DE102006032280B4 - Inclination - Google Patents

Abstract

Inclinometer (10), containing acceleration measuring means with two mutually perpendicular input axes (x, y) which define a third axis (z) perpendicular to the input axes, the acceleration measuring means delivering measurement signals according to the accelerations in the direction of the two input axes and the third axis (z) is arranged perpendicular to the direction of the acceleration due to gravity, furthermore (a) means for determining the quadrant of an inclination angle (φ) of the accelerometer about the third axis (z) from the two measurement signals of the accelerometer and (b) means for Determination of the angle of inclination from the two measurement signals and from the particular quadrant are present, (c) the angle of inclination is the angle between one of the input axes (x) and a horizontal, characterized in that (d) the means for determining the quadrant means (26 ) included to determine whether the sine of the angle of inclination (φ) is greater than the cosine de s angle of inclination or whether the cosine is negative if the sine and cosine are equal, the angle of inclination being between> 45 ° and ≤ 225 ° in the presence of these conditions in the second or third quadrant and in the absence of these conditions in the first or fourth quadrant ≤ 45 ° or > 225 °, (e) the means for determining the quadrant furthermore contain means (38) for the second and third quadrants for determining whether the absolute value of the sine of the angle of inclination is greater than the absolute value of the cosine of the angle of inclination, if this is present Condition of the angle of inclination (φ) in the second quadrant and, if this condition is not met, the angle of inclination (φ) is in the third quadrant, and (f) the means for determining the quadrant further comprise means (36) for determining whether for the first and fourth quadrants the absolute value of the sine of the inclination angle is greater than the absolute value of the cosine of the inclination angle, where b If this condition is met, the angle of inclination (φ) is in the fourth quadrant and if this condition is not met, the angle of inclination (φ) is in the first quadrant.

Description

• (a) Mittel zur Bestimmung des Quadranten eines Neigungswinkels (φ) des Beschleunigungsmessers um die dritte Achse (z) aus den beiden Messsignalen des Beschleunigungsmessers und
• (b) Mittel zur Bestimmung des Neigungswinkels aus den beiden Messsignalen und aus dem bestimmten Quadranten vorhanden sind,
• (c) der Neigungswinkel der Winkel zwischen einer der Eingangsachsen (x) und einer Horizontalen ist.

The invention relates to an inclinometer comprising an accelerometer having two mutually perpendicular input axes (x, y) defining a third axis (z) perpendicular to the input axes, the accelerometer providing measurement signals in accordance with the accelerations in the direction of the two input axes and the third Axis (z) is arranged perpendicular to the direction of gravitational acceleration, wherein further

• (A) means for determining the quadrant of an inclination angle (φ) of the accelerometer about the third axis (z) from the two measuring signals of the accelerometer and
• (b) there are means for determining the angle of inclination from the two measuring signals and from the specific quadrant,
• (c) the angle of inclination is the angle between one of the input axes (x) and a horizontal.

In known inclinometers with biaxial accelerometers, the input axes x and y in the initial state are both in a horizontal plane. A third axis z, which is perpendicular to the two input axes, is arranged vertically. Upon rotation of the tilt sensor by an angle α about the input axis x, the input axis y provides a measurement signal a _x = g sinα, where g is the acceleration due to gravity. Upon rotation of the tilt sensor by an angle β about the input axis y, the input axis x delivers a measurement signal a _y = g sinβ. The measuring range of such an arrangement is purely theoretical ± 90 °. Due to the limited resolution of the measured accelerations, however, the real measuring range is considerably smaller. The angular resolution is proportional to the cosine of the angle. Thus, the angular resolution at 60 ° is only half the angular resolution at 0 °. At 90 ° the angular resolution is zero.

Another disadvantage of this inclination angle measurement is that accelerations of the inclination sensor in the direction of the input axes greatly falsify the measurement result. If z. B. the inclination sensor is oriented so that the input axes x and y lie in the horizontal plane, and is accelerated translationally with 1 g in the x or y direction, the measurement error is 90 °.

In the publication EP 48 212 A1 a course attitude reference device with a position gyroscope is disclosed. The spin axis of the position gyroscope is substantially horizontal and thus aligned perpendicular to the direction of gravitational acceleration. Furthermore, a total of four inclination sensors are described, which may be formed by acceleration sensors. Two inclination sensors each are arranged with mutually perpendicular input axes in a plane. This makes it possible to determine the inclination of the plane with respect to the horizontal, ie the roll angle and the pitch angle of the plane. It is based on small pitch and roll angles, which lie in the first or fourth quadrant. A third axis, which is perpendicular to the two input axes, is oriented substantially vertically, that is to say parallel to the gravitational acceleration. Also in the EP 48 212 A1 a measurement of an inclination angle of ± 90 ° or more with the inclination sensors described is not provided. Rather, it is assumed that small angles of inclination and thus the quadrant of the angle of inclination a priori fixed on the first or fourth quadrant.

