WO2017125366A1 - Method for adapting an echo threshold curve for an ultrasound sensor of a motor vehicle - Google Patents

Abstract

The invention relates to a method for operating an ultrasound sensor (4) of a motor vehicle (1), in which a predetermined threshold value curve (10) having a distance-dependent curve of threshold values (S1, S2, S3) is provided for the ultrasound sensor (4), with which threshold value curve an amplitude (A) of a receive signal received by the ultrasound sensor (4) for measuring a distance between the motor vehicle (1) and an object (9) located in a surroundings area (8) of the motor vehicle (1) is compared, wherein, to increase a sensitivity of the ultrasound sensor (4), at least one threshold value (S1, S2, S3) of the threshold value curve (10) is decreased after detecting the presence of the object (9) in the surrounding area (8). The invention also relates to an ultrasound sensor device (3), to a driver assistance system (2) and to a motor vehicle (1).

Description

 METHOD FOR ADAPTING AN ECHO THRESHOLD PERFORMANCE FOR A ULTRASONIC SENSOR OF A MOTOR VEHICLE

The invention relates to a method for operating an ultrasonic sensor of a motor vehicle, wherein for the ultrasonic sensor, a predetermined, a distance-dependent course of threshold values having threshold curve is provided, with which an amplitude of the ultrasonic sensor for measuring a distance between the motor vehicle and in a

 Received surrounding area of the vehicle object

 Receive signal to be compared. The invention also relates to a

 Ultrasonic sensor device, a driver assistance system and a motor vehicle.

The interest here is directed to an ultrasonic sensor, by means of which distances between a motor vehicle and objects located in its surroundings can be measured. The objects detected by the ultrasonic sensor and their distances can be provided to a driver assistance system of the motor vehicle, for example a parking assistance assistant. Ultrasonic sensors work according to the echo delay principle. This means that a transmission signal in the form of a

 Transmitted ultrasonic signal, the transmission signal is reflected in the surrounding area of the motor vehicle and is received as a received signal again from the ultrasonic sensor. As a rule, the received signal has a multiplicity of echoes which originate from reflections in the surrounding area. The echoes can be so-called target echoes which originate from a reflection of the transmission signal at an object, or be clutter echoes or ground echoes which originate from a reflection of the transmission signal at a floor or a lane of the motor vehicle.

In order to assess whether the echoes in the received signal are target echoes or ground echoes, it is known from the prior art, so-called

 Specify threshold curves with which amplitudes of the echoes in the

 Receive signal to be compared. Due to the threshold curve, a

Sensitivity of the ultrasonic sensor can be adjusted. If the amplitude of an echo is greater than the threshold curve, then the echo is interpreted as a target echo and evaluated. If the amplitude of an echo is smaller than the threshold curve, it will Echo interpreted as a false echo or ground echo, which is to be filtered out or hidden.

Such an ultrasonic sensor, in which the amplitude of a received signal and a measured distance value are available for distinguishing between relevant and irrelevant signals, are described in EP 1 296 159 B1. It is also known from DE 10 2005 059 907 A1 to store a data field in a memory, through which support points or interpolation points of

Threshold curve are given. A temporal location of the bases of the

Threshold curve can be changed depending on the operating conditions of the ultrasonic sensor or environmental conditions.

As a rule, the threshold curve is specified as a distance-dependent or transit time-dependent profile of threshold values. In a distance range in which floor echoes are known to occur, correspondingly high threshold values are predetermined, so that the ultrasonic sensor has a reduced or lower sensitivity in this area. The low one

Sensitivity of the ultrasonic sensor, however, may result in objects which, in a distance range in which the ultrasound sensor has low threshold values and thus high sensitivity, being able to be recognized without difficulty in particular being weakly reflective, no longer being detected in that distance range with the reduced sensitivity can.

It is an object of the present invention to provide a solution, as objects in a surrounding area of a motor vehicle can be detected particularly reliable.

This object is achieved by a method, a

 Ultrasonic sensor device, a driver assistance system and a motor vehicle according to the independent claims solved. Advantageous embodiments of the invention are subject of the dependent claims, the description and the figures.

