ITTO20110828A1 - METHOD OF CALCULATION TO DETERMINE THE VALUES TO BE ASSIGNED TO THE PARAMETERS OF A MATHEMATICAL MODEL THAT SIMULATES THE DYNAMIC PERFORMANCE OF THE TIRES OF A VEHICLE DURING THE VEHICLE OF THE SAME VEHICLE - Google Patents

Description

DESCRIPTION

of the patent for industrial invention entitled:

"CALCULATION METHOD FOR DETERMINING THE VALUES TO BE ASSIGNED TO THE PARAMETERS OF A MATHEMATICAL MODEL SIMULATING THE DYNAMIC PERFORMANCE OF A VEHICLE TIRES WHILE THE VEHICLE IS RUNNING"

TECHNIQUE SECTOR

The present invention relates to a calculation method for determining the values to be assigned to the parameters of a mathematical model that simulates the dynamic performance of the tires of a vehicle while the vehicle is running.

ANTERIOR ART

Tire manufacturers are frequently asked to build tires that adapt to a specific vehicle model, that is, that have dynamic characteristics that allow them to optimize the vehicle's behavior on the road.

In the initial design phase of a tire that must be adapted to a specific vehicle model, a mathematical model is normally used which simulates the dynamic performance of the tires while the vehicle is running; the aid of the mathematical model is fundamental to optimize the initial phase of the project (i.e. to obtain the maximum result in the minimum time) as it allows (or rather should allow) to define a dimensioning close to the definitive one before starting the construction of prototypes to be tested in the laboratory and on the road (the construction and testing of prototypes involves long times and high costs and therefore, if possible, prototypes should be used only in the final phase).

Once the mathematical model to be used has been decided (i.e. once the equations that make up the mathematical model have been decided), it is necessary to determine the values to be assigned to the parameters of the mathematical model. In other words, each equation of the mathematical model includes a certain number of parameters that must be "customized" with respect to the vehicle whose behavior is to be simulated, i.e. each parameter must be assigned a value that reflects (within the mathematical model ) the actual physical behavior of the vehicle whose behavior is to be simulated.

Currently, to determine the values to be assigned to the parameters of the mathematical model, the tires, suspensions and shock absorbers of the vehicle whose behavior is to be simulated are removed from the vehicle and individually subjected to various bench tests; the dynamic characteristics of the tires, suspensions and shock absorbers are determined as a function of the result of these bench tests and then the corresponding values are calculated from the dynamic characteristics to be assigned a part of the parameters of the mathematical model. The values of the remaining parameters of the mathematical model are determined by other bench tests which involve the whole vehicle and which generally involve the measurement of the (unsprung) masses of the vehicle and the survey of the dynamic characteristics of the steering chain.

Once all the values to be assigned to the parameters of the mathematical model have been determined, the vehicle whose behavior is to be simulated is equipped with measuring instruments that are generally applied to the wheels (such as the so-called "Dynawheel" of the company IDIADA) and measure in time real while driving on the road a series of physical quantities, such as, for example, the forces acting on the wheels in a three-dimensional reference system and the movements (both translation and rotation) of the wheels with respect to the frame always in a reference system three-dimensional. Then the real data measured while driving on the road are compared with the similar simulated data provided by the mathematical model to verify the goodness of the mathematical model (i.e. the degree of correspondence of the mathematical model to physical reality) and, if necessary, to refine the mathematical model. through targeted correction of the values assigned to the parameters.

However, the method described above for determining the values to be assigned to the parameters of the mathematical model presents problems as it requires that the shock absorbers and suspensions are removed from the vehicle and then subjected to tests on dedicated test benches: disassembly (and obviously the subsequent assembly) of shock absorbers and suspensions requires the intervention of an expert mechanic and above all the dedicated test benches for shock absorbers and suspensions are very expensive and complex to use. Consequently, the method described above for determining the values to be assigned to the parameters of the mathematical model is adequate for an automobile manufacturer (who has to size and calibrate shock absorbers and suspensions), but is problematic for a tire manufacturer (who normally assembles and disassembles wheels but does not intervene on shock absorbers and suspensions).

DESCRIPTION OF THE INVENTION

The purpose of the present invention is to provide a calculation method for determining the values to be assigned to the parameters of a mathematical model that simulates the dynamic performance of the tires of a vehicle while the vehicle is running, which calculation method is easy and economical. realization and is, at the same time, devoid of the drawbacks described above.