The publication US 2003/0158699 A1 describes a sensor for detecting orientation. In particular, the sensor has three mutually orthogonal accelerometers which determine pitch, roll and yaw angles relative to the earth's magnetic field or gravitational field. The pitch angle can be resolved over an angular range of 360 °.

The publication DE 197 19 564 A1 discloses a device for determining a rotation angle of a shaft, wherein a quadrant is determined from a sine and a cosine signal of an angle sensor and with the sign selected according to the slope of the signals in the quadrant, the angular position of the signals is represented by summation and offset addition ,

The invention is based on the object to provide an acceleration-measuring inclinometer, which allows an angle measurement over a large angular range, preferably over 360 °.

• (d) die Mittel zur Bestimmung des Quadranten Mittel (26) enthalten zur Feststellung, ob der Sinus des Neigungswinkels (φ) größer ist als der Kosinus des Neigungswinkels oder ob bei Gleichheit von Sinus und Kosinus der Kosinus negativ ist, wobei der Neigungswinkel bei Vorliegen dieser Bedingungen im zweiten oder dritten Quadranten zwischen > 45° und ≤ 225° liegt und bei Nichtvorliegen dieser Bedingungen im ersten oder vierten Quadranten ≤ 45° oder > 225° liegt,
• (e) die Mittel zur Bestimmung des Quadranten weiterhin für den zweiten und dritten Quadranten Mittel (38) enthalten zur Feststellung, ob der Absolutbetrag des Sinus des Neigungswinkels größer ist als der Absolutbetrag des Kosinus des Neigungswinkels, wobei bei Vorliegen dieser Bedingung der Neigungswinkel (φ) im zweiten Quadranten und bei Nichtvorliegen dieser Bedingung der Neigunkungswinkel (φ) im dritten Quadranten liegt, und
• (f) die Mittel zur Bestimmung des Quadranten ferner für den ersten und vierten Quadranten Mittel (36) enthalten zur Feststellung, ob der Absolutbetrag des Sinus des Neigungswinkels größer ist als der Absolutbetrag des Kosinus des Neigungswinkels, wobei bei Vorliegen dieser Bedingung der Neigungswinkel (φ) im vierten Quadranten und bei Nichtvorliegen dieser Bedingung der Neigungswinkel (φ) im ersten Quadranten liegt.

According to the invention this object is achieved with a tilt sensor of the type mentioned in that

• (d) the means of identification of the quadrant ( 26 ) to determine whether the sine of the angle of inclination (φ) is greater than the cosine of the angle of inclination or whether the sine and cosine are equal, the cosine is negative, the angle of inclination in the presence of these conditions in the second or third quadrant between> 45 ° and ≤ 225 ° and in the absence of these conditions in the first or fourth quadrant ≤ 45 ° or> 225 °,
• (e) the means for determining the quadrant continue to be used for the second and third quadrant 38 ) for determining whether the absolute value of the sine of the inclination angle is larger than the absolute value of the cosine of the inclination angle, and in the presence thereof Condition of the inclination angle (φ) in the second quadrant and, in the absence of this condition, the inclination angle (φ) in the third quadrant, and
• (f) the means for determining the quadrant further for the first and fourth quadrant means ( 36 ) to determine whether the absolute value of the sine of the inclination angle is greater than the absolute value of the cosine of the inclination angle, wherein in the presence of this condition, the inclination angle (φ) in the fourth quadrant and in the absence of this condition, the inclination angle (φ) in the first quadrant.

In such an arrangement, upon rotation of the inclination transducer about the angle φ about the "third" axis (z), the two input axes x and y provide measurement signals a _x = g cosφ a _y = g sinφ.

The measurement signals are thus proportional to the cosine or the sine of the rotation angle. The cosine and sine are positive or negative depending on the quadrant of the rotation angle. From the combination of these measurement signals can therefore be concluded on the quadrant of the rotation angle. From the measurement signals, the rotation angle can be calculated taking into account the quadrant. By adding suitable fixed offset values, an output signal can then be generated which provides an unambiguous measure of the angle of rotation over an angular range of 360 °.

Embodiments of the invention are the subject of the dependent claims.

An embodiment of the invention is explained below with reference to the accompanying drawings.