An inventive method is used to operate an ultrasonic sensor of a motor vehicle. In the method, a predetermined threshold value curve having a distance-dependent variation of threshold values is provided for the ultrasonic sensor, with which an amplitude of one of the ultrasonic sensor for measurement a distance between the motor vehicle and a received in an environment region of the motor vehicle object received signal to be compared. In addition, to increase a sensitivity of the ultrasonic sensor, at least a threshold value of the threshold curve is lowered after detecting the presence of the object in the surrounding area.

From the ultrasonic sensor is used to detect the object in the

Surrounding area receive the received signal. The received signal has a distance-dependent or transit-time-dependent profile. This means that the received signal has a multiplicity of echoes, each echo being based on its position in the received signal in each case one transit time and thus one

Distance in the environment area can be assigned. In order to determine whether an echo in the received signal originates from a reflection at the object or from a reflection at an impurity, for example from a ground reflection, an amplitude of the echo, in particular a maximum of the echo, with the

distance-dependent or transit time-dependent threshold value curve. The threshold curve is a distance in the surrounding area

or a running time associated with a threshold value. In this case, each echo is compared with that threshold value of the threshold curve which is associated with the distance corresponding to the echo. When the amplitude of the echo exceeds the associated threshold, the echo is characterized as a target echo, that is, from a reflection on an object. Then the echo can be evaluated to determine the distance of the object. The distance of the object is determined as the distance at which the echo in the distance-dependent

Receive signal occurs. If the amplitude of the echo falls below the associated threshold value, the echo is characterized as a false echo or ground echo, that is, originating from a reflection at a floor or roadway of the motor vehicle. In particular, the echo is not evaluated and rejected, for example.

The predetermined threshold curve predetermines a sensitivity of the ultrasonic sensor, a so-called standard sensitivity of the ultrasonic sensor. For example, the threshold curve may be subdivided into at least three threshold curve sections, with each threshold section being associated with a range of distances. A first distance range may include distances from a near range with respect to the motor vehicle. A second distance range may include distances from a central area relative to the motor vehicle and a third distance Distance range may have distances from a remote area with respect to the motor vehicle. In this case, in particular the distances from the middle region are assigned higher threshold values than the distances from the near range and the far range, since, for example, ground echoes occur particularly frequently in the middle region. If the threshold curve is fixed and is not changed, it may happen that an object located in the far field, which, for example, based on the comparison of the amplitude of the echo with the remote area assigned

Threshold was detected, can no longer be detected when it is in the central area, since the amplitude of the echo, for example, no longer exceeds the threshold associated with the central area. The object is in a so-called detection gap.

In order to prevent such a detection gap, it is now envisaged that a

Sensitivity of the ultrasonic sensor is increased when an object in the surrounding area has been detected by the ultrasonic sensor. If, for example, the object was detected at a first distance from the motor vehicle in a first measuring cycle, at least one threshold value is reduced for at least one second measuring cycle following the first measuring cycle, which corresponds to a smaller second distance than the first distance. As a result, the object whose distance relative to the motor vehicle changes, for example, due to a movement of the motor vehicle and / or the object between the two measuring cycles, can in particular decrease, can also in the at least one second

Measuring cycle are detected. In other words, this means that the object is detected, for example, in the first measuring cycle in the far-end region and then at least one threshold value in the one associated with the central region

Threshold curve section is lowered. Thus, the object can still be reliably detected even if it is located in the central area.

By increasing the sensitivity of the ultrasonic sensor in the presence of an object in the surrounding area, a detection gap can be prevented.

This can ensure that the object is permanently from the

Ultrasonic sensor can be detected. Thus, the process is designed to be particularly reliable.

Preferably, the presence of the object is detected when in one

predetermined number of measuring cycles performed by the ultrasonic sensor, the object based on the comparison of the amplitude of the received in the measuring cycle Receiving signal is detected with the threshold curve. For example, the object is detected for the first time in a first measuring cycle by exceeding the

Threshold curve is detected by an amplitude of an echo in the received signal from the ultrasonic sensor. The presence of the object is detected when the amplitude of the echo associated with the object, for example, exceeds the threshold curve in at least one further measuring cycle. In other words, the object detected for the first time is confirmed if it is in the at least one other

Measuring cycle is detected again. For example, three, in particular temporally consecutive, measuring cycles can be specified in which the object must be detected in order to detect the presence of the object. Thus, it can be ensured that the sensitivity is increased only when an object is actually located in the surrounding area of the motor vehicle.

