Automated leveling and depth control system of 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 hitch member configured to couple to a work machine, the hitch member being coupled to at least one of the first, second, and third frame sections; a first actuator coupled to the first frame section, a second actuator coupled to the second frame section, and a third actuator coupled to the third frame section; a first sensor coupled to the first frame section, the first sensor configured to detect a first height of the first frame section from an underlying surface; a second sensor coupled to the second frame section, the second sensor configured to detect a second height of the second frame section from the underlying surface; a third sensor coupled to the third frame section, the third sensor configured to detect a third height of the third frame section from the underlying surface; a control unit disposed in electrical communication with the first sensor, the second sensor, and the third sensor, the controller operably controlling the first actuator, the second actuator and the third actuator; wherein, the control unit compares the first height, the second height, and the third height to one another and determines if each height is equal to or within a threshold limit of one another; further wherein, when one of the first height, second height or third height is determined not to be equal to or within the threshold limit of the other two heights, the controller determines which frame section is uneven with the other two frame sections and actuates the actuator that is coupled to the uneven frame section until the first height, second height, and third height are equal or within the threshold limit of one another. 2. The implement of claim 1 , wherein at least one of the first sensor, second sensor, and third sensor is ultrasonic, radar, optical, or laser. 3. The implement of claim 1 , further comprising: a fluid source for providing hydraulic fluid; a first control valve operably controllable between an open position and a closed position, the first control valve fluidly coupling the fluid source to the first actuator in the open position; a second control valve operably controllable between an open position and a closed position, the second control valve fluidly coupling the fluid source to the second actuator in its open position; a third control valve operably controllable between an open position and a closed position, the third control valve fluidly coupling the fluid source to the third actuator in its open position; and a flow path defined between the fluid source, the first actuator, the second actuator, and the third actuator, the flow path fluidly coupling the first, second and third actuators in parallel with one another. 4. The implement of claim 3 , wherein: the height of the first frame section is controllably adjusted by the first actuator when the first control valve is in its open position and the second and third control valves are in their closed positions; the height of the second frame section is controllably adjusted by the second actuator when the second control valve is in its open position and the first and third control valves are in their closed positions; and the height of the third frame section is controllably adjusted by the third actuator when the third control valve is in its open position and the first and second control valves are in their closed positions. 5. The implement of claim 1 , further comprising a fourth sensor, a fifth sensor, and a sixth sensor, the fourth sensor being coupled to the first frame section, the fifth sensor being coupled to the second frame section, and the sixth sensor being coupled to the third frame section. 6. The implement of claim 5 , wherein: the first sensor is coupled at a front end of the first frame section and the fourth sensor is coupled at a rear end thereof, the first sensor detecting a front height of the first frame section and the fourth sensor detecting a rear height of the first frame section; the second sensor is coupled at a front end of the second frame section and the fifth sensor is coupled at a rear end thereof, the second sensor detecting a front height of the second frame section and the fifth sensor detecting a rear height of the second frame section; and the third sensor is coupled at a front end of the third frame section and the sixth sensor is coupled at a rear end thereof, the third sensor detecting a front height of the third frame section and the sixth sensor detecting a rear height of the third frame section. 7. The implement of claim 6 , further comprising: a linkage pivotably to one of the first, second or third sections of the frame for adjustably controlling a pitch of the frame; and a linkage actuator coupled to the linkage for adjusting a length of the linkage; wherein, if a front height of one of the frame sections is detected not to be equal to or within a threshold limit of the rear height of the respective frame section, the control unit operably actuates the linkage actuator to adjust the length of the linkage until the front height is equal to or within the threshold limit of the rear height. 8. The implement of claim 7 , further comprising a fluid circuit fluidly coupled to a fluid source, the fluid circuit including a control valve disposed in fluid communication with the linkage actuator; wherein, the control valve is operably controlled to actuate the linkage actuator between a retracted position and an extended position. 9. The implement of claim 3 , wherein the fluid flow path further fluidly couples the first actuator and the second actuator in series with one another. 10. The implement of claim 9 , wherein the fluid flow path further fluidly couples the third actuator in series with the first actuator and the second actuator. 11. The implement of claim 9 , wherein the fluid flow path further fluidly couples the third actuator in parallel with the first actuator and the second actuator. 12. The implement of claim 9 , wherein the fluid flow path comprises: a first pressure line fluidly coupling the fluid source with the first actuator via the first control valve when the first control valve is in its open position; a second pressure line fluidly coupling the fluid source with the second actuator via the second control valve when the second control valve is in its open position, wherein the first pressure line and the second pressure line are in parallel with one another; and a third pressure line fluidly coupling the first actuator with the second actuator. 13. The implement of claim 12 , wherein the second pressure line is fluidly coupled with the third pressure line when the second control valve is in its open position. 14. A method of leveling an agricultural implement having a transversely extending frame forming a center frame section, a first frame section disposed on one side of the center frame section, and a second frame section disposed on an opposite side of the center frame section, the method comprising: providing a fluid source, a control unit, one or more actuators coupled to each frame section, a plurality of sensors coupled to each frame section, and a plurality of tools coupled to each frame section; detecting a height of the first frame section relative to an underlying surface with a first sensor of the plurality of sensors, a height of the second frame section relative to the underlying surfac