The present disclosure provides hydraulic power sources for watercraft. Example power sources can include: a watercraft having an engine; a variable ratio drive assembly operably engaged with the engine; a hydraulic pump operably engaged with the variable ratio drive assembly; and a hydraulic motor powered by the hydraulic pump. The present disclosure also provides methods for providing hydraulic power aboard a watercraft. Example methods can include: using an engine of the watercraft to drive a variable ratio drive assembly; using the variable ratio drive assembly to drive a hydraulic pump; using the hydraulic pump to power a hydraulic motor; and using the hydraulic motor to drive a load.

Wakeboat hull control systems and methods are provided to monitor the orientation of the wakeboat hull in the surrounding water, and to automatically control wakeboat ballast components to achieve or maintain desired hull orientations. Systems and methods are provided to measure, store, and recall hull orientation. Systems and methods are also provided to enable automated action to improve the safety, automation, performance, convenience, and marketing advantage of wakeboat ballast systems.

Wakeboat hull control systems and methods are provided to monitor the orientation of the wakeboat hull in the surrounding water, and to automatically control wakeboat ballast components to achieve or maintain desired hull orientations. Systems and methods are provided to measure, store, and recall hull orientation. Systems and methods are also provided to enable automated action to improve the safety, automation, performance, convenience, and marketing advantage of wakeboat ballast systems.

Wakeboat hull control systems and methods are provided to monitor the orientation of the wakeboat hull in the surrounding water, and to automatically control wakeboat ballast components to achieve or maintain desired hull orientations. Systems and methods are provided to measure, store, and recall hull orientation. Systems and methods are also provided to enable automated action to improve the safety, automation, performance, convenience, and marketing advantage of wakeboat ballast systems.

Wakeboat hull control systems and methods are provided to monitor the orientation of the wakeboat hull in the surrounding water, and to automatically control wakeboat ballast components to achieve or maintain desired hull orientations. Systems and methods are provided to measure, store, and recall hull orientation. Systems and methods are also provided to enable automated action to improve the safety, automation, performance, convenience, and marketing advantage of wakeboat ballast systems.

The present disclosure provides hydraulic power sources for wakeboats are provided. The power sources can include: a wakeboat having a hull and an engine; a hydraulic pump mechanically driven by the engine; and a hydraulic motor powered by the hydraulic pump. The power sources may also include a load powered by the hydraulic motor. The present disclosure also provides methods for hydraulically powering a load from aboard a wakeboat are also provided. The methods can include: comprising: mechanically driving a hydraulic pump with an engine of the wakeboat; using the hydraulic pump to power a hydraulic motor; and using the hydraulic motor to drive a load.

The present disclosure provides hydraulic power sources for wakeboats are provided. The power sources can include: a wakeboat having a hull and an engine; a hydraulic pump mechanically driven by the engine; and a hydraulic motor powered by the hydraulic pump. The power sources may also include a load powered by the hydraulic motor. The present disclosure also provides methods for hydraulically powering a load from aboard a wakeboat are also provided. The methods can include: comprising: mechanically driving a hydraulic pump with an engine of the wakeboat; using the hydraulic pump to power a hydraulic motor; and using the hydraulic motor to drive a load.

Wakeboat hull control systems are provided that can include a first accelerometer operatively associated with the hull of the wakeboat to measure the acceleration of the hull along a first axis; a second accelerometer operatively associated with the hull of the wakeboat to measure the acceleration of the hull along a second axis, the first axis being non-parallel to the second axis; and processing circuitry calculating the rotation of the hull of the wakeboat about a third axis based on the acquired measurements. Wakeboat hull control methods are provided that can include using the processing circuitry to calculate the rotation of the hull of the wakeboat about a third axis based on the acquired measurements.

Wakeboat hull control systems are provided that can include a first accelerometer operatively associated with the hull of the wakeboat to measure the acceleration of the hull along a first axis; a second accelerometer operatively associated with the hull of the wakeboat to measure the acceleration of the hull along a second axis, the first axis being non-parallel to the second axis; and processing circuitry calculating the rotation of the hull of the wakeboat about a third axis based on the acquired measurements. Wakeboat hull control methods are provided that can include using the processing circuitry to calculate the rotation of the hull of the wakeboat about a third axis based on the acquired measurements.

The invention relates to a semisubmersible float, in particular for an offshore wind turbine, comprising at least four columns, including a central column and three outer columns connected to the central column by arms in the form of a pontoon, the outer columns and the pontoon arms comprising ballasts, is characterized in that the ballasts are filled by gravity and emptied using compressed air.