DE10140710A1 - Angle sensor with magneto-resistive sensor elements - Google Patents

Abstract

The angle sensor for measuring an angle of rotation contains a first sensor 3a which has a first angle of rotation measuring range (eg 180 °) and a second sensor (3b) which has a larger measuring range. The first sensor is highly precise and produces a well-linear output signal, while the second sensor 3b produces less accurately and in particular a less linear output signal. The second sensor supplies an auxiliary signal that is only used to determine the period of its output signal in which the first sensor 3a lies. The first sensor is preferably a magneto-resistive rotating field sensor of the AMR type (anisotropic magneto-resistive), while the second sensor is based on the GMR effect (giant magneto-resistive) (FIG. 1).

Description

The invention relates to an angle sensor two sensors and in particular with two magnetoresistive Sensor elements according to the preamble of the claim 1.

To measure the rotational position of a rotatable component, such as B. a shaft, it is known (DE 195 06 938 A1), two mechanically coupled individual sensors use. The mechanical coupling takes place via gears, the number of teeth assigned to the two sensors Gears, for example, differs by 1. Both Sensors emit a periodic individual signal. Optical, magnetic, capacitive, inductive or resistive sensors can be used. The Difference of the measured values of both sensors, multiplied by the respective number of teeth is based on the periodicity of the Sensors standardized and in a further difference formation the measured angle determines and checks whether this Angle is negative, in which case the full Angular period is added.

DE 196 32 656 A1 describes one method and one Device for contactless detection of the position or Rotational position of an object, the two parallel tracks with magnetized increments, the number the increments are different per track, preferably by the number 1. A sensor is assigned to each track one sinusoidal and one cosine output signal depending on the relative position between the sensor and the respective increment of the track. The Phase difference of the angle values of the sinusoidal signals of both tracks gives a linear signal, but in sections is positive or negative. If this signal is negative, then becomes a constant value of two π to the difference signal added.

DE 198 49 554 C1 uses two sensors, one of which one is only used to add the period number determine and this to the current output signal of the other Add sensors. The mechanical coupling of two Sensors to extend the measuring range is also from the EP 0 386 334 and DE 197 47 753 C1 are known.

A major problem with the angle sensors mentioned is that either the measurement accuracy of the system due to the necessary mechanical coupling of the individual sensors is deteriorated (DE 195 06 938 A1 and DE 198 49 554 C1) or for a high resolution scan of magnetic standards in practice often only such Individual sensors are available, which for demanding applications are too imprecise (DE 196 32 656 A1).

The object of the invention is the angle sensor improve the type mentioned in that he with less effort an accurate measurement result over a Angle range that is larger than that Measuring angle range of one of the sensors.

This object is achieved by the specified in claim 1 Features solved. Advantageous configurations and Further developments of the invention are the subclaims remove.

The basic principle of the invention is an accurate one Sensor (e.g. an AMR sensor (anisotropic magneto-resistive)) with limited measuring range (180 °) and a second imprecise sensor (e.g. GMR sensor (Giant Magneto-Resistive)) to be used with a larger measuring range (360 °), whereby the second inaccurate sensor only serves the period of the first sensor.

In principle, the first sensor creates an ambiguous one Measurement signal, while the second sensor a clear one Measurement signal generated when the full measurement range of 360 ° or will go through more. In practice, therefore, becomes the second Sensor also have less accuracy than the first Sensor. In principle, it is also possible that both Sensors work with approximately the same measuring accuracy.

In magneto-resistive rotating field sensors, the z. B. on the AMR effect (anisotropic magneto-resistive) or the GMR effect (Giant Magneto-Resistive), the Field direction sensitivity used in the plane of the sensor element, d. H. it becomes the tangential component of the magnetic field registered (see e.g. the publication ELSEVIER, Sensors and Actuators A 91 2001) 2-6; also C.P.O. Treutler "Magnetic sensors for automotive applications"). As Control magnets come in many simple block magnets or diametrically magnetized disc magnets are used, which are rotatably supported relative to the sensor element and thereby a magnetic field with variable at the measuring location Cause direction. It is a property of the AMR Effect that only the alignment, but not that Sign of the magnetic field is recognized. As a result of this shows the output signal of the AMR angle sensor without additional auxiliary devices over a period of 180 °, d. H. a measurement uniqueness is only over half a turn of the control magnet. In contrast, one signal period with special GMR angle sensors achieve over a full revolution. Compared to one Rotary field probe based on AMR technology must be used according to the current state of technology a worse one Measurement accuracy can be accepted. With the invention on the other hand, there is the measuring accuracy of an AMR angle sensor over an extended measuring range and thus in particular also available over the full 360 °.

According to one embodiment of the invention, the first is Sensor one AMR angle sensor and the second one GMR angle sensor. The second sensor stands alone already represents an angle encoder for 360 ° Accuracy of measurement are comparatively very low Claims made. The second angle sensor can with different technologies can be realized. Conceivable is, for example, a circular, potentiometric Resistance layer that is almost a full circulation extends and with a grinder tap the sufficient Provides angle information. Preferably the second one But angle encoder is also a contactless one Field direction probe, so that the permanent magnet used can control both sensors. This is what the Use of the GMR angle sensor mentioned.

