METHOD AND DEVICE FOR ASCERTAINING THE STEERING ANGLE OF A ONE-TRACK VEHICLE

Abstract

A method for ascertaining the steering angle of a one-track vehicle, in which: with a frame sensor system attached at a first location on the frame of the vehicle, the first frame accelerations occurring there and first frame rotation rates of the two-wheeler are each ascertained in three first spatial directions, with a steering system sensor system attached at a second location of the steering system of the vehicle, the steering system accelerations of the two-wheeler occurring there are ascertained in three second spatial directions, based on the ascertained first frame accelerations and first frame rotation rates, second frame accelerations at the location of the second steering system sensor system in the three first spatial directions are calculated based on a mathematical relationship, and based on the calculated second frame accelerations and the ascertained steering system accelerations, the steering angle of the vehicle is ascertained.

Claims

1. A method for ascertaining a steering angle of a one-track vehicle, the method comprising: ascertaining, with a frame sensor system attached at a first location on the frame of the vehicle, the first frame accelerations occurring there and first frame rotation rates of the two-wheeler in three first spatial directions; ascertaining, with a steering system sensor system attached at a second location on the steering system of the vehicle, the steering system accelerations of the two-wheeler occurring there in three second spatial directions; determining, based on the ascertained first frame accelerations and first frame rotation rates, second frame accelerations at the location of the second steering system sensor system in the three first spatial directions based on a mathematical relationship; and ascertaining, based on the calculated second frame accelerations and the ascertained steering system accelerations, the steering angle of the vehicle.

2. The method of claim 1, wherein the frame sensor system is a first inertial sensor cluster, which ascertains the accelerations and rotation rates occurring at the attachment site of the system in each case in the three first spatial directions.

3. The method of claim 1, wherein the steering system sensor system is a second inertial sensor cluster, which rotates together with the steering column and ascertains the accelerations occurring at the attachment site of the system in the three second spatial directions.

4. The method of claim 1, wherein the second frame accelerations at the location of the second steering system sensor system are ascertained with the aid of the relationship $.Math. \overline{a} .Math. ? = \overline{a} .Math. ? - \dot{\overline{ω}} \times \overline{l} .Math. ? - \overline{ω} .Math. ? \times \overline{ω} \times \overline{l} .Math. ?$ $? .Math. indicates text missing or illegible when filed$ ā.sup.T denoting the second frame accelerations, denoting the first frame accelerations, denoting the first frame rotation rates, denoting the derivative of the first frame rotation rates with respect to time, and denoting the distance vector from the sensor on the frame to the sensor on the steering system.

5. The method of claim 4, wherein the steering angle is ascertained with the aid of the relationship $\sin .Math. .Math. δ = \frac{a_{y}^{T} .Math. a_{x}^{L} - a_{x}^{T} .Math. a_{y}^{L}}{a_{x}^{T^{2}} + a_{y}^{T^{2}}}$ δ denoting the steering angle, a.sub.x.sup.L denoting the steering system acceleration in the longitudinal direction of the front wheel, a.sub.y.sup.L denoting the steering system acceleration in the transverse direction of the front wheel, a.sub.x.sup.T denoting the second frame acceleration in the longitudinal direction of the frame, and a.sub.y.sup.T denoting the second frame acceleration in the transverse direction of the frame.

6. The method of claim 1, wherein the three first spatial directions are orthogonal to one another, and the three second spatial directions are orthogonal to one another.

7. The method of claim 1, wherein the one-track vehicle is a motorcycle.

8. A device for ascertaining a steering angle of a one-track vehicle, comprising: a steering angle ascertaining device, including: ascertaining, with a frame sensor system attached at a first location on the frame of the vehicle, the first frame accelerations occurring there and first frame rotation rates of the two-wheeler in three first spatial directions; ascertaining, with a steering system sensor system attached at a second location on the steering system of the vehicle, the steering system accelerations of the two-wheeler occurring there in three second spatial directions; determining, based on the ascertained first frame accelerations and first frame rotation rates, second frame accelerations at the location of the second steering system sensor system in the three first spatial directions based on a mathematical relationship; and ascertaining, based on the calculated second frame accelerations and the ascertained steering system accelerations, the steering angle of the vehicle.

Description

BRIEF DESCRIPTION OF THE DRAWING

[0016] The FIGURE schematically illustrates in a top view the turned-in front wheel and the rear wheel of a one-track motor vehicle and a sensor cluster attached to the frame and to the steering column.

DETAILED DESCRIPTION

[0017] The present invention is based on a two-wheeler, on whose frame an inertial sensor system for sensing accelerations and rotation rates is located and on whose steering system at least one inertial sensor system for sensing accelerations is located. An additional steering angle sensor may be dispensed with. The method introduced hereafter is based on a comparison of acceleration components on the frame and on the steering system. The integration of rotation rates of the steering system for the determination of the steering angle, which carries with it the difficulty of an integration of the rotation rate signals typically subject to offset, may thus be eliminated.

[0018] The vehicle has an inertial sensor cluster on the frame, which is able to detect accelerations and rotation rates. On the steering system, a further sensor or a further sensor system rotating together with the steering axle, which is able to detect the accelerations in all spatial directions, is installed on the steering axle.

