EP1671081A1

EP1671081A1 - Method and circuit arrangement for determining a quality level of phase signals

Info

Publication number: EP1671081A1
Application number: EP04762534A
Authority: EP
Inventors: Axel Wenzler
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2003-10-01
Filing date: 2004-07-28
Publication date: 2006-06-21
Also published as: US7340345B2; DE10345729A1; CN1860347B; AU2004286016B2; CN1860347A; WO2005043086A1; AU2004286016A1; US20060116822A1

Abstract

The invention relates to a method and a circuit arrangement for evaluating phase signals for determining an angle or a path of a linearly or rotatably displaced component, whereby a number (N) of phase measuring values (<), produced by scanning at least one phase-emitting arrangement on the linearly or rotatably displaced component by means of a respectively associated sensor, are evaluated. According to the invention, once the phase measuring values (a) have been transformed with a matrix (M1), a quality level (R) is determined by producing a vector (T) followed by the result of a quantisation operation (V) relating to the vector (T). Once another transformation has been carried out with another matrix (M4), another vector (X) is produced from the difference (t) between the vector (T) and the result of the quantisation operation (V), coefficients (Cj) and (Dj) being applied to the constituents (xj) of said other vector, and the quality level (R) is derived therefrom.

Description

Method and circuit arrangement for determining a quality measure of phase signals

State of the art

The invention relates to a method and a circuit arrangement for determining a quality measure of phase signals, in particular when detecting a movement or a rotation angle or a torque on axes or shafts, according to the preamble of the main claim.

For example, to detect the torque acting on a steering wheel axle of a motor vehicle, very small changes in angle in both directions of rotation of the steering wheel must be measured during the rotation of the steering wheel. Incremental angle encoders can be used here, which assign a phase measurement value to an angular position based on the evaluation of optically, magnetically or otherwise as a result of the signals generated and detected by suitable means. To increase the uniqueness range, it is possible to view at least one further measuring channel with a different phase slope. There So there are several phase measurements here. from which the quantity to be measured, such as the angle of rotation, an angle difference or the distance to a target, is to be determined.

In the case of more than two phase signals, for example, a method described in DE 101 42 449 AI is proposed for evaluating such phase measured values. There, from a number N of ambiguous, disturbed phase signals, a highly precise, robust and unambiguous phase or angle measured value is generated. For this purpose, the measured phase values are arithmetically transformed using a linear transformation method and evaluated with a predetermined weighting.

The method is used, for example, in an optical angle sensor in which N parallel tracks are applied to a cylinder. Each of the N tracks (i = 1 ... N) contains n _± periods of phase information, which is represented, for example, in the optical case by n _± periods of light-dark transitions. Other sensor principles, for example magnetic or capacitive, are also possible here. The traces of the sensor can also be applied on one level instead of on a cylinder, for example in the case of a displacement sensor.

It is also known from DE 195 06 938 AI that the phase signals can be evaluated by the simple or multiple use of a classic or modified vernier method.

Furthermore, to determine an angle difference from DE 101 42 448 AI, it is also known that the phase measurement values are added up in a weighted manner and the integral and non-integral part is then determined therefrom. The non-integer part is proportional to the angular difference between two track groups of an incremental encoder on a shaft, so that the torque on the shaft can be determined by multiplying by the spring rate of a torsion bar connected between the track groups.

From DE 100 34 733 AI, it is also known per se that in an initialization phase, a predetermined offset value is added to the phase measurement value, and the offset value is in turn adapted from this. An iterative approximation method for offset adjustment of two orthogonal sensor signals is still known per se from DE 199 15 968 AI.

The generic method can be used, for example, with a corresponding sensor arrangement, as described in the aforementioned DE 101 42 448 AI, on the steering shaft of a vehicle as a so-called torque angle sensor (TAS), in which the steering angle and the steering torque are output simultaneously should.

Advantages of the invention

With the generic method mentioned at the outset for detecting, for example, the angle of rotation and / or the torque on rotating mechanical components, phase measurement values can be evaluated by scanning at least one phase encoder on the rotating component by means of a respectively assigned sensor. According to the invention, a determination of a quality measure for the phase signals is advantageously carried out in that after a transformation of the phase measured values with a predetermined one Matrix a vector and the result of a quantization operation with respect to the vector is generated and then another vector is generated from the difference between the vector and the result of the quantization operation after a transformation with a further matrix. The absolute minimum is then formed from the components of the further vector and the quality measure is derived from this.

The quality measure can be determined in a particularly advantageous manner according to the following relationship:

R - e "= min, _," ΛD _t ± x. - C

the quantities C _j and Dj represent coefficients that can be derived from the phase signals. The application of the coefficients C _j and Dj and the transformation of the vector with the further matrix can also be summarized in a simple manner in one process step.

The method according to the invention can advantageously be implemented with a circuit arrangement which is formed from an electronic circuit and has a linear mapping module for processing the phase signals and a quantization module. With a further linear mapping module, the additional vector can be generated from the difference between the vector at the output of the first linear mapping module and the result of the quantization operation at the output of the quantization module, which vector can be loaded with the coefficients.