1 is a schematic perspective view and shows a tilt sensor with two mutually perpendicular input axes x and y and a vertical to the two input axes third axis z.

2 shows the rotation of the tilt sensor of 1 around the horizontally arranged third axis z.

3 is a diagram showing the measurement signals and their conditions occurring when the tilt sensor rotates through 360 ° on the input axes

4 is a flowchart showing the signal processing for determining the quadrant.

5 is a diagram showing the output of the tilt sensor depending on the angle of rotation.

In 1 is with 10 a tilt sensor called. The inclinometer 10 is constructed with acceleration measuring devices. The acceleration measuring means are preferably formed by a biaxial acceleration sensor. The acceleration measuring means have two mutually perpendicular input axes x and y. They measure the accelerations in the direction of the input axes x and y. These are usually the components of the gravitational acceleration g. Perpendicular to the two input axes x and y, a third axis z is defined.

According to the invention, the third axis z extends horizontally. The inclinometer 10 is rotatable about this axis z. The rotation angle φ should be measured around the axis z. In the initial state, the input axis x also extends horizontally. The other input axis y runs vertically in the direction of acceleration due to gravity. The angle φ is the angle by which the input axis x has rotated out of the horizontal about the axis z. Is in 2 shown. At the input axes x and y, components of the gravitational acceleration are measured a _x = g cosφ a _y = g sinφ.

The components are thus proportional to the cosine or the sine of the rotation angle φ.

In 3 is the course of the cosine and sine through the curves 12 respectively. 14 shown. The cosine and sine functions are ambiguous over 360 °. From the values or signs of both angular functions but the quadrant can be determined, in which the angle of rotation is located.

In 3 Four quadrants QI, QII, QIII and QIV are defined
Quadrant QI from 315 ° to 45 °
Quadrant QII from 45 ° to 135 °
Quadrant QIII from 135 ° to 225 °
Quadrant QIV from 225 ° to 315 °

In 3 Furthermore, the ratio of the accelerations on the two input axes is shown, which corresponds to the tangent or the Kotangens the rotation angle. In the first quadrant QI of 3 is curve 16 the tangents of the rotation angle φ. Curve 18 in 3 gives the Kotangens the rotation angle φ again. In the third quadrant QIII gives curve 20 again the tangent of the angle of rotation φ again, and in the fourth quadrant QIV shows curve 22 again the tangent of the angle of rotation φ.

From the trigonometric functions sine and cosine the quadrant can be determined, in which the angle of rotation lies. This is in the flowchart of 4 shown.

Enter sinφ and cosφ. Is in 4 through block 24 shown. Next, it is checked whether the condition (sinφ> cosφ) or (sinφ = cosφ and cos <0) is satisfied. Is in 4 through block 26 shown.

If this is the case (j), the angle of rotation φ lies in the second quadrant QII or in the third quadrant QIII, ie> 45 ° and ≤ 225 3 Verify: The curve runs between 45 ° and 225 ° 14 of the sinus above the curve 12 of the cosine. If sine and cosine are the same, namely in the points 28 at 45 ° and 30 at 225 ° from 3 , the cosine must be negative, which in point 30 the case 151 , The value 225 ° is still in the third quadrant QIII, while the value 45 ° is not yet in the second quadrant QII.

If the condition is not fulfilled, the angle of rotation φ lies either in the first quadrant QI or in the fourth quadrant QIV, ie, either ≤ 45 ° or> 225 °. Also that one can by means of 3 Verify: In the fourth quadrant QIV for values> 225 ° to 315 °, the curve runs 12 of the cosine above the curve 14 of the sinus. The same applies to the first quadrant QI for values of 315 (left in 3 ) up to 45 °. In the point 28 the cosine is positive, not negative. The value 45 ° belongs to the first quadrant QI. In the point 30 the cosine is negative. The point 225 therefore does not belong to the fourth quadrant QIV.

From the two signals of the input axes x and y thus the rotation angle φ is limited to two quadrants. Is in 4 through the blocks 32 and 34 shown.

It will now both in a result according to block 32 as well as a result according to block 34 checked whether the absolute value of the sine is greater than the absolute value of the cosine, ie | Sinφ | , | cosφ |,

Is in 4 through the rhombs 36 respectively. 38 shown. If a restriction according to block 32 has occurred, then the angle of rotation φ is in the presence of this condition according to rhombus 36 (j) in the fourth quadrant QIV, ie> 225 ° and <315 °. If the condition is not fulfilled (n), the angle of rotation lies in the first quadrant QI, ie ≥ 315 ° and ≤ 45 °. Is in 4 through the blocks 41 ) respectively. 42 shown with a restriction according to block 34 is the rotation angle φ in the presence of the condition according to rhombus 38 (j) in the second quadrant QII, ie> 45 ° and <135 °. Is the condition according to rhombus 38 not satisfied (n), then the rotation angle φ in the third quadrant QIII, ie ≥ 135 ° and ≤ 225 °. Is in 4 through blocks 44 respectively. 46 shown.