According to the present invention, a calculation method is provided for determining the values to be assigned to the parameters of a mathematical model that simulates the dynamic performance of the tires of a vehicle while the vehicle is running according to what is established in the attached claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will now be described with reference to the attached drawings, which illustrate a non-limiting example of embodiment, in which:

Figure 1 is a schematic three-dimensional view of a four-wheeled vehicle, the dynamic performance of which is to be simulated by means of a mathematical model; And

• Figures 2-6 are some graphs that compare the real dynamic behavior of the vehicle's wheels with the corresponding dynamic behavior simulated by means of the mathematical model.

PREFERRED EMBODIMENTS OF THE INVENTION

In Figure 1, the number 1 indicates as a whole a vehicle (in particular a car) provided with four wheels 2 which are equipped with corresponding tires. Each wheel 2 is connected to a frame 3 of the vehicle 1 by means of a corresponding suspension 4 which is provided with a shock absorber 5 and a spring 6 arranged around the shock absorber 5.

By means of a mathematical model it is desired to simulate the dynamic performance of the tires of the vehicle 1 during the running of the vehicle 1 itself. The mathematical model to be used to simulate the dynamic performance of the tires of vehicle 1 is widely known in the literature, is valid for a wide range of four-wheeled vehicles, and contains a series of parameters that must be "customized" with respect to the vehicle 1 whose behavior you want to simulate. In other words, each parameter of the mathematical model must be assigned a value that reflects (within the mathematical model) the actual physical behavior of the vehicle 1 whose behavior is to be simulated.

To determine the values to be assigned to the parameters of the mathematical model, the mathematical model is divided into four areas: the characterization of the chassis 3, the characterization of the tires, the characterization of the suspension 4, and the characterization of the shock absorbers 5. The characterization of the chassis 3 takes place in the traditional way by means of static tests with the vehicle 1 stationary and essentially involves determining the value of the unsprung masses (i.e. the weight of the vehicle 1 with the exception of the wheels 2 and all the suspension components 4), the moments of inertia in a three-dimensional reference system, and the characteristics of the steering. The characterization of the tires takes place in the traditional way by removing the tires from the vehicle 1 and subjecting the tires to static (ie with the tire stationary) and dynamic (ie with the tire in motion) bench tests. The characterization of the suspensions 4 and the characterization of the shock absorbers 5 takes place in an innovative way by means of static tests with the vehicle 1 stationary and dynamic tests with the vehicle 1 in motion; the novelty consists in the fact that the suspensions 4 and the shock absorbers 5 are not removed from the vehicle 1, but always remain mounted on the vehicle 1 and therefore the various tests take place always involving the whole vehicle 1 in its entirety.

In other words, in the mathematical model the parts corresponding to the suspensions 4 and shock absorbers 5 of the vehicle 1 are isolated, then the complete vehicle 1, or equipped with all its parts, is subjected to static tests with the vehicle 1 stationary and to dynamic tests. with the vehicle 1 in motion by measuring during these static and dynamic tests a series of experimental values of physical quantities that characterize the behavior of the vehicle 1; finally, the values to be assigned to the parameters of the parts of the mathematical model corresponding to suspensions 4 and shock absorbers 5 are determined as a function of the experimental values measured during these static and dynamic tests.

To carry out the tests, vehicle 1 is equipped with a series of measuring instruments which, by way of example, may include:

a steering sensor which measures the steering angle SWA (i.e. the angular position of the steering wheel of the vehicle 1) and the steering torque (i.e. the torque that is applied to the steering wheel of the vehicle 1);

a tri-axial gyroscope which is fixed to the frame 3 and measures in a three-dimensional reference system the linear accelerations along the three axes of the frame 3 with respect to the ground and the angular velocities around the three axes of the frame 3 with respect to the ground;

an optical sensor which is fixed to the frame 3, is pointed towards the road surface, and measures the longitudinal speed of the frame 3 (i.e. of the vehicle 1) with respect to the ground, the lateral speed of the frame 3 (i.e. of the vehicle 1) with respect to the ground , and the attitude angle (i.e. the angle between the two vectors of longitudinal speed and lateral speed) of the chassis 3 (i.e. of the vehicle 1) with respect to the ground;

dynamometric wheels, each of which is coupled to a corresponding wheel 2 and measures the forces and moments acting on the wheel 2 in a three-dimensional reference system; And

wheel markers, each of which is coupled to a corresponding wheel 2 and measures in a three-dimensional reference system the six degrees of freedom (three positions and three angles) of wheel 2 with respect to frame 3, i.e. it measures the position and orientation of wheel 2 in a three-dimensional reference system and with respect to the frame 3.