It proves to be advantageous if the at least one threshold value is reduced as soon as the presence of the object is detected by the ultrasonic sensor. In other words, the sensitivity of the ultrasonic sensor is increased immediately when the presence of the object has been detected. This means that immediately after detection of the presence of the object in the surrounding area the at least one threshold value is reduced. Thus, the object can be permanently detected with a particularly high sensitivity.

Alternatively, the at least one threshold value is only reduced as soon as the object already detected by the ultrasound sensor is no longer detected on the basis of the comparison of the amplitude of the received signal with the threshold value curve. This means that the at least one threshold value is not already reduced as soon as the object has been detected, but only when it can no longer be detected by the ultrasound sensor, for example due to the object entering the detection gap. In other words, it means that the sensitivity is not increased immediately but as needed. Thus it can be prevented that the

Ultrasonic sensor is set too sensitive and the ultrasonic sensor, for example, thereby incorrectly interpreted ground echoes as target echoes, although the object could still be detected with the standard sensitivity. In particular, the sensitivity is then increased only in that distance range in which the object with the standard sensitivity can not be detected.

In a development of the invention, all threshold values of the threshold curve are reduced after detection of the presence of the object in the surrounding area. In particular, all threshold values are reduced as soon as the presence of the object has been detected, ie immediately after the detection of the presence of the object. For example, the predetermined threshold curve can be shifted parallel to more sensitive threshold values. This will be the predetermined

Threshold curve or standard threshold curve is mapped to a more sensitive threshold curve. Thus, especially quickly and easily

Sensitivity of the sensor can be increased.

Alternatively, only that threshold value of the threshold curve can be reduced, which corresponds to a detected by the ultrasonic sensor actual distance of the object. According to this embodiment, the threshold curve is only partially lowered. This means that always only one threshold value is lowered, namely the threshold value in the distance-dependent profile of the threshold curve, which corresponds to the current distance of the object. For the others

Threshold values of the threshold curve are given the default values. In other words, a window "traveling" with the object is formed in the threshold curve in which the ultrasonic sensor has the increased sensitivity Thus, especially in the central area where floor echoes occur frequently, the standard sensitivity can be maintained for a maximum period of time a misinterpretation of ground echoes as target echoes can be prevented.

It can be provided that the at least one threshold value of the threshold curve is reduced until the presence of the object of the

Ultrasonic sensor based on the comparison of the amplitude of the received signal with the at least one reduced threshold is no longer detected. In other words, this means that the increased sensitivity of the ultrasonic sensor due to the detected presence of the object is again reduced and the ultrasonic sensor, for example, set back to the standard sensitivity as soon as the object is no longer recognized even with the increased sensitivity. In this case, it is assumed that the object has moved away from the surrounding area of the motor vehicle. In order to prevent the ultrasonic sensor from being set too sensitive, the at least one threshold value is increased again so that the ultrasonic sensor is operated again with the standard sensitivity.

According to one embodiment, the at least one threshold value of

Threshold curve reduced to a predetermined value. In this case, a first value or default value is specified for each threshold value. By the distance-dependent course of the threshold values with the default value becomes the

formed predetermined threshold curve and thus specified the standard sensitivity. The default values are provided when there is no object in the surrounding area of the motor vehicle. In addition, a lower second value than the default value may be predetermined for each threshold and provided once the object has been detected in the surrounding area. By specifying the two values, the sensitivity of the ultrasonic sensor can be changed particularly easily and without great computational effort.

In an alternative embodiment of the invention, the at least one threshold value of the threshold curve is set after detecting the presence of the object so that a difference between the amplitude of the echo in the received signal and the threshold value falls below a predetermined limit value. According to this

Embodiment, the threshold is thus set dynamically in the presence of the object. This means that the threshold value is lowered, for example, only so far that the object can barely be detected by the ultrasound sensor, ie that the amplitude of the echo associated with the object just exceeds the at least one dynamically determined threshold value. In other words, this means that the predetermined limit value is chosen so that the amplitude of the echo only slightly exceeds the at least one threshold value of the threshold curve. Thus, it can be ensured that, although the object can be detected in particular permanently, but unwanted noise, such as ground echoes are no longer recognized.

