Swing-arm pivot piston landing gear systems and methods

The invention claimed is: 1. An aircraft with a landing gear system, comprising: a nose gear disposed proximate a front of the aircraft, the nose gear comprising: a trailing link attached to a wheel of the aircraft; a pivot piston that extends to extend the trailing link about a first point of rotation and retracts to retract the trailing link about a second point of rotation, wherein the first point of rotation and the second point of rotation are vertically aligned; and an upper master link to rotate the trailing link around the second point of rotation to rotate the nose gear between a first position of the landing gear wherein the nose gear is retracted into the aircraft, a second position of the landing gear wherein the trailing link is parallel to a ground, and a third position of the landing gear wherein the trailing link is in an extended position for takeoff; a main gear, hydraulically coupled to the nose gear, the main gear disposed proximate a rear of the aircraft, the main gear controllably movable between the third position of the landing gear, in which the main gear is extended, and a fourth position of the landing gear, in which the main gear is retracted; and a first lever connected to a front hydraulic cylinder of the nose gear and a second lever connected to a rear hydraulic cylinder of the main gear, wherein the first and second levers adjust an equilibrium between the front hydraulic cylinder and the rear hydraulic cylinder, wherein: in a ground position, the nose gear is in the second position of the landing gear, the main gear is in the third position of the landing gear, and a fuselage of the aircraft is level with the ground; and in a pitch angle position, the nose gear is extended in the third position of the landing gear, the main gear is in the fourth position of the landing gear, and the fuselage of the aircraft is rotated to a positive pitch angle with respect to the ground, wherein extending the nose gear further comprises adjusting the equilibrium between the front hydraulic cylinder and the rear hydraulic cylinder as a function of the first lever and the second lever. 2. The aircraft of claim 1 , wherein: the pitch angle position comprises a takeoff pitch angle position; and the landing gear system rotates the fuselage of the aircraft to a predetermined takeoff pitch angle (αTO). 3. The aircraft of claim 1 , wherein: the pitch angle position comprises a landing pitch angle position; and the landing gear system rotates the fuselage of the aircraft to a predetermined landing pitch angle (αL). 4. The aircraft of claim 1 , further comprising: a main cylinder coupled to the main gear; a nose cylinder coupled to the nose gear; and a valve coupled to the main cylinder and the pivot piston, the valve comprising a closed position and an open position; wherein, in the closed position, the valve prevents a flow of a fluid between the pivot piston and the main cylinder; wherein, in the open position, the valve enables the flow of the fluid between the pivot piston and the main cylinder; and wherein a flow of fluid between the nose cylinder and the main cylinder causes the pivot piston to extend and the main cylinder to lower, or vice-versa. 5. The aircraft of claim 4 , wherein: the valve comprises a hydraulic valve; and the fluid comprises hydraulic fluid. 6. The aircraft of claim 4 , wherein: the valve comprises a pneumatic valve; and the fluid comprises one of air or nitrogen. 7. An aircraft with a rotating landing gear system, comprising: a nose gear disposed proximate a front of the aircraft, the nose gear comprising: a trailing link attached to a wheel of the aircraft; a pivot piston that extends to extend the trailing link about a first point of rotation and retracts to retract the trailing link about a second point of rotation, wherein the first point of rotation and the second point of rotation are vertically aligned; and an upper master link to rotate the trailing link around the second point of rotation to rotate the nose gear between a first position of the landing gear wherein the nose gear is retracted into the aircraft, a second position of the landing gear wherein the trailing link is parallel to a ground, and a third position of the landing gear wherein the trailing link is in an extended position for takeoff; two or more main gears disposed proximate a rear of the aircraft; two or more main cylinders, each mechanically coupled to the two or more main gears to move the main gears between the third position of the landing gear, in which the main gears are extended, and a fourth position of the landing gear, in which the main gears are retracted; a first lever connected to a front hydraulic cylinder of the nose gear and a second lever connected to a rear hydraulic cylinder of the two or more main cylinders, wherein the first and second levers adjust an equilibrium between the front hydraulic cylinder and the rear hydraulic cylinder; and a hydraulic valve hydraulically coupling the upper master link, the pivot piston, and the main cylinders to enable fluid to flow between a nose cylinder and the main cylinders to change a pitch angle of the aircraft with respect to the ground. 8. The aircraft of claim 7 , wherein the nose cylinder and the two or more main cylinders are sized and shaped such that, when the hydraulic valve is opened with the aircraft on the ground, the nose cylinder and the two or more main cylinders maintain their relative positions. 9. The aircraft of claim 8 , wherein a total piston surface area of the two or more main cylinders is greater than a total piston surface area of the nose cylinder; and wherein a distance between the nose gear and a center-of-gravity (CG) of the aircraft is greater than a distance between the two or more main gears and the CG. 10. The aircraft of claim 7 , wherein the nose cylinder and the two or more main cylinders are sized and shaped such that, when the hydraulic valve is opened with the aircraft in the air, the nose cylinder retracts and the two or more main cylinders extend. 11. The aircraft of claim 10 , wherein a total weight of the two or more main gears is greater than a total weight of the nose gear. 12. The aircraft of claim 7 , wherein a second movement of the nose gear, caused by a first movement of the two or more main gears, is three times greater than the first movement. 13. A method for mechanically rotating an aircraft to a desired pitch angle during a procedure, the method comprising: determining that the aircraft has reached a predetermined speed; opening a hydraulic valve hydraulically coupled to a nose gear cylinder of a nose gear and a main gear cylinder of a main gear to enable fluid to flow from the nose gear cylinder to the main gear cylinder, or vice versa, to achieve the desired pitch angle; moving a first lever connected to the nose gear cylinder of the nose gear and a second lever connected to the main gear cylinder of the main gear, wherein moving the first and second levers adjusts an equilibrium between the nose gear cylinder and the main gear cylinder, wherein the nose gear comprises: a trailing link attached to wheel of the aircraft; a pivot piston that extends to extend the trailing link about a first point of rotation and retracts to retract the trailing link about a second point of rotation, wherein the first point of rotation and the second point of rotation are vertically aligned; and an upper master link to rotate the trailing link around the second point of rotation to rotate the nose gear between a first position wherein the nose gear is retracted into the aircraft, a second position wher