According to a preferred embodiment, for each suspension 4 of the vehicle 1 the mathematical model provides for the use of four equations of the suspension 4 which all have the same identical structure and respectively provide the camber angle of the wheel 2, the angle of wheel toe 2, the longitudinal position of the wheel attachment and the transverse position of the wheel attachment. The structure of the four equations of suspension 4 is as follows:

A size of the suspension 4 to be determined (ie the camber angle of the wheel 2, the toe angle of the wheel 2, the longitudinal position of the wheel attachment, or the transverse position of the wheel attachment);

Static astrovalue of the size of the suspension 4;

z position of wheel 2 along the vertical axis;

SWA steering angle;

Fx longitudinal force acting on wheel 2;

Transverse force acting on wheel 2;

A moment of self-alignment acting on the wheel 2 and which tends to rotate the wheel 2 around the vertical axis.

In the equation described above, the following are determined by means of static tests on vehicle 1 (i.e. tests which involve keeping vehicle 1 completely stationary): the Astatstatic value of the size of the suspension 4, the variation ΔΑζ of the size of the suspension 4 due to the change in position z along the vertical axis of the center of gravity of the vehicle 1, and the variation AASWA of the size of the suspension 4 due to the variation of the steering angle SWA.

The Astatstatic value of the size of the suspension 4 can be determined by means of a static test which provides for detecting the static configuration of the suspensions 4 of the vehicle 1 in the absence of external stresses. The variation ΔΑζ of the size of the suspension 4 due to the variation of the position z along the vertical axis of the center of gravity of the vehicle 1 can be determined by means of static tests which involve applying a symmetrical and asymmetrical vertical force directed downwards. The variation AASWA of the size of the suspension 4 due to the variation of the steering angle SWA can be determined by means of static tests which involve rotating the steering wheel of the vehicle 1 in both directions.

In the equation described above, the following are determined by means of dynamic tests on vehicle 1 (i.e. tests involving moving vehicle 1 along a test path): the variation δΑ of the size of the suspension 4 as a function of the longitudinal force acting on wheel 2, the variation δΑ of the size of the suspension 4 as a function of the transversal force acting on the wheel 2, and the variation δΑ of the size of the suspension 4 as a function of the self-aligning moment Mz acting on the wheel 2.

The variation δΑ of the size of the suspension 4 as a function of the variation dFx of the force Fxlongitudinal acting on the wheel 2 can be determined by means of dynamic tests which involve braking and accelerating the vehicle 1 in a quasi-static (i.e. very slow) way along a perfectly straight path. .

According to a preferred embodiment, the total sum of the variation δΑ of the size of the suspension 4 as a function of the force is determined by means of dynamic tests (i.e. with the vehicle 1 in motion) which provide for quasi-static (i.e. very slow) variations on the vehicle 1 Transversal acting on the wheel 2 and the variation δΑ of the size of the suspension 4 as a function of the self-aligning moment Mz acting on the wheel 2; furthermore (as a result of a simplification that introduces a certain error) the total sum of the two variations δΑ of the size of the suspension 4 is attributed only as a function of the transversal force acting on the wheel 2. In other words, accepting an approximation to simplify, the sum overall of the two variations δΑ of the size of the suspension 4 is attributed only as a function of the transversal force acting on the wheel 2 (i.e. it is assumed that the self-aligning moment Mz acting on the wheel 2 has no effect on the size A of the suspension 4 in question). This approximation is inevitable, since by means of static and / or dynamic tests on the vehicle 1 in its entirety it is not possible to separate the contribution of the transversal force acting on the wheel 2 from the contribution of the self-aligning moment Mz acting on the wheel 2; consequently, both contributions are considered together and are attributed solely to the transversal force acting on the wheel 2. Several experimental tests have shown that this approximation would have a significant impact on the accuracy of the simulation of the dynamic behavior of the various elements of the suspension 4, but it has a negligible (i.e. not significant) impact in the simulation of the dynamic behavior of the tire carried by the wheel 2 (i.e. from the point of view of the "end user" of the suspension 4, or from the point of view of the tire, it does not really matter what actually happens at inside the suspension 4, but only what "comes out" of the suspension 4).