The invention also relates to an ultrasonic sensor device having at least one ultrasonic sensor and a control device which is designed to

to carry out inventive method. The control device may be, for example, a central control unit of the motor vehicle, which can control a plurality of ultrasonic sensors of the motor vehicle and thus the

Sensitivity of each ultrasonic sensor can be set individually. However, it can also be provided that the control device is integrated in the ultrasonic sensor, so that each ultrasonic sensor has a control device. Thus, each ultrasonic sensor itself can increase its sensitivity if it has detected an object in the surrounding area. An inventive driver assistance system comprises an inventive

Ultrasonic sensor device. The driver assistance system can be configured, for example, as a parking assistance assistant.

The invention also relates to a motor vehicle with a driver assistance system. The motor vehicle is designed in particular as a passenger car.

Further features of the invention will become apparent from the claims, the figures and the description of the figures. The features and feature combinations mentioned above in the description, as well as the features and combinations of features mentioned below in the description of the figures and / or shown alone in the figures, can be used not only in the respectively specified combination but also in other combinations or in isolation, without the frame to leave the invention. Thus, embodiments of the invention are to be regarded as encompassed and disclosed, which are not explicitly shown and explained in the figures, however, emerge and can be produced by separated combinations of features from the embodiments explained. Embodiments and combinations of features are also to be regarded as disclosed, which thus do not have all the features of an originally formulated independent claim. Moreover, embodiments and combinations of features, in particular by the embodiments set out above, are to be regarded as disclosed, which go beyond or deviate from the combinations of features set out in the back references of the claims.

The invention will now be described with reference to preferred embodiments and with reference to the accompanying drawings.

Showing:

Fig. 1 is a schematic representation of an embodiment of a

 motor vehicle according to the invention;

Fig. 2 is a schematic representation of a predetermined threshold curve

 comprising a distance-dependent course of threshold values;

3 is a schematic representation of the threshold curve according to FIG. 2 and a lowered threshold curve; and Fig. 4 is a schematic representation of the threshold curve of FIG. 2, which is partially lowered.

In the figures are the same as well as functionally identical elements with the same

Provided with reference numerals.

1 shows a motor vehicle 1 according to an embodiment of the present invention

Invention. The motor vehicle 1 is formed in the present embodiment as a passenger car. The motor vehicle 1 comprises a

Driver assistance system 2, which is designed for example as a parking assistance assistant and can support a driver of the motor vehicle 1 during a parking operation. The driver assistance system 2 comprises an ultrasound sensor device 3 which has at least one ultrasound sensor 4 and a control device 5.

In the present exemplary embodiment, the ultrasound sensor device 3 comprises eight ultrasound sensors 4. Four ultrasound sensors 4 are arranged in a front region 6 of the motor vehicle 1 and four further ultrasound sensors 4 are arranged in a rear region 7 of the motor vehicle 1. By means of the ultrasonic sensor device 3, a surrounding area 8 of the motor vehicle 1 can be monitored. Here are the

Ultrasonic sensors 4 adapted to a distance of an object 9 in the

Surrounding area 9 of the motor vehicle 1 to detect the motor vehicle 1. For this purpose, the ultrasonic sensors 4 can emit a transmission signal in the form of an ultrasound signal and reflected in the surrounding area 8

Transmission signal received as received signal again.

The control device 5 is designed here as a vehicle-side, central control unit, which can communicate with the ultrasonic sensors 4. The

Control device 5 can drive the ultrasonic sensors 4, for example, to set or specify a sensitivity of the ultrasonic sensors 4. But it can also be provided that each ultrasonic sensor 4 has its own

Control device 5, for example in the form of an evaluation device which is integrated into the respective ultrasonic sensor 4.

The received signal received from one of the ultrasonic sensors 4 has a distance-dependent or transit time-dependent profile. This shows that Receiving signal usually a plurality of echoes, which are derived from reflections in the surrounding area 8. Based on a position of an echo in the

Receive signal, the duration of the echo can be determined, which can be converted directly into the distance in which the transmission signal in the

Surrounding area 8 was reflected. Here, in the received signal, which was received by the ultrasonic sensor 4, due to the reflection of the transmission signal on the object 9, an echo occurs at a position which corresponds to a distance of the object 9 relative to the motor vehicle 1. In order to distinguish echoes in the received signal, which originate from objects and are therefore so-called target echoes, from echoes which originate, for example, from ground reflections and are therefore so-called bottom echoes, a predetermined threshold curve 10 is provided, which is shown in FIG. 2 and through which a standard sensitivity of the ultrasonic sensor 4 is predetermined.