With the method and the circuit arrangement according to the invention, a scaled quality measure can thus advantageously be determined for assessing the relationship between the individual phase measurement values. With help This measure then makes it possible to identify faults and incorrect measurements of the sensor system. The invention thus enables the entire sensor system to be monitored, since such an assessment of the overall system was previously not possible. For example, an inclination of the sensor head compared to the sensor tracks due to a so-called tilt angle causes a significant reduction in the quality measure. Furthermore, the invention provides a method and a circuit arrangement for determining the quality measure with little expenditure on software and / or hardware in an electronic circuit, since the calculation of the quality measure does not initially require the calculation of the absolute angle values.

drawing

An embodiment of a circuit arrangement for performing the method according to the invention is explained with reference to the drawing. Show it:

Figure 1 is a schematic view of a circuit arrangement for detecting the angle of rotation of an axis or shaft by evaluating phase signals and the arrangement for determining the quality measure and

FIG. 2 shows the phase signals after a transformation and quantization into a two-dimensional space. Description of the embodiment

FIG. 1 shows a block diagram of a circuit arrangement for detecting the angle of rotation of an axis or shaft by evaluating phase signals α, which are taken, for example, from an axis of a rotating component, the angle of rotation φ and the angle difference of which can be determined using a corresponding sensor arrangement. Such an arrangement is known in principle from DE 101 42 448 AI mentioned as prior art in the introduction to the description. It is known from DE 101 42 449 AI, also mentioned in the introduction to the description, that the following equation applies to phase signals oci in the case of an angle sensor with N phase signals:

The size Φ is the absolute angle searched for in the measurement task, whereby the same relationships also apply to a linear displacement sensor. Ideal measurement values are assumed, ie there are basically no measurement errors. The method according to the invention is then described using a four-dimensional phase evaluation (N = 4) of the signals from optical signal transmitters. From this, the angular position ggf. _m and, if necessary, the torque of the shaft or axis can then be determined using the other components.

In detail, according to FIG. 1, a linear mapping module M1 for transforming the phase signals with a A matrix Mi is present in a vector T and a quantization module V for generating a quantization operation V. This is followed by a further linear mapping module M3 for transformation with a matrix M ₃ and an operation with an od 2 ¹⁶ module, likewise known from the prior art, takes place, taking into account the output signal of a weighting module W for the phase signals α in order to obtain the angular position stellung ,

The starting point for calculating the quality measure R according to the invention are the phase values themselves or a determination according to equation (2) below from the difference t between the vectors T and V, which as intermediate values of the multidimensional phase evaluation according to the prior art DE 101 42 449 AI in the In principle, the usual circuit arrangements are available here. _ t = T - V = T - quant (T) (2)

This N-1 dimensional difference t is mapped into a vector X using a matrix M4 according to FIG. 1 in a linear mapping module M4:

X = M ₄ -_t (3)

The matrix M4 consists of

Lines. The components X _{j of} the vector X_ are then multiplied in a module C by coefficients C _j . Further n _x coefficients Dj are then added or subtracted to the result. From the 2n _x values obtained in this way, the value-based ge minimum formed. This minimum has value

The value e _max is the error permitted in all N phase values at the same time; e _max depends on the dimension and the special choice of the period numbers nj. The calculation sequence for the aforementioned quantities can be found in principle for example for N = 4 dimensions from the signal flow graph shown in FIG. 1. The circuit arrangement for other dimensions N is basically identical, only the specified number of signal lines changes.

In a numerical example with N = 3 phase signals, the following values are assumed, for example: nι = 3, n ₂ = 4, and n ₃ = 5. The starting point is the values according to equation (2). The matrices Mi and M ₄ are in this case:

and the coefficients C _j and D _j each with j = 1 ... 3 then have the values:

c = - ^l c = - c = - ^l £> _! = -, D ₂ = -, D ₃ = - ¹ 7 ² 8 6

For ideal phase signals according to equation (1), R = 1 and

R-e_ = 45 ° For example, if all phase signals ± are shifted by 180 ° as an inverse pattern, the quality measure is R = 0.

The quality measure R calculated using the previously described method specifies how much noise or which measurement error can still be permitted based on the current phase measurement value, so that the desired functionality can be guaranteed. In an example of N = 3 dimensions after a transformation into a two-dimensional t-space, FIG. 2 shows the range limits BG for the phase measurement values in the t-space as vectors t. The possible locations of the noise for a correct result are limited here with the area RB.

The noise is typically related to the value e _max . This means that for ideal phase values according to the relationship (1), R = 1 applies and the current measured value is therefore at the starting point of the vector t. If the current measured value lies exactly on a range limit BG of the quantization unit V according to FIG. 1, the quality measure R assumes its minimum value R = 0.

Claims

Claims ¹

1) Method for evaluating phase signals to determine an angle or path on a linearly or rotationally moving component, in which - a number (N) phase measurement values (α) are evaluated, which are obtained by scanning at least one phase encoder arrangement on the linearly or rotationally moving component of a respectively assigned sensor and in which - the phase measurement values (α) are mathematically transformed into a new area by means of a linear transformation, characterized in that - a quality measure (R) is determined in that after a transformation of the phase measurement values (α ) with a matrix (Mi) a vector (T) and then the result of a quantization operation (V) with respect to the vector (T) is generated that - from the difference (t) from the vector (T) and the result of the quantization operation (V) after a transformation with a further matrix (M ₄ ) a further vector (X) is generated and that - from the components (XJ) of the further vector (X) the minimum amount is formed and the quality measure (R) is derived from this. 2) Method according to claim 1, characterized in that

- The quality measure (R) is determined according to the following relationship: the quantities (C _j ) and (D _j ) represent coefficients which can be derived from the phase signals.

3) Method according to claim 2, characterized in that

- The application of the coefficients (C _j ) and (D _j ) and the transformation of the vector (X) with the further matrix (M ₄ ) are combined in one process step.

4) Circuit arrangement for carrying out a method according to one of the preceding claims, characterized in that - an electronic circuit with a linear mapping module (Ml) for processing the phase signals (α) with a matrix (Mi) and with a quantization module (V) is and that - with a linear mapping module (M4) from the difference (t) from the vector (T) at the output of the linear mapping module (Ml) and the result of the quantization operation (V) at the output of the quantization module (V) the other Vector (X) can be generated the coefficients (C _j ) and (D _j ) can be applied in further components (C, D).