The overall sum (of the variation δΑ of the size of the suspension 4 as a function of the transversal force acting on wheel 2 and of the variation δΑ of the size of the suspension 4 as a function of the self-aligning moment Mz acting on the wheel 2) can be determined by means of dynamic tests. which provide for varying the steering angle SWA of the vehicle 1 while the vehicle 1 advances at a constant speed.

According to a preferred embodiment, the vectors containing the quantities that excite each damper 5 and the quantities that are directly influenced by the damper 5 are determined in a high number of points and starting from the experimental values measured during the dynamic tests; then, the damping characteristic of each shock absorber 5 is constructed by means of a mathematical technique which has the aim of minimizing the differences, for the same quantities that excite the shock absorber 5 and for all points, between the values measured by means of the dynamic tests and the values estimated by the mathematical model of the quantities which are directly influenced by the shock absorber 5. Preferably (but not necessarily), a genetic algorithm is used to construct the damping characteristic of each shock absorber 5; in particular, the objective of the genetic algorithm is to minimize the mean square deviation between the measured value and the estimated value of the quantities that are directly influenced by the damper 5.

According to a preferred embodiment, the quantities which excite the shock absorbers 5 are the roll angle of the frame 3 and the roll speed of the frame 3 and the quantities which are directly influenced by the shock absorber 5 are the vertical position of the wheels 2 front and vertical position and 2 rear wheels.

It is important to note that the equation of the mathematical model that represents each shock absorber 5 of the vehicle 1 provides for the knowledge of the mass of the chassis 3 of the vehicle 1, i.e. the unsprung masses of the vehicle 1, and the stiffness of the spring 6 coupled to the shock absorber 5. The mass of the chassis 3 of the vehicle 1 is measured directly by measuring the weight of the vehicle 1 in static conditions, while the stiffness of the spring 6 coupled to each shock absorber 5 is identified by means of static tests which involve applying different static vertical loads on the 2 wheels of the vehicle 1.

Once all the values to be assigned to the parameters of the mathematical model have been determined, as described above, the vehicle 1 whose behavior is to be simulated is subjected to a series of validation tests which involve comparing the dynamic behavior under different conditions real (i.e. effective, directly deriving from instrumental measurements) with the same simulated dynamic behavior, i.e. obtained through the mathematical model (an example of this comparison is illustrated in Figures 2-6). The purpose of these validation tests is both to verify the correctness of the mathematical model (i.e. the identity within the expected errors between the real dynamic behavior and the simulated dynamic behavior), and to refine (if necessary) the values of the model parameters. mathematical as a function of the deviations between the real dynamic behavior and the simulated dynamic behavior.

By way of example, Figure 2 shows a graph showing the correlation between the lateral acceleration [m / s <2>] of the frame 3 on the abscissa and the steering angle SWA [°] on the ordinate; the real dynamic behavior is shown in a solid line, while the corresponding simulated dynamic behavior is shown in a dashed line.

By way of example, Figure 3 shows a graph showing the correlation between the lateral acceleration [m / s <2>] of the frame 3 on the abscissa and the variation of the yaw angle [° / s] on the ordinate; the real dynamic behavior is shown in a solid line, while the corresponding simulated dynamic behavior is shown in a dashed line.

By way of example, Figure 4 shows a graph showing the evolution over time [s] in the abscissa of the variation of the roll angle [° / s] of the frame 3 in the ordinate; the real dynamic behavior is shown in a solid line, while the corresponding simulated dynamic behavior is shown in a dashed line.

As an example, Figure 5 shows a graph showing the evolution over time [s] in the abscissa of the front camber angle [°] in the ordinate; the real dynamic behavior is shown in a solid line, while the corresponding simulated dynamic behavior is shown in a dashed line.

By way of example, Figure 5 shows a graph showing the evolution over time [s] in the abscissa of the compression of the front shock absorbers 5 [mm] in the ordinate; the real dynamic behavior is shown in a solid line, while the corresponding simulated dynamic behavior is shown in a dashed line.

The calculation method described above has numerous advantages.