In this case, threshold values S are plotted over the transit time t, which can be converted into a distance relative to the motor vehicle 1, by means of which the

runtime-dependent or distance-dependent threshold curve 10 is specified. In each case, respective transit times t1, t2, t3 are a threshold value S1, S2, S3

assigned. The threshold curve 10 here has three threshold curve sections. A first time range corresponding to a near range is

Thresholds S assigned from a first threshold range. A second

Time range, which corresponds to a central area, are associated with threshold values S from a second threshold range and a third time range, which corresponds to a far range, are threshold values S from a third time range

Assigned threshold range. The running time t1 is assigned to an object which is located in the far-end area, the running times t2 and t3 are assigned to an object which is located in the middle area. For example, floor echoes occur more frequently in the middle area. Therefore, the threshold values S2, S3 associated with the second threshold range are increased in relation to the threshold values S1 from the first and third threshold ranges. In other words, this means that the ultrasonic sensor 4 has a lower sensitivity in the center region than in the near region and the far region.

This threshold curve 10 is used to compare the amplitudes of the echoes in the received signal. If an amplitude exceeds the threshold curve 10, the associated echo is identified as the target echo. If an amplitude falls below the threshold curve 10, the associated echo is identified, for example, as ground echo. Here, a profile of the amplitude A of the echo 1 1 associated with the object 9 in the received signal detected by the ultrasonic sensor 4 as a function of the transit time t is shown. The lower the transit time t of the echo 1 1, the closer the object 9 is to the motor vehicle 1, that is, the smaller the distance of the object 9 to the motor vehicle 1. It is shown that the object 9 can be detected on the basis of the comparison of the amplitude A of the echo 1 1 with the threshold curve 10 when the echo 1 1 has a transit time between t1 and t2 and t3 and 0. Here, for example, the object 9 is first detected by the ultrasonic sensor 4 at the transit time t1 on the basis of the comparison of the amplitude A of the echo 11 with that at the transit time t1

corresponding threshold S1 detected. In the ranges t1 to t2 and t3 to 0, the amplitude A of the echo 1 1 is greater than or equal to the threshold value curve 10. However, if the echo 1 1 associated with the object 9 has a transit time between t2 and t3, the object 9 can no longer be detected, since the amplitude A of the echo 1 1 does not exceed the threshold curve 10 in this area. The object 9 is thus located in a detection gap 12.

In order to prevent this detection gap 12, as shown in FIG. 3, at least one threshold value S1, S2, S3 of the threshold curve 10 is lowered when the presence of the object 9 in the surrounding area 8 of the motor vehicle 1 has been detected. After detection of the object 9, a reduced value S1 ', S2', S3 'is provided for the at least one threshold value S1, S2, S3. The reduced values S1 ', S2', S3 'may, for example, be predetermined and stored in a vehicle-internal memory or determined dynamically by the control device 5. In this case, the reduced values S1 ', S2', S3 'can be determined so that the amplitude A of the echo 1 1 the respective reduced threshold value S1', S2 ', S3' by only one highest

exceeds predetermined limit.

According to this embodiment, all the thresholds S1, S2, S3 of the

Threshold curve 10 lowered. This means that the predetermined threshold curve 10, that is to say the standard threshold curve 10, is mapped to a more sensitive threshold curve 10 '. For this purpose, the standard threshold curve 10, for example, be moved in parallel, so that the default threshold S1 to the reduced

Threshold S1 ', the standard threshold S2 is mapped to the reduced threshold S2' and the standard threshold S3 is mapped to the reduced threshold S3 '. Thus, the object 9 can also be detected when the echo 1 1 has a transit time t between t2 and t3. The at least one reduced threshold value S1 ', S2', S3 'is provided as long as the object 9 can also be determined on the basis of the comparison of the amplitude A of the echo 11 in FIG

Received signal with the reduced, more sensitive threshold curve 10 'is no longer detected. It is then assumed that the object 9 is no longer located in the surrounding area 8 of the motor vehicle 1.