Even if in the following embodiment the AMR sensor in a gearless variant only two periods in Measuring range 360 °, it should be emphasized that the Principle of the invention on a period number greater than 2 can be expanded, for example, by the AMR sensor is provided with a transmission gear. The advantage such an arrangement is an increased resolution for the useful signal. For example, have the gears Gear ratio of 1: 2, so goes through the exact Sensor (AMR sensor) four periods of its output signal, while the other sensor only goes through one period.

In the following the invention is based on a Embodiment in connection with the drawing in more detail explained. It shows:

Figure 1 is a schematic diagram of the sensor according to the invention.

2 shows the phase angle of the two sensor signals as a function of the mechanical rotation angle in degrees. and

Fig. 3 is a diagram of the output signal of the entire angle sensor as a function of the mechanical angle of rotation and the "auxiliary signal" of the second sensor.

First, reference is made to FIG. 1. The angle sensor 1 has a permanent magnet 2 with north pole N and south pole S, which is connected to a rotatable shaft 2 a. Opposite the magnet 2 is a sensor board 3 , which is oriented so that its surface points perpendicular to the central axis of the shaft 2 a and the magnet 2 . On the sensor board 3, an angle sensor 3 a and 3 b are mounted on both sides in each case. The position of the two sensors 3 a and 3 b is chosen so that they are aligned with their centers with the axis of rotation of the shaft 2 a.

The first sensor 3a is a high-accuracy sensor, such as an "AMR-sensor" having an output signal having a first period, here a period of 180 °. In contrast, the second sensor 3 b is a less precise sensor, for example a GMR sensor, the output signal of which has a second period, here 360 °, which is therefore larger and in particular an integer multiple of the period of the first sensor 3 a.

Both sensors 3 a and 3 b are connected to evaluation electronics 4 , which here have two inputs 4 a and 4 b and one output 4 c.

Fig. 2 shows a diagram of the output signals of the two sensors. The solid line is the output signal of the first sensor 3 a appearing at the input 4 a, which is shown here as strictly linear and highly accurate and has a period of 180 °. The second illustrated in phantom signal is the signal of the sensor 3 b 4 b at the input, which is less accurate and contrast increases while substantially monotonically, but has a significant non-linearity. But it is over the full measuring range of 360 °. Based on this signal, even in the case of major inaccuracies, it can be readily determined whether the output signal of the first sensor 3 a is in the first period from 0 to 180 ° or the second period from 180 to 360 °. For this purpose, for example, the output signal of the second sensor 3 b can be compared with a preset limit value, for example running over a threshold switch. If the signal is greater than the set threshold value, the value of 180 ° is added to the output signal of the first sensor 3 a. In order to maintain the accuracy even in the border area close to 180 °, the signal of the first sensor 3 a is also evaluated for the decision as to whether 180 ° is added or not. In a first step, the numerical value n × 180 ° is added to the output signal of the first sensor 3 a and the result is compared with the signal of the second sensor 3 b standardized to the same value range. If the deviation is too large, the integer n is then corrected accordingly in a second step. In the further course, a simple comparator is then sufficient, which determines whether the output signal of the second sensor is greater than 180 ° + x. In this case, 180 ° is always added to the output signal of the first sensor 3 a.

Fig. 3 shows as a solid line the output signal at the output 4 c and in comparison the inaccurate, non-linear output signal of the second sensor 3 b, which is referred to here as an "auxiliary signal". The increase in measuring accuracy can be clearly seen here.

Claims (6)

1. Angle sensor with two sensors, each of which generates a periodic output signal, the output signals of the two sensors having a different number of periods in the measuring range, characterized in that
that the first sensor ( 3 a) is a highly accurate sensor that generates a larger number of periods of its output signal in the measuring range than the second sensor ( 3 b),
that the second sensor ( 3 b) can be less accurate than the first sensor and generates a clearly lower output signal with only one signal period in the measuring range and
that the output signal of the second sensor ( 3 b) is evaluated to determine the current number of periods of the first sensor ( 3 a). 2. Angle sensor according to claim 1, characterized in that the first sensor ( 3 a) is a magneto-resistive rotating field sensor which is based on the effect of anisotropic magnetoresistive elements and has a periodicity of 180 ° by evaluating the field direction sensitivity in the plane. 3. Angle sensor according to claim 2, characterized in that the second sensor ( 3 b) is a magneto-resistive rotating field sensor which is based on the GMR effect (giant magneto-resistive) and has a measuring range of 360 °. 4. Angle sensor according to one of claims 1 to 3, characterized in that at least one of the sensors ( 3 a, 3 b) is coupled by means of a gear to a component ( 2 a), the angular position of which is to be measured, the gear ratio of the gear is selected so that the two sensors are rotated with different transmission ratios. 5. Angle sensor according to one of claims 2 to 4, characterized in that a control magnet ( 2 ) with the component ( 2 a), the rotational position of which is to be measured, is connected, the control magnet ( 2 ) generating a magnetic field which is relative to (a, 3 b 3) generates at least one of the sensors as a function of the rotational position of a magnetic field of variable direction. 6. Angle sensor according to claims 2 and 3, characterized in that both sensors ( 3 a, 3 b) on a common circuit board ( 3 ) are attached so that their centers are aligned with the axis of rotation of the component ( 2 a) and that the axis of rotation of the component ( 2 a) is perpendicular to the board.