In the first place, the calculation method described above allows to determine the values to be assigned to the parameters of the mathematical model without requiring the disassembly of either the suspensions 4 or the shock absorbers 5 from the vehicle 1 (consequently, the use of a test benches dedicated to suspensions and shock absorbers). Therefore, the calculation method described above is particularly suitable for a tire manufacturer who normally assembles and disassembles wheels but does not intervene on suspensions and shock absorbers.

Furthermore, the calculation method described above allows to obtain a mathematical model which allows to simulate with great precision the dynamic performances of the tires without requiring, at the same time, a long and laborious refining process by means of experimental tests; this result is obtained thanks to the fact that to determine the values to be assigned to the parameters of the mathematical model the vehicle 1 is always tested in its entirety and therefore taking into account from the beginning the reciprocal interactions between the various components of the vehicle 1 (instead, by testing individually the various components of the vehicle 1 a faithful characterization of each component is obtained, but the effect of the reciprocal interactions between the various components is completely lost).

It is important to note that the calculation method described above is suitable for a tire manufacturer who is only interested in the sizing of the tires (i.e. all the other components of the vehicle 1 have already been sized by the manufacturer of the vehicle 1 and therefore are invariants on which there is no possibility of intervention), since in the absence of a specific and single characterization of the suspensions 4 and shock absorbers 5 it is not possible to know the detailed behavior of these elements, but only their effect on the wheels 2 (and therefore, in ultimately, on tires which are the only and effective object of the simulation).

In other words, the (fully achieved) objective of the present invention is to allow a tire manufacturer who has to build tires that are adapted to a specific vehicle model (i.e. that have dynamic characteristics that allow to optimize the behavior on road of the vehicle) to use in an efficient (i.e. without excessive use of resources) and effective (i.e. with profit) a tool (the mathematical model) created and developed by vehicle manufacturers to meet their specific needs and therefore excessively refined and complex for a tire manufacturer.

Claims (15)

