EP3788397A1 - Method and device for operating ultrasonic sensors of a vehicle - Google Patents

Abstract

The invention relates to a method for operating ultrasonic sensors (102) of a vehicle (100), which is characterized in that front ultrasonic sensors (102) of the vehicle (100) are used to detect wind noise on the vehicle (100), rear ultrasonic sensors (102) of the vehicle (100) are used to detect road conditions in the region of the vehicle (100), and lateral ultrasonic sensors (102) of the vehicle (100) are used to detect objects in the region of the vehicle (100).

Description

 description

Method and device for operating ultrasonic sensors of a

vehicle

Field of the invention

The invention relates to a method and a device for operating ultrasonic sensors of a vehicle.

State of the art

Using ultrasonic sensors, obstacles around a vehicle can be detected at low vehicle speeds. At higher speeds, the detection is made difficult by wind noise and tire noise.

Disclosure of the invention

Against this background, with the approach presented here, a method for operating ultrasonic sensors of a vehicle and a device for operating ultrasonic sensors of a vehicle, and finally a corresponding computer program product and a machine-readable

Storage medium according to the independent claims presented. Advantageous developments and improvements of the approach presented here emerge from the description and are described in the dependent claims.

Advantages of the invention Embodiments of the present invention may advantageously allow differentially oriented ultrasonic sensors of a vehicle to be used for different tasks. In each case, the

Ultrasonic sensors are used for a task that is particularly well suited for it.

A method for operating ultrasonic sensors of a vehicle is presented, which is characterized in that front ultrasonic sensors of the vehicle are used for detecting wind noise on the vehicle, rear ultrasonic sensors of the vehicle for detecting a

Road conditions are used in the field of the vehicle, and lateral ultrasonic sensors of the vehicle for detecting objects in the area of the vehicle can be used.

Ideas for embodiments of the present invention may be considered, inter alia, as being based on the thoughts and findings described below.

A vehicle can be oriented in different directions

Have ultrasonic sensors. When the ultrasonic sensors are actively operated, they emit ultrasonic pulses into an orientation-dependent detection area. Objects in the detection area will have the

Ultrasound pulses partially reflected and received as echoes back to the ultrasonic sensor. The echoes have a much lower intensity than the ultrasonic pulses. From a transit time of the ultrasonic pulses and the echoes, a distance to the respective object can be determined. In addition to the echoes, the ultrasonic sensors detect ambient noise when in a receiving frequency band of the ultrasonic sensors. Are the

Ambient noise louder than the echoes, the ambient noise may interfere with receiving the echoes.

While driving, the vehicle will be powered by one from a local

Wind speed and a local wind direction and a current vehicle speed resulting wind flows around. The wind causes noise on a body of the vehicle, as

Wind noises can be designated and can be detected by the ultrasonic sensors. The wind noise can vary depending on Vehicle speed, wind speed and wind direction be louder than the echoes.

Depending on the speed of the vehicle, when rolling on the road, tires of the vehicle cause noises, which can be called rolling noises and can be detected by the ultrasonic sensors. The

Rolling noise may be louder than the echoes, depending on the vehicle speed.

When a pavement road condition is wet, the tires cause additional noise when unwinding, which may be referred to as wet smearing, for example, and may be detected by the ultrasonic sensors. Wet scratching may be louder than the echoes, depending on the road condition and vehicle speed.

Regardless of the vehicle speed, others produce

Noise sources Noise. For example, other vehicles generate wind noise, rolling noise and wet or wet conditions on wet or wet roads. These extraneous noises can also be detected by the ultrasonic sensors.

The different ambient noise and extraneous noise interfere with each other, so that at each ultrasonic sensor, a composite ambient noise is detected.

At the differently oriented ultrasonic sensors, the

different ambient noise to different intensities. The wind noise has a high intensity on the forward-facing ultrasonic sensors. The rolling noise and wet hissing have a high intensity on the rear-facing sensors. On the side-facing ultrasonic sensors, the extraneous noise of other vehicles on a high intensity.

To detect the wind noise and / or to recognize the

Road conditions and / or for recognizing the objects can be sent to the

Ultrasonic sensors detected noise levels are evaluated. The

Foreign noises can be quantified in a numerical value. Of the

Numerical value can be called noise level. The noise level indicates an intensity of ambient noise at one

Ultrasonic sensor. The noise level is already determined in the ultrasonic sensor and mapped in a received signal of the ultrasonic sensor. By using the noise level, further data processing can be done with reduced computational effort.

