DE4142457C2 - Method for determining the rotational position of a steering shaft of motor vehicles - Google Patents

Description

The invention relates to a method according to the preamble of Claim 1.

In such a method known from DE 40 08 167 A1, the Rotational position of the steering shaft from the comparison of the speeds of the wheels one Vehicle axis won. Two encoders are required for this. In addition, one exact determination of the rotational position is not possible because the necessary A prerequisite for having identical speed signals when driving straight ahead, due to tire circumference and air pressure tolerances, one-sided loading and The like. Is often not met.

From EP 386 439 A2 it is also known with the aid of two steering angle sensors a rough measurement signal for the entire steering angle range of the steering shaft and a Fine measurement signal for the rotational position of the steering shaft within the respective Get steering turn. Again, two encoders are required which means a considerable effort. There is also an additional one Susceptibility to failure, e.g. B. in the event of failure of the coarse sensor, the information of Fine sensor, although it is correct for itself, no longer for security reasons is taken into account and therefore steering angle information is no longer available stands.

The invention has for its object a method of the aforementioned To create the type with little effort and low susceptibility to failure provides extremely accurate information about the actual steering angle.  

The invention solves this problem by the characterizing features of Claim 1.

In the invention, no attempt is made to use a sensor Obtain information about the steering angle range, which is opposite to that by the information provided by the fine sensor only with regard to the scale differs. This is the benchmark for EP-3 86 439 A2 mentioned at the beginning difference given by the gear ratio of the steering shaft. The overall single sensor provides fine steering angle information, i. H. steering angle information related to a single steering revolution.

Without using a separate sensor, the front wheel Speeds only obtained a steering angle information as a rough measurement signal, the represents the steering angle range. The range is a steering angle of 180 DEG or preferably 360 DEG, i.e. H. an entire steering wheel or Understand steering shaft rotation. One accepted in any form Steering angle range at the beginning of a trip is because of the recorded steering angle area information a clear trend towards the actual Have steering angle range, quickly corrected by the true steering angle range become.  

Improvements and further refinements of the Er invention are the subject of claims 2 to 10.

The claims in the claims 3 to 5 are numerical Possibilities indicated that be in claim 2 written use of the speed difference signals of the two front wheels efficiently for extraction the steering angle range information. The one in Claim 4 specified linear and reciprocal Zu  correlation with the vehicle speed results from the simplified adoption of the motor vehicle as linearized single track model.

The claims 6 to 8 deal with the statistical evaluation of the steering angle obtained empire information. This is a division of classes (Classification) of the steering angle range information taken. The information obtained is transferred to the divided into different possible steering angle ranges (Claim 6), possibly even swift Dependence on density (claim 8). The latter is based on the consideration that at higher speeds as a rule, the steering angle range in which the center position of the steering shaft is also.

The measure specified in claim 7, only about a predetermined speed of, for example Working at 5 km / h is advantageous in two ways Terms. On the one hand, it results when a right Ziproker connection of the steering angle with the vehicle speed is taken into account, a numerical Problem with very low vehicle speeds. In addition, it is taken into account that the steering angle area information for particularly small vehicles speeds without special interest is there downstream control devices for vehicle stabilization lization or influencing of vehicle dynamics these speeds are not effective anyway.

The following is the numerical process of extraction steering angle range information based on mathema table formulas further explained.  

The linearized single-track model of a motor vehicle results in a “synthetic”, ie model-like steering angle δs1 for small values of this angle

δs1 = (k1 / v + k2 × v) × δv

with K1 and K2 vehicle-specific constants,
v = vehicle speed and
δv = differential speed of the two front wheels.

For larger steering angles, the value δs results from a functional development

δs = δs1 × [k3 + k4 × | δs1 | + (k4 × δs1) ² ]

with k3, k4 u. k5 vehicle-specific constants.

At the start of the journey, a steering angle range for the steering angle δw is assumed which contains the central position. If the assumption is correct, the steering angle signal supplied by the fine sensor is synchronized with the actual steering angle and shows the sawtooth-like curve shown in FIG. 1. After every 360 ° there is a jump in the signal which corresponds to the entire signal value range.

However, the assumption can also be incorrect. In this Case there is a phase difference that is an integer Is a multiple of 360 °. Such is the case shown in dashed lines.  

Information about the total steering angle can be obtained from the information from the fine sensor together with the signal direction of the steering angle jump by adding or subtracting a corresponding value. This results in information about the total steering angle, which depends on the original assumption of the center position and which is shifted parallel to the actual steering angle if incorrectly assumed by 360 °, or a multiple thereof ( Fig. 2). For the incorrect acceptance shown in dashed lines, this results in the dashed line course of the supposed steering angle compared to the actual steering angle, which is continuously drawn.