That can be attached again by 3 be verified. In the fourth quadrant, the absolute value of the sine (curve 14 ) greater than the absolute value of the cosine (curve 12 ). In the first quadrant QI, the absolute value of the sine (curve 14 ) is smaller than the absolute value of the cosine (curve 12 ). In the second quadrant QII the absolute value of the sine (curve 14 ) greater than the absolute value of the cosine (curve 12 ). In the third quadrant QIII this is not the case: there is the absolute value of the cosine (curve 12 ) greater than the absolute value of the sine (curve 14 ).

In this way, the quadrant of the rotation angle φ is clearly defined.

As a next step, depending on the detected quadrant, the tangent or cotangent functions obtained for the different quadrants with a suitable offset in Qrdinaten are set together in such a way that an output signal which changes approximately linearly with the angle of rotation φ results.

Depending on the detected quadrant, the output signal is selected as follows:
Quadrant QI: 1 + (sinφ / cosφ)
Quadrant QII 3 - (cosφ / sinφ)
Quadrant QII 5 + (sinφ / cosφ)
Quadrant QIV 7 - (cosφ / sinφ)

This results in an angle-dependent output signal 48 , as it is in 5 is shown. The curves 12 to 22 are down in 5 marked with.

If, for example, by the signal processing according to 4 If it is determined that the rotation angle φ is in the third quadrant QIII, then the ratio corresponding to the tangent of the rotation angle is formed from the signals obtained at the input axes x and y. This ratio corresponds to curve 20 in 3 , The (positive or negative) tangent becomes the number 5 added. This results in an output signal according to curve 48 that is uniquely associated with the angle φ. Thus, a measured value in the range of 0 ° to 360 ° is available. The characteristic 48 has a linearity error. This linearity error can be compensated by addition or subtraction of correction values.

Another advantage of the tilt sensor described is that accelerations in the direction of the input axes x or y falsify the measurement result less than in the known inclination sensors mentioned above. For example, if the inclinometer is accelerated perpendicular to the z-axis at 1 g, then the measurement error is only 45 °.

Claims (2)

Inclinometer ( 10 ), comprising acceleration measuring means with two mutually perpendicular input axes (x, y), which define a third axis (z) perpendicular to the input axes, wherein the acceleration measuring means supply measuring signals in accordance with the accelerations in the direction of the two input axes and the third axis (z) is arranged perpendicular to the direction of gravitational acceleration, further comprising (a) means for determining the quadrant of an inclination angle (φ) of the accelerometer about the third axis (z) from the two measuring signals of the accelerometer and (b) means for determining the inclination angle (c) the angle of inclination is the angle between one of the input axes (x) and a horizontal, characterized in that (d) the means for determining the quadrant mean (d) 26 ) to determine whether the sine of the angle of inclination (φ) is greater than the cosine of the angle of inclination or whether the sine and cosine are equal, the cosine is negative, the angle of inclination in the presence of these conditions in the second or third quadrant between> 45 ° and ≤ 225 ° and in the absence of these conditions in the first or fourth quadrant ≤ 45 ° or> 225 °, (e) the means for determining the quadrant continue to be used for the second and third quadrant means ( 38 ) for determining whether the absolute value of the sine of the inclination angle is greater than the absolute value of the cosine of the inclination angle, in which case the inclination angle (φ) in the second quadrant and in the absence of this condition the inclination angle (φ) in the third quadrant, and (f) the means for determining the quadrant further for the first and fourth quadrant means ( 36 ) to determine whether the absolute value of the sine of the inclination angle is greater than the absolute value of the cosine of the inclination angle, wherein in the presence of this condition, the inclination angle (φ) in the fourth quadrant and in the absence of this condition, the inclination angle (φ) in the first quadrant. Inclination sensor according to claim 1, characterized in that by the means for determining the inclination angle (φ) from the two measurement signals taking into account the quadrant, an output signal is generated, in the first quadrant 1 + (sin φ / cos φ) in the second quadrant 3 - (cos φ / sin φ) in the third quadrant is 5 + (sin φ / cos φ) in the fourth quadrant 7 - (cos φ / sin φ).

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