The at least one threshold value S1, S2, S3 can be lowered as soon as the object 9 has been detected, ie immediately after the object 9 has been detected. However, it can also be provided that the at least one threshold value S1, S2, S3 is lowered only when the object 9 can no longer be detected by the comparison of the amplitude A of the echo 11 with the threshold value curve 10. This is the case, for example, when the echo 1 1 has a transit time t, which is located within the detection gap 12.

In Fig. 4 it is shown that the threshold curve 10 is only partially lowered. In this case, only that threshold value S4 is mapped to a lowered threshold value S4 ', which corresponds to an instantaneous transit time t4 of the echo 1 1. In particular, only a threshold curve section is lowered, which has the threshold value S4. Thus, a window "moving in" with the transit time t of the echo 1 1 is determined in the threshold curve 10. Thus, the sensitivity of the ultrasound sensor 4 is dynamically adjusted and only increased in certain areas can no longer be detected by means of the comparison of the amplitude A of the echo 1 1 with the threshold value curve 10. By partially lowering the threshold value curve 10, it is advantageously possible to prevent the threshold value curve 10 over the entire distance range

or running time range is set too sensitive.

Claims

claims

1 . Method for operating an ultrasonic sensor (4) of a motor vehicle (1), wherein for the ultrasonic sensor (4) a predetermined, a

 distance-dependent course of threshold values (S1, S2, S3)

 Threshold curve (10) is provided, with which an amplitude (A) of one of the ultrasonic sensor (4) for measuring a distance between the

 Motor vehicle (1) and one in a surrounding area (8) of the motor vehicle (1) located object (9) received received signal to be compared, characterized in that

 to increase a sensitivity of the ultrasonic sensor (4) at least one threshold value (S1, S2, S3) of the threshold value curve (10) after detection of the

 Presence of the object (9) in the surrounding area (8) is reduced.

2. The method according to claim 1,

 characterized in that

 the presence of the object (9) is detected when, in a predetermined number of measuring cycles performed by the ultrasonic sensor (4), the object (9) is compared by comparing the amplitude (A) of the measuring cycle

 Received signal received with the threshold curve (10) is detected.

3. The method according to claim 1 or 2,

 characterized in that

 the at least one threshold value (S1, S2, S3) is reduced as soon as the presence of the object (9) is detected by the ultrasonic sensor (4).

4. The method according to claim 1 or 2,

 characterized in that

the at least one threshold value (S1, S2, S3) is only reduced as soon as the object (9) already detected by the ultrasound sensor (4) is no longer detected on the basis of the comparison of the amplitude (A) of the received signal with the threshold value curve (10).

5. The method according to any one of the preceding claims,

 characterized in that

 all threshold values (S1, S2, S3) of the threshold curve (10) are reduced after detection of the presence of the object (9) in the surrounding area (8).

6. The method according to any one of claims 1 to 4,

 characterized in that

 only that threshold value (S4) of the threshold curve (10), which corresponds to a current distance of the object (9) detected by the ultrasound sensor (4), is reduced after the detection of the presence of the object (9).

7. The method according to any one of the preceding claims,

 characterized in that

 the at least one threshold value (S1, S2, S3) of the threshold curve (10) is reduced until the presence of the object (9) of the

 Ultrasonic sensor (4) based on the comparison of the amplitude (A) of

 Receiving signal with the at least one reduced threshold value (SV, S2 ', S3') is no longer detected.

8. The method according to any one of the preceding claims,

 characterized in that

 the at least one threshold value (S1, S2, S3) of the threshold curve (10) is reduced to a predetermined value (SV, S2 ', S3').

9. The method according to any one of claims 1 to 7,

 characterized in that

 the at least one threshold value (S1, S2, S3) of the threshold curve (10) is adjusted after detection of the presence of the object (9) such that a difference between the amplitude (A) of the received signal and the threshold value (SV, S2 ', S3 ') falls below a predetermined limit.

10. Ultrasonic sensor device (3) with at least one ultrasonic sensor (4) and a control device (5), which is adapted to a method according to a to carry out the preceding claims.

1 1. Driver assistance system (2) with an ultrasonic sensor device (3) according to claim 10.

12. Motor vehicle (1) with a driver assistance system (2) according to claim 1. 1