by a virtual reality ride system, which includes an electronic display that presents virtual reality image content to a rider of a ride vehicle, sensors that measure sensor data indicative of movement characteristics of the ride vehicle, and virtual reality processing circuitry. The virtual reality processing circuitry determines a predicted movement profile of the ride vehicle based on the sensor data, in which the predicted movement profile indicates that the ride vehicle is expected to move a predicted movement magnitude during a predicted movement duration, determines a target perceived movement magnitude greater than the predicted movement magnitude by applying a movement-exaggeration factor to the predicted movement magnitude, and determines movement-exaggerated virtual reality image content to be presented on the electronic display at least in part by adapting default virtual reality image content to incorporate the target perceived movement magnitude.

A linear actuator comprises a motor for producing a bi-directional rotational output. A casing is connected to the motor at a proximal end, the casing having an inner cavity defining a joint surface. A shaft is within the inner cavity of the casing and actuated by the motor for rotation. A sliding tube is at least partially in the inner cavity of the casing for moving in translation in an axial direction relative to the casing. One or more travelling nut is connected to the sliding tube assembly for moving with the sliding tube in the axial direction, the travelling nut being operatively engaged to the shaft for converting a rotational motion of the shaft into a translation of the sliding tube. A liner is between the sliding tube and the joint surface of the inner cavity, an inner surface of the liner defining longitudinal contact surfaces separated by longitudinal grooves, the longitudinal contact surfaces contacting the sliding tube.

A linear actuator comprises a motor for producing a bi-directional rotational output. A casing is connected to the motor at a proximal end, the casing having an inner cavity defining a joint surface. A shaft is within the inner cavity of the casing and actuated by the motor for rotation. A sliding tube is at least partially in the inner cavity of the casing for moving in translation in an axial direction relative to the casing. One or more travelling nut is connected to the sliding tube assembly for moving with the sliding tube in the axial direction, the travelling nut being operatively engaged to the shaft for converting a rotational motion of the shaft into a translation of the sliding tube. A liner is between the sliding tube and the joint surface of the inner cavity, an inner surface of the liner defining longitudinal contact surfaces separated by longitudinal grooves, the longitudinal contact surfaces contacting the sliding tube.

A ride system includes ride vehicles. Each ride vehicle includes a rider support configured to carry a rider, a support actuator coupled to the rider support and a base of the ride vehicle and configured to move the rider support relative to the base, and a ride vehicle movement system integrated with the base and configured to move the ride vehicle relative to a ride area. The ride system also includes a controller configured to control the support actuator and the ride vehicle movement system of each ride vehicle individually based on a choreographed routine and an input received from a selected ride vehicle. The input is indicative of an adjustment to the support actuator, the ride vehicle movement system, or both, of each ride vehicle. The input is based on a correlative adjustment to the support actuator, the ride vehicle movement system, or both, of the selected ride vehicle.

A ride system includes ride vehicles. Each ride vehicle includes a rider support configured to carry a rider, a support actuator coupled to the rider support and a base of the ride vehicle and configured to move the rider support relative to the base, and a ride vehicle movement system integrated with the base and configured to move the ride vehicle relative to a ride area. The ride system also includes a controller configured to control the support actuator and the ride vehicle movement system of each ride vehicle individually based on a choreographed routine and an input received from a selected ride vehicle. The input is indicative of an adjustment to the support actuator, the ride vehicle movement system, or both, of each ride vehicle. The input is based on a correlative adjustment to the support actuator, the ride vehicle movement system, or both, of the selected ride vehicle.

A boat motion simulator or system configured specially to impart boat-type motions (e.g., roll, sway, heave, pitch, surge, and yaw) to a passenger boat. The simulator or system is also configured to use buoyancy or buoyant forces to vertically support the boat such that the system's components imparting the boat motions do not provide vertical support of the boat, which, instead, floats naturally in a volume of water provided within the simulator or system while or concurrently with motions being imparted upon the boat by a drive or motion assembly. The simulator or system may also include a display and sound system operable with this drive or motion assembly to display imagery and a soundtrack that are synchronized with the motions imparted upon the boat by the drive or motion assembly to provide a unique and realistic boat simulator or boat ride experience for passengers in the boat.

A boat motion simulator or system configured specially to impart boat-type motions (e.g., roll, sway, heave, pitch, surge, and yaw) to a passenger boat. The simulator or system is also configured to use buoyancy or buoyant forces to vertically support the boat such that the system's components imparting the boat motions do not provide vertical support of the boat, which, instead, floats naturally in a volume of water provided within the simulator or system while or concurrently with motions being imparted upon the boat by a drive or motion assembly. The simulator or system may also include a display and sound system operable with this drive or motion assembly to display imagery and a soundtrack that are synchronized with the motions imparted upon the boat by the drive or motion assembly to provide a unique and realistic boat simulator or boat ride experience for passengers in the boat.