Method for determining the track rod force modeling the torsional elastic release of the tyre in order to manage transitions between park and drive

The invention claimed is: 1. A method of evaluating an actuation force on a transmission member that is called force at tie rods when a vehicle transitions from a parking situation to a running situation, comprising: transitioning the vehicle from the parking situation to the running situation; and evaluating the force at the tie rods by a process comprising: initially estimating a value for the force at the tie rods to obtain an estimated value for the force at the tie rods; and correcting the estimated value for the force at the tie rods by reducing said estimated value, in absolute value, according to a longitudinal velocity of the vehicle (V_vehic) when the vehicle transitions from the parking situation, in which the longitudinal velocity of the vehicle (V_vehic) is zero, to the running situation, in which the longitudinal velocity of the vehicle (V_vehic) is non-zero, wherein: the vehicle is equipped with a power steering system comprising a steering mechanism that connects an actuator to a steered wheel that is orientable in yaw; the steered wheel carries a tire with a tread that is in contact with a ground; and the steering mechanism comprises the transmission member on which the actuation force is evaluated. 2. The method according to claim 1 , wherein the force at the tie rods is evaluated from a model using: a first force component (F 1 ) that is representative of a yaw elastic torsion of the tire corresponding to a position deviation (Δx) between on the one hand a position (X CR ) imparted to the transmission member by the power steering system and on the other hand a position (X BR ) of the tread of the tire which is retained, against displacements of the transmission member, by a friction resistant force (Frot, k c ) that the ground exerts on the tread of the tire, and a second force component (F 2 ) that attenuates the first force component (F 1 ), according to the longitudinal velocity of the vehicle (V_vehic), as soon as the vehicle adopts a non-zero longitudinal speed, so as to take into consideration a progressive release of the yaw elastic torsion of the tire during the transition between the parking situation, where the longitudinal velocity of the vehicle is zero, and the running situation, where the longitudinal velocity of the vehicle is non-zero. 3. The method according to claim 2 , wherein the first force component (F 1 ) is modeled by means of a first stiffness coefficient (k t ), representative of a torsional stiffness of the tire, which is multiplied by the position deviation (Δx) between the transmission member and the tread of the tire: F 1 =k t *Δx. 4. The method according to claim 2 , wherein the second force component (F 2 ) is modeled by means of a second coefficient (k d ) multiplied by the longitudinal velocity of the vehicle (V_vehic) and by the position deviation (Δx) between the transmission member and the tread of the tire: F 2 =k d *V_vehic*Δx. 5. The method according to claim 4 , wherein the second force component (F 2 ) is calculated from the longitudinal velocity of the vehicle (V_vehic) and from a static friction value (Frot) that is representative of a friction force between the tread and the ground, in slip limit, which must be overcome by an action of the transmission member to cause, when the vehicle is stopped, a yaw displacement of the tread of the tire on the ground. 6. The method according to claim 5 , wherein the force at the tie rods is calculated from a first-order term relative to the longitudinal velocity of the vehicle (V_vehic) and equal to Frot 1 + K d · V_vehic k t . 7. The method according to claim 5 , wherein the second coefficient (k d ) is adjusted according to the static friction value (Frot). 8. The method according to claim 5 , wherein the static friction value (Frot) is adjusted according to parameters specific to the vehicle or to an environment of the vehicle and which modify an adhesion of the tire on the ground. 9. The method according to claim 4 , wherein the second coefficient (k d ) is adjusted according to the longitudinal velocity of the vehicle (V_vehic). 10. The method according to claim 2 , wherein the model allowing evaluation of the force at the tie rods additionally uses a third force component (F 3 ), which depends on the position (X CR ) of the transmission member, in order to model effects of lift-up of the vehicle during yaw steering of the steered wheel. 11. The method according to claim 10 , wherein the third force component (F 3 ) is calculated from a second-degree polynomial comprising a linear term and a quadratic term relative to the position (X CR ) of the transmission member: F 3 =kf1*X CR +kf2*X CR 2 . 12. The method according to claim 11 , wherein the coefficients (kf1, kf2) of the second-degree polynomial are adjusted according to the longitudinal velocity of the vehicle (V_vehic). 13. The method according to claim 1 , wherein the force at the tie rods is representative of a force exerted by the transmission member formed by a steering tie rod on one end of a rack that is movably mounted relative to a frame of the vehicle, and the steering tie rod connects to the steered wheel, and the force at the tie rods is evaluated from the longitudinal velocity of the vehicle (V_vehic) and the position of the rack (X CR ) considered as a representative position of the transmission member.