Method and system of operating an automotive harvester

What is claimed is: 1. A method of operating an automotive harvester comprising a cutting module comprising a base-cutting set including at least two cutting disks, a conveyance system including a floating roller, and a chopping assembly including at least two billet-cutting blades, the method comprising steps of: measuring a parameter of the base-cutting set; measuring a parameter of the chopping assembly; measuring a position of the floating roller of the conveyance system; comparing the parameter of the base-cutting set and the parameter of the chopping assembly with a first reference value, during a pre-defined time interval; comparing the measured position of the floating roller of the conveyance system with a second reference value, during a pre-defined time interval; managing a propulsion speed of the automotive harvester based on a result of comparing the parameter of the base-cutting set and the parameter of the chopping assembly with the first reference value; and managing a rotation speed of the at least two cutting disks of the base-cutting set and of the at least two billet-cutting blades of the chopping assembly based on the result of comparing the measured position with the second reference value. 2. The method of claim 1 , wherein the parameter of the base-cutting set and the parameter of the chopping assembly comprise exertion parameters. 3. The method of claim 2 , wherein the parameter of the base-cutting set and the parameter of the chopping assembly comprise exertion parameters obtained by reading a hydraulic pressure variation of hydraulic drive mechanisms that drive the at least two cutting disks of the base-cutting set and the at least two billet-cutting blades of the chopping assembly. 4. The method of claim 2 , wherein the parameter of the base-cutting set and the parameter of the chopping assembly comprise exertion parameters obtained by reading a speed variation of the cutting disks of the base-cutting set and of the billet-cutting blades of the chopping assembly. 5. The method of claim 1 , wherein the step of managing the propulsion speed of the automotive harvester comprises at least one of the following sub-steps: reducing the propulsion speed of the automotive harvester; maintaining the propulsion speed of the automotive harvester; or accelerating the propulsion speed of the automotive harvester until nominal cruising speed is resumed. 6. The method of claim 5 , wherein the sub-step of maintaining the propulsion speed of the automotive harvester is performed when the parameter of the base-cutting set or the parameter of the chopping assembly is greater than the first reference value. 7. The method of claim 5 , wherein the sub-step of maintaining the propulsion speed of the automotive harvester is performed when the parameter of the base-cutting set and the parameter of the chopping assembly are equal to or less than the first reference value, and that the automotive harvester is at cruising speed. 8. The method of claim 5 , wherein the sub-step of maintaining the propulsion speed of the automotive harvester is performed when the parameter of the base-cutting set and the parameter of the chopping assembly are equal to or less than the first reference value, and that the automotive harvester is below cruising speed. 9. The method of claim 1 , wherein the step of managing the rotation speed of the at least two cutting disks of the base-cutting set and of the at least two billet-cutting blades of the chopping assembly comprises at least one of the following sub-steps: accelerating the rotation speed of the least two cutting disks of the base-cutting set and of the least two billet-cutting blades of the chopping assembly; maintaining the rotation speed of the least two cutting disks of the base-cutting set and of the least two billet-cutting blades of the chopping assembly; or reducing the rotation speed of the least two cutting disks of the base-cutting set and of the least two billet-cutting blades of the chopping assembly. 10. The method of claim 9 , wherein the sub-step of accelerating the rotation speed of the least two cutting disks of the base-cutting set and of the least two billet-cutting blades of the chopping assembly is performed when the position of the floating roller of the conveyance system is greater than the second reference value. 11. The method claim 9 , wherein the sub-step of maintaining the rotation speed of the least two cutting disks of the base-cutting set and of the least two billet-cutting blades of the chopping assembly is performed when the position of the floating roller of the conveyance system is greater than the second reference value, and that the rotation speed of the at least two cutting disks of the base-cutting set and of the at least two billet-cutting blades of the chopping assembly is equal to a nominal rotation speed. 12. The method claim 9 , wherein the sub-step of reducing the rotation speed of the least two cutting disks of the base-cutting set and of the least two billet-cutting blades of the chopping assembly is performed when the position of the floating roller of the conveyance system is greater than the second reference value, and that the rotation speed of the at least two cutting disks of the base-cutting set and of the at least two billet-cutting blades of the chopping assembly is greater than a nominal rotation speed. 13. A system of operating an automotive harvester comprising: a cutting module comprising a base-cutting set including at least two cutting disks; a conveyance system including a floating roller; a chopping assembly including at least two billet-cutting blades; an electronic management center comprising a processing core and a data-storage core; a sensor associated with the base-cutting set; a sensor associated with the conveyance system; a sensor associated with the chopping assembly; a sensor capable of measuring a speed of the automotive harvester, wherein each of the sensors are configured for communicating with the electronic management center; a propulsion drive; a drive of the at least two cutting discs of the base-cutting set; a drive of the at least two billet-cutting blades of the chopping assembly, wherein the sensor associated with the base-cutting set relays data comprising parameters of the base-cutting set to the electronic management center, wherein the sensor associated with the conveyance system relays positioning data of the floating roller of the conveyance system to the electronic management center, wherein the sensor associated with the chopping assembly relays data comprising parameters of the chopping assembly to the electronic management center, wherein the processing core of the electronic management center compares signals originating from the sensors and to reference data stored in the data-storage core of the electronic management center, wherein the electronic management center controls a propulsion speed of the automotive harvester by the propulsion drive, and wherein the electronic management center controls rotation of the at least two cutting disks of the base-cutting set and of the at least two billet-cutting blades of the chopping assembly by the drive of the at least two cutting disks of the base-cutting set and the at least two billet-cutting blades of the chopping assembly.