Gang angle adjustment for a work machine and method thereof

The invention claimed is: 1. An agricultural implement, comprising: a transversely extending frame forming at least a first frame section, a second frame section, and a third frame section, where the first frame section is disposed between the second and third frame sections; a pair of elongated, generally end-to-end gang assemblies on the first frame section, an elongated gang assembly on the second frame section, and an elongated gang assembly on the third frame section, each of the gang assemblies including a plurality of rotatable tillage tools mounted in such a manner that their axes of rotation extend substantially transverse to a path of travel of the respective frame; each of the gang assemblies being horizontally adjustable relative to their respective frame for adjusting the angles between the path of travel of the frame and the axes of rotation of the tools; an actuator for each gang assembly for operably controlling the angular adjustment of the gang assemblies; and a controller disposed in electrical communication with the actuators; wherein, the actuator on the second frame section comprises a master actuator for one of the actuators on the first frame section, and the actuator on the third frame section comprises a master actuator for the other actuator on the first frame section. 2. The implement of claim 1 , wherein each of the actuators is controlled independently of the other actuators. 3. The implement of claim 1 , wherein each actuator comprises a linear electric actuator. 4. The implement of claim 1 , further comprising an electric power source electrically coupled to each actuator for supplying electrical power thereto. 5. The implement of claim 4 , further comprising an alternator disposed in electrical communication with the electric power source. 6. An agricultural implement, comprising: a transversely extending frame forming at least a first frame section, a second frame section, and a third frame section, where the first frame section is disposed between the second and third frame sections; a plurality of elongated, generally end-to-end gang assemblies on the first frame section, the second frame section, and the third frame section, each of the gang assemblies including a plurality of rotatable tillage tools mounted in such a manner that their axes of rotation extend substantially transverse to a travel direction of the implement; a plurality of hydraulic actuators coupled to the first, second and third frame sections, where each hydraulic actuator is configured to operably control the angular adjustment of one of the plurality of gang assemblies relative to the respective frame section; a fluid source for supplying hydraulic fluid to the plurality of hydraulic actuators; a controller; a first master control valve and a second master control valve, the first and second master control valves being fluidly coupled to the fluid source and the plurality of actuators; and a plurality of sensors coupled to the first, second and third frame sections, the plurality of sensors disposed in electrical communication with the controller. 7. The implement of claim 6 , wherein a hydraulic actuator on the second frame section comprises a master hydraulic actuator for one of the hydraulic actuators on the first frame section, and a hydraulic actuator on the third frame section comprises a master hydraulic actuator for a different hydraulic actuator on the first frame section. 8. The implement of claim 6 , wherein: the hydraulic actuator on the second frame section is fluidly coupled to the fluid source when the first master control valve is disposed in an open position; the hydraulic actuator on the third frame section is fluidly coupled to the fluid source when the second master control valve is disposed in an open position. 9. The implement of claim 8 , wherein the first master control valve is operably controlled by the controller independently of the second master control valve. 10. The implement of claim 6 , wherein: a first sensor of the plurality of sensors is coupled to a first actuator on the first frame section; a second sensor of the plurality of sensors is coupled to a second actuator on the first frame section; a third sensor of the plurality of sensors is coupled to an actuator on the second frame section; and a fourth sensor of the plurality of sensors is coupled an actuator on the third frame section. 11. The implement of claim 6 , wherein: the fluid source, the first master control valve, a first actuator on the first frame section, and an actuator on the second frame section are fluidly coupled in series to form a first hydraulic circuit; the fluid source, the second master control valve, a second actuator on the first frame section, and an actuator on the third frame section are fluidly coupled in series to form a second hydraulic circuit; further wherein, the first hydraulic circuit and the second hydraulic circuit are hydraulically parallel to one another. 12. The implement of claim 6 , wherein: the plurality of gang assemblies comprises a first gang assembly and a second gang assembly coupled to the first frame section; the plurality of sensors are configured to detect a position of the first, second, and third frame sections and communicate a position signal to the controller based on the position of each frame section; further wherein, the first master control valve or the second master control valve is operably controlled to its open position by the controller until the first gang assembly and the second gang assembly are angularly adjusted to have approximately the same gang angle relative to the travel direction of the implement. 13. The implement of claim 6 , wherein: each actuator comprises a cylinder and a rod, the rod moving between a retracted position and an extended position within the cylinder; each of the plurality of sensors being coupled to the rod of a corresponding one of the plurality of actuators. 14. The implement of claim 6 , further comprising: a first correction valve fluidly coupled between the fluid source and a first actuator on the first frame section, the first actuator being fluidly coupled in series with an actuator on the second frame section; and a second correction valve fluidly coupled between the fluid source and a second actuator on the second frame section, the second actuator being fluidly coupled in series with an actuator on the third frame section; wherein, the controller is in electrical communication with the first and second correction valves. 15. The implement of claim 14 , wherein: the controller operably actuates the first correction valve to an open position to exhaust hydraulic fluid flowing between the first actuator and the actuator on the second frame section; the controller operably actuates the second correction valve to an open position to exhaust hydraulic fluid flowing between the second actuator and the actuator on the third frame section. 16. The implement of claim 6 , wherein: the plurality of gang assemblies comprises a front pair of elongated, generally end-to-end gang assemblies on the first frame section, a rear pair of elongated, generally end-to-end gang assemblies on the first frame section, a front elongated gang assembly on the second frame section, a rear elongated gang assembly on the second frame section, a front elongated gang assembly on the third frame section, and a rear elongated gang assembly on the third frame section; the plurality of actuators comprises a first actuator for controlling angular adjustment of the rear elongated gang assembl