To detect the objects, echoes detected at the ultrasonic sensors can be evaluated. The objects can also be actively recorded. As a result, it is also possible to determine a distance to the objects from the transit time of the echo signals. The extraneous noise emitted by the objects can additionally be evaluated on the basis of the received noise level.

Wind noise and / or objects imaged in sensor information of the rear-facing ultrasonic sensors may be compensated using the wind noise detected at the forward-facing ultrasonic sensors and / or the objects detected at the side-facing ultrasonic sensors. In sensor information to the side

aligned wind noise and / or road conditions can be measured using the attached forward ultrasonic sensors

aligned wind sensors and / or detected by the rear-facing ultrasonic sensors road condition can be compensated. Objects and / or the road condition imaged in sensor information of the forward-facing ultrasonic sensors may be compensated using the road condition detected on the rear-facing ultrasonic sensors and / or the objects detected on the side-facing ultrasonic sensors. Since different components of the ambient noise are respectively detected particularly well at the differently oriented ultrasonic sensors, the respectively less well-detected components of the ambient noise can be compensated.

Sensor information of pairs arranged symmetrically to a vehicle longitudinal axis of the vehicle ultrasonic sensors can be evaluated together. Noise of the own vehicle is substantially the same on both sides of the vehicle. If different sounds are detected on both sides, it is very likely

Foreign noises from a foreign noise source on one side of the

Vehicle. Sensor information of the ultrasonic sensors arranged on one side of the vehicle can be used to detect on the vehicle side overtaking or outdated other vehicles. Overhauling vehicles and overhauled vehicles travel at a different speed. As a result, an outdated vehicle is first detected at the front sensors. An overtaking vehicle is first detected at the rear sensors.

The method may, for example, in software or hardware or in a hybrid of software and hardware, for example in a

Be implemented control unit.

The approach presented here also provides a device which is designed to implement the steps of a variant of the method presented here

to implement, control or implement appropriate facilities.

The device may be an electrical device having at least one computing unit for processing signals or data, at least one memory unit for storing signals or data, and at least one interface and / or a communication interface for reading in or outputting data embedded in a communication protocol, be. The arithmetic unit can be, for example, a signal processor, a so-called system ASIC or a microcontroller for processing sensor signals and outputting

Be data signals in response to the sensor signals. The storage unit may be, for example, a flash memory, an EPROM or a magnetic storage unit. The interface can be used as a sensor interface for reading in the sensor signals from a sensor and / or as an actuator interface for

Outputting the data signals and / or control signals to be formed on an actuator. The communication interface can be designed to read in or output the data wirelessly and / or by cable. The

Interfaces may also be software modules that are present, for example, on a microcontroller in addition to other software modules.

Also of advantage is a computer program product or computer program with program code which can be stored on a machine-readable carrier or storage medium such as a semiconductor memory, a hard disk memory or an optical memory and for carrying out, implementing and / or controlling the steps of the method according to one of the above described embodiments, in particular when the program product or program is executed on a computer or a device.

It should be understood that some of the possible features and advantages of the invention are described herein with reference to different embodiments. A person skilled in the art will recognize that the features of the method and the device are suitably combined, adapted or

can be exchanged to get to further embodiments of the invention.

Short description of the drawing

Embodiments of the invention will now be described with reference to the accompanying drawings, wherein neither the drawings nor the description are to be construed as limiting the invention.

1 shows a representation of a vehicle with differently oriented ultrasonic sensors and a device according to one exemplary embodiment.

The figure is merely schematic and not to scale. Same

Reference numerals in the figure designate the same or equivalent features.

Embodiments of the invention

Fig. 1 shows a representation of a vehicle 100 with different

aligned ultrasonic sensors 102 and a device 104 according to an embodiment. The ultrasonic sensors 102 are arranged distributed over the vehicle 100. Here, the ultrasonic sensors 102 are numbered clockwise from one to thirteen.

The first ultrasonic sensor 102 is here arranged on a left front corner of the vehicle 100 and aligned with respect to a vehicle longitudinal axis 106 of the vehicle 100 to the left. The second ultrasonic sensor 102 is also arranged at the left front corner and oriented relative to the vehicle longitudinal axis 106 obliquely to the left front. The third ultrasonic sensor 102 is also disposed at the left front corner and oriented forward.

