Use of a power-steering motor to simulate an end-of-travel stop for said steering

1 . A method of managing a power-steering motor, during which an assistance setpoint (Ctot) is established which is intended to be applied to a power-steering motor designed for providing an assistance force (Assistance force) to assist in maneuvering a steering actuator member, of steering rack type, said actuator member being moveably mounted at least between a first position and a second position, distinct from each other, which delimit a functional travel of said actuator member allowing the latter to modify the orientation angle of a steering effector member, of steered wheel type, the method includes the following steps: a step (a) of defining a virtual end of travel threshold, during which at least one virtual end of travel threshold is chosen which corresponds to a fictional engaging position of the actuator member against a virtual stop, wherein said fictional engaging position strictly lies between the first position and the second position, a step (b) of evaluating a position, during which the instantaneous position of the actuator member is evaluated and compared with the virtual end of travel threshold so as to detect a crossing of said virtual end of travel threshold by said actuator member, and, if it is detected that the actuator member has crossed said virtual end of travel threshold in a predetermined crossing direction, a step (c) of simulating an end of travel stop during which is included in the assistance setpoint (Ctot) a resistance setpoint (Torque stop ) which simulates the effect of a mechanical stop by opposing to the progression, in the considered crossing direction, of the actuator member beyond the virtual end of travel threshold. and in that the resistance setpoint (Torque stop )is obtained by an expression of the first order simulating a spring-damper stop and which comprises to this end an elastic component (F E =K P VRE ·X Rack ) simulating a spring effect, which is proportional, according to a predetermined stiffness coefficient (K P VRE ), to the displacement amplitude (X Rack ) of the actuator member beyond the virtual end of travel threshold and a viscous component (F V =K D VRE ·{dot over (X)} Rack ), simulating a damping force, which is proportional, according to a predetermined coefficient of viscosity (K D VRE ), to the displacement speed ({dot over (X)} Rack ) of the actuator member, or by an expression of the second order simulating a mass-spring-damper stop and which comprises to this end an elastic component (F E ), a viscous component (F v ), and an inertial component (F 1 =K D2 VRE ·{umlaut over (X)} Rack ), simulating a moveable mass effect, which is proportional, according to a predetermined coefficient of inertia (K D2 VRE ), to the acceleration ({umlaut over (X)} Rack ), of the actuator member. 2 . The method according to claim 1 , wherein the virtual end of travel threshold(s) and/or the coefficients of stiffness (K P VRE ), of viscosity (K D VRE ) and of inertia (K D2 VRE ), are modified according to at least one parameter from among: the speed of displacement (V v ) of the vehicle on which the power-steering motor is set, the torque (τ V ) exerted by the driver on a steering wheel which controls the displacement of the actuator member, the position (Pt, X Rack ), the speed ({dot over (X)} Rack ) or the acceleration ({umlaut over (X)} Rack ) of the actuator member. 3 . The method according to claim 2 , wherein when the vehicle circulates beyond a predetermined high speed threshold, the damping of the virtual stop is increased. 4 . The method according to claim 1 , wherein the displacement of the actuator member being controlled by a steering wheel, the virtual end of travel threshold precedes by 30 degrees to 60 degrees, the extreme steering angular position of said steering wheel which corresponds to the mechanical displacement limit of the actuator member in the considered steering direction. 5 . The method according to claim 1 , wherein it is used as an anti-theft method, by parameterizing the virtual end of travel threshold(s) such as to use the power-steering motor to lock the displacement of the steering actuator member in an invariable position, or restrict said displacement within a predetermined restraining range, less than 50%, the displacement range corresponding to the normal functional travel of said actuator member. 6 . The method according to claim 5 , wherein the anti-theft adjustment of the virtual stop corresponds to values of the coefficients of stiffness (K P VRE ), of viscosity (K D VRE ) and/or of inertia (K D2 VRE ), strictly higher than those used for the virtual stops implemented during normal driving. 7 . The method according to claim 1 , wherein it is used as a method of adjusting the symmetry of the running gear of a vehicle including at least one effector member formed by a steered wheel, during which is set a first left virtual end of travel threshold and a second right virtual end of travel threshold such that the first virtual end of travel threshold and the second virtual end of travel threshold are located at equidistance on either side of a central median position which corresponds to an absence of turning of the steered wheel(s) of the running gear.