R IV E N D I CA Z I O N I 1) Calculation method for determining the values to be assigned to the parameters of a mathematical model that simulates the dynamic performance of the tires of a vehicle (1) while the vehicle is running (1); the calculation method includes the steps of: isolate in the mathematical model the parts corresponding to suspensions (4) and shock absorbers (5) of the vehicle (1); subject the complete vehicle (1), i.e. provided with all its parts, to static tests with the vehicle (1) stationary and to dynamic tests with the vehicle (1) in motion, measuring a series of experimental values during these static and dynamic tests of physical quantities that characterize the behavior of the vehicle (1); and determining the values to be assigned to the parameters of the parts of the mathematical model corresponding to suspensions (4) and shock absorbers (5) as a function of the experimental values measured during the static and dynamic tests. 2) Method of calculation according to claim 1 and comprising the further steps of: determine, in a large number of points and starting from the experimental values measured during the dynamic tests, the vectors containing the quantities that excite each shock absorber (5) of the vehicle (1) and the quantities that are directly influenced by the shock absorber (5); And construct the damping characteristic of each shock absorber (5) of the vehicle (1) by means of a mathematical technique which aims to minimize the differences, for the same quantities that excite the shock absorber (5) and for all points, between the values measured by the dynamic tests and the values estimated by the mathematical model of the quantities that are directly influenced by the shock absorber (5). 3) A calculation method according to claim 2 and comprising the further step of using a genetic algorithm to construct the damping characteristic of each shock absorber (5) of the vehicle (1). 4) Method of calculation according to claim 3 and comprising the further step of using the genetic algorithm to minimize the mean square deviation between the measured value and the estimated value of the quantities which are directly influenced by the damper (5). 5) Calculation method according to claim 2, 3 or 4, in which the quantities which excite the shock absorbers (5) are the roll angle of the chassis (3) and the roll speed of the chassis (3) and the quantities which the vertical position of the front wheels (2) and the vertical position and of the rear wheels (2) are directly influenced by the shock absorber (5). 6) Calculation method according to one of claims 2 to 5, wherein: the equation of the mathematical model that represents each shock absorber (5) of the vehicle (1) provides for the knowledge of the mass of the chassis (3) of the vehicle (1), i.e. of the unsprung masses of the vehicle (1), and of the stiffness of a spring (6) coupled to the shock absorber (5); the mass of the chassis (3) of the vehicle (1) is directly measured by a measurement of the vehicle weight (1) under static conditions; And the stiffness of the spring (6) coupled to each shock absorber (5) is identified by means of static tests which involve applying different static vertical loads on the wheels (2) of the vehicle (1). 7) Calculation method according to one of claims 1 to 6, wherein: for each suspension (4) of the vehicle (1) the mathematical model provides for the use of four suspension equations (4) which all have the same identical structure and respectively provide the wheel camber angle (2), the angle convergence of the wheel (2), the longitudinal position of the wheel attachment and the transverse position of the wheel attachment; the structure of the four suspension equations (4) is the following: A = Astat + ΔΑ (z) ΔΑ (SWA) δΑ (Fx) δΑ (Fy) δΑ (Mz) The extent of the suspension (4) to be determined; Static astrovalue of the magnitude of the suspension (4); z position of the wheel (2) along the vertical axis; SWA steering angle; Fx longitudinal force aqent on the wheel (2); Transverse force on the wheel (2); Moment of self-alignment occurring on the wheel (2) and which tends to rotate the wheel (2) around the vertical axis. 8) Method of calculation according to claim 7 and comprising the further steps of: determine by means of static tests on the vehicle (1) the Astatstatic value of the suspension magnitude (4), the variation ΔΑ (ζ) of the suspension magnitude (4) due to the variation of position (z) along the vertical axis of the center of gravity of the vehicle (1), and the variation hA (SWA) of the size of the suspension (4) due to the variation of the steering angle SWA; and determine by means of dynamic tests on the vehicle (1) the variation δΑ of the size of the suspension (4) as a function of the longitudinal force Fxlongitudinal acting on the wheel (2), the variation δΑ of the size of the suspension (4) as a function of the transversal force acting on the wheel (2), and the variation δΑ of the size of the suspension (4) as a function of the self-aligning moment Mz acting on the wheel (2). 9) Calculation method according to claim 8 and comprising the further step of determining the Astatstatic value of the size of the suspension (4) by means of a static test which provides for detecting the static configuration of the suspensions (4) of the vehicle (1) in the absence of external stresses. 10) Method of calculation according to claim 8 or 9 and comprising the further step of determining the variation ΔΑ (ζ) of the size of the suspension (4) due to the variation of the position (z) along the vertical axis of the center of gravity of the vehicle (1) by means of static tests which involve applying a vertical force directed downwards on the chassis (3) of the vehicle (1) in a symmetrical and asymmetrical manner. 11) Method of calculation according to claim 8, 9 or 10 and comprising the further step of determining the variation AA (SWA) of the size of the suspension (4) due to the variation of the steering angle SWA by means of static tests which provide turning a vehicle steering wheel (1) in both directions. 12) Calculation method according to one of claims 8 to 11 and comprising the further step of determining the variation δΑ of the size of the suspension (4) as a function of the variation dFx of the force Fxlongitudinal acting on the wheel (2) by means of dynamic tests which provide to brake and accelerate the vehicle (1) in a quasi-static way along a perfectly straight path. 13) Calculation method according to one of claims 8 to 12 and comprising the further steps of: determine the total sum of the variation δΑ of the suspension size (4) as a function of the transversal force acting on the wheel (2) and of the variation δΑ of the suspension size (4) as a function of the self-alignment moment Mz acting on the wheel (2) by means of dynamic tests involving quasi-static variations on the vehicle (1); and to attribute, accepting an approximation to simplify, the total sum of the two variations δΑ of the size of the suspension (4) only as a function of the transversal force acting on the wheel (2). 14) Calculation method according to claim 13 and comprising the further step of determining the overall sum by means of dynamic tests which provide for varying the steering angle SWA of the vehicle (1) while the vehicle (1) advances at a constant speed. 15) Calculation method according to one of claims 1 to 14 and comprising the further step of measuring the experimental values of the following physical quantities which characterize the behavior of the vehicle (1): SWA steering angle; steering torque; linear accelerations of the chassis (3) of the vehicle (1) in a three-dimensional reference system and with respect to the ground; angular velocities of the chassis (3) of the vehicle (1) in a three-dimensional reference system and in relation to the ground; longitudinal speed, lateral speed, and angle of attitude of the chassis (3) of the vehicle (1) with respect to the ground; forces and moments acting on the wheels (2) of the vehicle (1) in a three-dimensional reference system; position and orientation of the wheels (2) of the vehicle (1) in a three-dimensional reference system and with respect to the frame (3) of the vehicle (1).