The fourth ultrasonic sensor 102 is at a right front corner of the

Vehicle 100 relative to the vehicle longitudinal axis 106 arranged symmetrically to the third ultrasonic sensor 102 and as the third ultrasonic sensor 102 aligned forward. The fifth ultrasonic sensor 102 is also arranged at the right front corner with respect to the vehicle longitudinal axis 106 symmetrical to the second ultrasonic sensor 102 and based on the

Vehicle longitudinal axis 106 obliquely oriented to the right front. The sixth ultrasonic sensor 102 is also arranged at the right front corner with respect to the vehicle longitudinal axis 106 symmetrical to the first ultrasonic sensor 102 and aligned with respect to the vehicle longitudinal axis 106 to the right.

The number seven is not taken.

The eighth ultrasonic sensor 102 is at a right rear corner of the

Vehicle 100 arranged and aligned relative to the vehicle longitudinal axis 106 to the right. The ninth ultrasonic sensor 102 is also arranged at the right rear corner and aligned with respect to the vehicle longitudinal axis 106 obliquely to the right rear. The tenth ultrasonic sensor 102 is also disposed at the right rear corner and rearwardly.

The eleventh ultrasonic sensor 102 is disposed at a left rear corner of the vehicle 100 with respect to the vehicle longitudinal axis 106 symmetrically with respect to the tenth ultrasonic sensor 102, and like the tenth ultrasonic sensor 102 is aligned rearward. The twelfth ultrasonic sensor 102 is also arranged at the left rear corner with respect to the vehicle longitudinal axis 106 symmetrical to the ninth ultrasonic sensor 102 and based on the

Vehicle longitudinal axis 106 obliquely aligned to the rear left. The thirteenth ultrasonic sensor 102 is also arranged at the left rear corner with respect to the vehicle longitudinal axis 106 symmetrical to the eighth ultrasonic sensor 102 and with respect to the vehicle longitudinal axis 106 to the left

aligned. Each ultrasonic sensor 102 may echo location of objects in its respective detection area 108 using emitted ultrasound and image a distance to the object in sensor information 110. Alternatively or additionally, each ultrasonic sensor 102

Record ambient noise and map in the sensor information 110. An intensity of the ambient noise is in each case imaged in a noise level 112 of the sensor information 110.

The sensor information 110 of all the ultrasonic sensors 102 are read in by the device 104.

When the vehicle 100 is traveling slowly, for example, when maneuvering, parking or in a traffic jam, the echolocation works as intended and few ambient noises are detected. If the ambient noise grows louder than the echoes of the ultrasound, the echolocation will only work to a limited extent.

For example, wind on a body of the vehicle 100 generates a wind noise detected by the ultrasonic sensors 102. Furthermore, tires of the vehicle 100 generate a rolling noise, which is also detected by the ultrasonic sensors 102. In addition, when a road surface is wet or wet, the tires generate a water sound or a wet hiss, which is also detected by the ultrasonic sensors 102. The wind noise, the rolling noise and the wet hiss are with

Foreign noises of other sources of noise contained in the ambient noise. At least the wind noise, the rolling noise and the

Water noise becomes louder with increasing speed of the vehicle 100.

In the approach presented here, sensor information 110 from substantially forward-facing ultrasonic sensors 102 is used to detect the wind noise. Sensor information 110 from substantially back-aligned ultrasonic sensors 102 are used to detect water noise and rolling noise.

Sensor information 110 from substantially to the side

Ultrasonic sensors 102 are used to detect extraneous noise from other sources of noise. In other words, a method for sensor selection in the field of wetness detection on the roadway by means of ultrasound is presented.

Currently, the road wetness or the indication mm-water column on a roadway can not be measured directly. From different operating conditions of the vehicle can be indirectly deduced on a wet road. This can be done for example by the wiper activity or ESP interventions. A continuous "measurement" of the road condition in the direction of moisture does not currently exist.

For obstacle detection, ultrasonic sensors are installed near the wheel arches. A significant problem in using obstacle detection during faster driving is the driving noise that is generated by the

Sensors superimpose radiated echoes and thus severely restrict the distance measurement. The more water from the tires splashes against the wheel arch, the louder the driving noise and the stronger the restriction.