The incorrect assumption of the original zero position of the steering angle can now be corrected with the aid of a correction factor which provides the actual steering angle using statistical means. For this purpose, a momentary correction factor KSm is determined for each steering angle, which is taken from the table below and shows the relationship with the associated steering angle range:
KSm = -2 for δw - δs <-540 °
KSm = -1 for -540 ° <δw - δs <-180 °
KSm = 0 for -180 ° <δw - δs <+ 180 °
KSm = 1 for 180 ° <δw - δs <540 °
KSm = 2 for 540 ° <δw - δs

The present steering angle range is in the form of Difference value between the assumed steering angle 0  (at the start of the journey) and that from the single-track model resulting steering angle δs taken into account.

The current correction factors KSm become a statistically verified (total) correction factor KS won by classifying. KSm is used with a vehicle speed dependent weighting in one Inscribed memory, not shown. Here is based on the consideration that at higher Ge speeds mostly the middle, d. H. the zero position the steering angle range containing the steering shaft is present. This is taken into account by the current correction door factor at higher speeds with a ge speed-dependent factor (e.g. 5 for vehicle speeds greater than 100 km / h or 3 for vehicle speeds between 50 and 100 km / h compared the value 1 for vehicle speeds below 50 km / h) is set. After running only a few computers In this way the actual Cor Determine correction factor KS quickly and correctly. KS he possible, the offset of the Steering angle compared to the assumed steering angle to eliminate equal to 0. Is KS correctly determined and the steering angle offset is eliminated, the result is at the subsequent calculations the correction factor KS to 0.

The previous description was based on a constant ge from the steering angle range information. The Speeds or speed differences between the two Front wheels are continuously with the same time interval won and described in the Processed way. Depending on the application, there may be  however, the need arises for certain Operating states, for example a braking operation of the Motor vehicle gaining the steering angle prevent area information. In these cases the calculation described can lead to incorrect results nits. Using the statistics described procedures can then be discontinuous However, who compensated relatively quickly the. It has been shown, for example, that a time interval between successive steering angle evaluations of 10 msec approximately within one Minute an exact statement about the current steering angle range results. Occasionally occurring briefly timely interruptions occur with such Processing speed and renewal rate not weight.

In this context, the Er invention particularly valuable, which in claim 9 given is. By shortening the time successive steering angle evaluations e.g. B. 5 msec at high speeds Problems caused by a short-term Interruption can occur in even less time eliminate as specified.

In special applications it may be necessary be an exact one relatively shortly after the start of the journey Information about the actual steering angle range to have available. Such an application is for example in a motor vehicle with four-wheel given guidance. In this case, as in Claim 10 indicated to be advantageous only then  to process the speeds of the two front wheels, when the vehicle is in a quasi-stationary driving state owns. Falsifications of the speed information or the wheel speed as a result of braking maneuvers, Aquaplaning and vehicle instabilities (sub- / Oversteer) can be checked via plausibility checks Driving state parameters are determined. For this you can for the steering wheel angular speed, the individual wheel acceleration as well as vehicle acceleration vehicle-specific limit values are specified at if they exceed the values of the wheel speeds or Wheel speeds are not taken into account. He can in addition for the quotients of the speeds of the both front wheels or the quotients from the front axle and rear axle speed vehicle or system specific limits (e.g. from 0.8 to 1.2) are specified and the steering angle range information is only obtained if these quotients are within this Limit values. It is thus done with the help of Plausi balance checks determine whether it is an in stationary or quasi-stationary driving state of the Motor vehicle acts and only in the latter case Steering angle range information obtained. This will be a system controlled by it at the start of the journey set the required way.

Claims (10)

1. A method for determining the rotational position, which is obtained by evaluating the rotational speeds of the two front wheels of the motor vehicle and wave over the entire rotational range of the steering with a Sen sorsignal passes a steering shaft of motor vehicles, having a center position and executes a plurality of revolutions, characterized in that that the sensor signal is used as steering angle range information and is superimposed by a second fine measurement signal which extends over a rotation range of the steering shaft of 360 ° and is supplied by an additional sensor. 2. The method according to claim 1, characterized in that the extraction the steering angle range information by evaluating the speed differences limit of the two front wheels. 3. The method according to claim 2, characterized in that the ver different times determined speed difference of the two front wheels is averaged numerically. 4. The method according to claim 2 or 3, characterized in that in the Evaluation of the speed difference between the two front wheels linear and right ziprok regarding the vehicle speed is taken into account. 5. The method according to any one of claims 2 to 4, characterized in that when evaluating the speed difference of the two front wheels is considered as functional development.   6. The method according to any one of claims 1 to 5, characterized in that the steering angle range information is obtained by means of a correction factor is derived from the classification of the current steering angle ranges is tested. 7. The method according to claim 6, characterized in that the classification is only carried out at a predetermined vehicle speed. 8. The method according to claim 6 or 7, characterized in that the Classification with a weighting that is dependent on the vehicle speed. 9. The method according to any one of claims 1 to 8, characterized in that the time interval for determining the speeds of the two pre the wheels for high speeds is smaller than for low speeds. 10. The method according to any one of claims 1 to 9, characterized in that the speeds of the two front wheels are then not evaluated, when the motor vehicle is in an unsteady driving state.