[0019] Hereafter, it is assumed that the sensor on the steering system, when the steering is not turned, and the sensor on the frame, are oriented in parallel to the frame. As a side note, it is mentioned that, for the case of sensors which are installed tilted or rotated, their output signals may be converted into a vehicle-parallel coordinate system with the aid of Euler's rotations.

[0020] From the accelerations and rotation rates which are detected by the sensor on the frame, the acceleration at the location of the sensor on the steering system is calculated with the aid of rigid body transformation and compared to the measured accelerations of the sensor on the steering system. The steering angle results from the comparison of the directly measured accelerations on the steering system and the transformed acceleration.

[0021] The transformation of the acceleration vector on the frame to the sensor location on the steering system reads:

[00003] $.Math. \overline{a} .Math. ? = \overline{a} .Math. ? - \dot{\overline{ω}} \times \overline{l} .Math. ? - \overline{ω} .Math. ? \times \overline{ω} \times \overline{l} .Math. ?$ $? .Math. indicates text missing or illegible when filed$

[0022] Here, text missing or illegible when filed denotes the distance vector between the sensor on the frame and the sensor on the steering system, and are the accelerations and rotation rates of the sensor on the frame. The representation of the vector ā.sup.T in the coordinate system fixed on the frame and fixed on the steering system is related to the steering angle δ via the following relationship:

[00004] $(\begin{matrix} a_{x}^{L} \\ a_{y}^{L} \end{matrix}) = (\begin{matrix} \cos .Math. .Math. δ & \sin .Math. .Math. δ \\ - \sin .Math. .Math. δ & \cos .Math. .Math. δ \end{matrix}) .Math. (\begin{matrix} a_{x}^{T} \\ a_{y}^{T} \end{matrix})$

[0023] Here, a.sub.x.sup.L and a.sub.y.sup.L denote the x and y components of the acceleration text missing or illegible when filed measured by the steering system sensor system. When negotiating curves, in general a.sub.y.sup.T≠0 applies at the location of the sensor on the steering system (a.sub.y=0 applies only in the center of gravity of the overall system driver+vehicle when negotiating curves), then this relationship may be solved, e.g., as follows for the steering angle δ:

[00005] $\sin .Math. .Math. δ = \frac{a_{y}^{T} .Math. a_{x}^{L} - a_{x}^{T} .Math. a_{y}^{L}}{a_{x}^{T^{2}} + a_{y}^{T^{2}}}$

[0024] The two prior mathematical relationships were disregarded for the sake of easier representation of the z component of text missing or illegible when filed and ,

[0025] The steering head angle τ in two-wheelers is generally not equal to zero. The effective steering angle δ.sub.eff then results from the vehicle-based steering angle δ, the steering head angle τ and the tilt φ from the relationship

[00006] $δ_{eff} \approx \frac{\cos .Math. .Math. τ}{\cos .Math. .Math. ϕ} .Math. δ$

[0026] The vehicle-based steering angle δ is the angle between the frame and the steering system. The sensor cluster on the frame is generally installed in powered two-wheelers in order to determine the tilt φ, and this variable is thus usually also available for this transformation.

[0027] FIG. 1 shows a top view onto rear wheel 100 and front wheel 101 of a one-track vehicle. Front wheel 101 is turned in to the right. Furthermore, the FIGURE shows a frame sensor system 102, which is attached to the frame of the two-wheeler and in particular detects the rotation rates and the accelerations in each case in three spatial directions orthogonal to one another. 103 denotes a steering system sensor system, which rotates together with the handlebar axle and detects the accelerations in three spatial directions orthogonal to one another. The measuring axes of the frame sensor system are denoted by x.sup.R and y.sup.R, and text missing or illegible when filed denotes the measured vectorial acceleration.

[0028] On the front wheel, the measuring axes x.sup.L and y.sup.L of the steering system sensor system rotating together with the front wheel are plotted. Furthermore, the measuring axes x.sup.T and y.sup.T of the likewise plotted second frame acceleration text missing or illegible when filed are shown. These measuring axes x.sup.T and y.sup.T form a coordinate system displaced in parallel to the measuring axes of the frame sensor system. denotes the acceleration ascertained at the location of the steering system sensor system, which is calculated with the aid of the rigid body dynamic relationship

text missing or illegible when filed
from the acceleration and rotation rate ascertained by the frame sensor system at its attachment site. Steering angle δ is not taken into consideration in the calculation of . Furthermore, steering angle δ is plotted in FIG. 1.

METHOD AND DEVICE FOR ASCERTAINING THE STEERING ANGLE OF A ONE-TRACK VEHICLE

Inventors

Cpc classification

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B62J45/414

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

G06F17/16

PHYSICS

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B62K21/00

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B62J45/42

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B60G2400/41

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B62D15/021

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

B60G2300/12

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

G01C19/5776

PHYSICS

Classification Explorer

B60G2401/904

PERFORMING OPERATIONS; TRANSPORTING

International classification

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B62D15/02

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

G01C19/5776

PHYSICS

Classification Explorer

B62K21/00

PERFORMING OPERATIONS; TRANSPORTING

Classification Explorer

G06F17/16

PHYSICS

Abstract

Claims

Description