The noise level reaches mainly directly through the air to the sensor, but can also be received indirectly by structure-borne sound from the sensor. These noises can be calculated as noise level or as "noise" (disturbance variable, noise value) in the ultrasonic control unit. The noise level can be output via CAN to other control units in the vehicle.

Driving tests have shown that the quality of detection of

Passenger properties, such. B. a wetness detection or detection of environmental properties, such. As the detection of other vehicles, very much depends on the respective selection of the involved ultrasonic sensors (USS). Not every sensor position (currently up to 12 sensors per vehicle can be installed) is equally well suited or even has a negative impact on the respective detection method. Therefore, a suitable sensor selection plays a very important role in order to be able to make robust and high-quality statements regarding wetness on the road.

Fundamentally different environmental or roadway properties can be detected by means of the ultrasonic sensors. These are object recognition, wetness detection on the road and wind detection.

In the approach presented here, the wind speed in the longitudinal direction is calculated with the noise levels of the front sensors, with the Noise levels of the side sensors are detected objects and with the noise levels of the rear sensors, wetness is measured on the road. Because wind and objects also reduce the noise levels of the rear sensors

influence, the measurement of the wetness with the help of the wind and

Object information corrected.

For recognition of objects (other road users, such as

Vehicles, trucks, ...) are the laterally arranged four sensors (Nr.l, 6, 8,

13). The respective difference signal of the noise values of the front sensors (no. 1, 6) and the rear sensors (no. 13, 8) is evaluated.

U diff. 1, 6 [mV] = U 1 [mV] - U 6 [mV]

U diff. 1, 6> Threshold Object Underrun of another vehicle on the left side of the vehicle U diff. 1, 6 <threshold Object overtaking person's own vehicle on the right side of the vehicle

U diff. 13, 8 behaves in the same way.

About the temporal behavior of the difference signals U diff. 1, 6 and U diff. 13, 8 can also be closed on an under- or overtaking. In an overtaking process, an increase of the difference signal first occurs vehicle-specifically on the right in the direction of travel on the front lateral sensors (1, 6), in terms of time of the differential speed according to thereafter at the rear sensors (8, 13). In a Unterholvorgang according to the other way around and on the left side. Furthermore, with a temporally (longer) constant difference signal on a continuous object (guardrail, wall, ...) and its location (distance, left or right)

getting closed.

Different thresholds are used for different types of objects (car, truck, ...). Thus, a conclusion can be drawn to the respective object in the ferry and z. B. with the objects from the

Radar / Lidar / camera environment are validated. For an object recognition, the sensors (1, 6, 8, 13) can be feature-specific as a whole

Speed band (currently> = 60km / h) in addition to the measurement of the

Noise levels also actively send out ultrasonic signals and objects using the Recognize received echoes, as long as they are not suppressed by excessive noise levels.

To detect the road wetness, the rear four sensors (Nos. 9, 10, 11, 12) are relevant. With this sensor selection, the best measurement results can be achieved in relation to the current road surface wetness. For these sensor positions z. B. the wind influence the least.

Is by the vehicle-specific object detection no object in

Detected detection area, all rear sensors (Nos. 9, 10, 11, 12) can be used for moisture detection. In this case, the sensors can be operated actively or inactive, since the noise value can be determined and processed in each case.

Is by the vehicle-specific object recognition (for example, with radar, camera or lidar) a continuous object (guardrail, ...) in

Detected detection area, the moisture detection can be suspended.

Alternatively, however, all rear sensors (Nos. 9, 10, 11, 12) for

Wetness detection be included. However, the sensor values of the rear sensors are then replaced by a sensor-specific and if necessary

Object-specific correction value is lowered. Thus, the object influence on the sensor-specific noise level is compensated.

If a short-term object (vehicle,...) Is detected in the detection area by the vehicle-specific object detection, the rear sensors (Nos. 9, 10, 11, 12) for detecting moisture are partially deactivated object-specifically. Here, object groups are formed which have a similar influencing pattern (course and intensity) with respect to the noise value of a single sensor. According to each object group it is defined, which sensors for the moisture detection during the influence contribute to the

Can provide moisture detection.

