Method for selecting the target state of a drive train

The invention claimed is: 1. A method for selecting a target state of a vehicle driveline connecting at least a combustion engine and/or an electric machine to the wheels of the vehicle by a transmission, from a set of states present on the transmission, which are defined by various combinations of couplers and reduction gears thereof in order to transfer torque from the combustion engine and/or from the electric machine to the wheels over one or more gear ratios, comprising: filtering to determine, from a list of available states, state consecutive eligible sets as a function of combined driveability constraints, the filtering comprising: a first filtering step of considering all of the available states from the set of states present on the transmission and outputting vectors including a first vector representative of the available states and a second vector representative of the authorized states in a full electric mode, after the first filtering step, a second filtering step linked to a man-machine interface of a driver and to an engaged energy mode, the second filtering step including: selecting a selected vector from the first vector or the second vector based on the engaged energy mode, performing further filtering the selected vector based on an output of the man-machine interface; and outputting a third vector based on the further filtering, after the second filtering step, a third filtering step of filtering the third vector based on speed constraints, and after the third filtering step, a fourth filtering step of filtering a fourth vector output from the third filtering step based on force constraints of the driveline. 2. The selection method as claimed in claim 1 , wherein the filtering produces an eligibility final vector at an end of all of the filtering, which represents the set of the states eligible as a function of the driveability constraints. 3. The selection method as claimed in claim 1 , the first filtering step delivers a dysfunction vector signaling a presence of dysfunction on some states. 4. The selection method as claimed in claim 1 , wherein the third filtering step compares a common speed with minimum and maximum thresholds, specific to each eligible state of the third vector. 5. The selection method as claimed in claim 4 , wherein the third filtering step checks, at the same time, that the common speed on each eligible state of the third vector complies with the minimum and maximum speeds that can be permitted on these states with respect to a vibratory level thereof. 6. The selection method as claimed in claim 1 , the fourth filtering step includes a mechanism for overloading force constraints on a highest force which compares maximum forces available on each eligible state with regard to an operating range thereof in order to overload the force constraints on the highest one thereof. 7. The selection method as claimed in claim 1 , wherein the fourth filtering step includes a mechanism for recognizing up or down states and a common state. 8. The selection method as claimed in claim 1 , wherein the fourth filtering step includes a mechanism for filtering with consideration of a vibratory level on the set of the states of the eligible states, except on various reverse states and a neutral state. 9. The selection method as claimed in claim 1 , wherein the fourth filtering step includes a mechanism for filtering without consideration of a vibratory level delivering a vector which represents the states of the driveline complying with all of the driveability constraints with the exception of vibratory level constraints. 10. The selection method as claimed in claim 8 , wherein the filtering includes a final mechanism for consolidation between eligibility vectors of the fourth filtering step, with and without consideration of the vibratory level.