The noise levels of all other sensors are not taken into account for the calculation of wetness during the time of this influence. For example, for an object type "automobile" only the two near-object sensors are deactivated (see also continuous object). In the case of a "truck" object type, however, all the rear sensors are not taken into account, since no moisture detection by ultrasonic sensors can currently be carried out here. The continuous noise value of the Sensorrohsignals is in a

sensor-individual status transferred. Each sensor is assigned an index (sensor designation): i = [1 2 3 4 5 6 NaN 8 9 10 11 12 13], because the index 7 is not used. The result is output as a status vector:

Z = [1 2 3 4 5] where the status is interpreted as follows and intermediate values may occur:

1: dry

 2: wet

 3: wet

 4: very wet

 5: aquaplaning danger n: support point of the status vector Z

v: speed (dependence)

t: time (dependency)

s (i): sensor selection

s (i) .SZ (t): sensor result at time t

stst noise: base value of the noise value

tracker noise: current noise value of the sensor and can be calculated as follows:

From the individually calculated sensor-individual results, a sensor fusion value is calculated via all sensors via a fusion factor. The size of the sensor-specific fusion factor depends on the "object recognition". Examples of different fusion factors k for wet or very wet roads. The crossed out sensors are not considered. k 1 (i) = [0 0 0 0 0 0 NaN no object detected

k 2 (i) = [0 0 0 0 0 0 NaN overtaking (car) detected

k 3 (i) = [0 0 0 0 0 0 NaN overtaking (lorry) detected

k 4 (i) = [0 0 0 0 0 0 NaN Undercarter (car) detected

Calculation of the merged result:

SZ fus (t): fused result of moisture detection

v_tracker noise: current vehicle speed

For detection of the wind in the vehicle longitudinal direction, the front four sensors (2, 3, 4, 5) are relevant. Here, the effect is exploited that the influence of wind on the noise level of the individual front sensors occurs reinforced. This effect can be determined in an experimental experiment and mapped in a corresponding model value. In this case, the vehicle is subjected to wind in the longitudinal direction (eg in a wind tunnel). From this, wind speed-dependent sensor-individual noise values can be mapped and form the following relationship:

(1) V wind [km / h] = V wind [km / h] - V vehicle [km / h]

 (2) V vehicle = 0km / h (in the wind tunnel)

 (3) V wind [km / h] ~ N sensor [mV] * k [km / h / mV]

 (4) V wind [km / h] = N sensor [mV] * k [km / h / mV] - V vehicle [km / h]

V: speed

N: noise value "noise"

k: speed-dependent correction factor or in road driving test:

(1) V wind [km / h] = V wind [km / h] - V vehicle [km / h]

 (2) V wind = 0km / h (windless day)

(3) V Fahrtwind [km / h] = V vehicle [km / h]

 (4) V wind [km / h] ~ N sensor [mV] * k [km / h / mV]

 (5) V wind [km / h] = N sensor [mV] * k [km / h / mV] - V vehicle [km / h]

Since headwind likewise increases the noise levels of the rear four sensors and decreases co-wind, the wind speed calculated with the front four sensors is used to compensate for the noise levels of the rear four sensors.

The approach presented here can be used as a software feature in any car with an integrated, automatic on / off parking assistant. The method can be used in principle in all vehicles with ultrasonic sensors. Since only an already calculated signal is made available on the CAN bus and a warning is issued to the driver on the basis of this signal, a minimum conversion with software changes to the ultrasound control device and to the HMI is very cost-effective.

Finally, it should be noted that terms such as "comprising," "comprising," etc., do not exclude other elements or steps, and terms such as "a" or "an" do not exclude a multitude. Reference numerals in the

Claims are not intended to be limiting.

Claims

claims

A method of operating ultrasonic sensors (102) of a vehicle (100), characterized in that front ultrasonic sensors (102) of the vehicle (100) are used to detect wind noise on the vehicle (100), rear ultrasonic sensors (102) of the vehicle (100). 100) are used to detect a road condition in the area of the vehicle (100), and lateral ultrasonic sensors (102) of the vehicle (100) are used to detect objects in the area of the vehicle (100).

2. Method according to claim 1, in which noise levels (112) detected for detecting the wind noise and / or for detecting the road condition and / or for detecting the objects at the ultrasonic sensors (102) are evaluated.

3. Method according to one of the preceding claims, in which echoes detected to detect the objects on the ultrasonic sensors (102) are evaluated.

4. The method according to any one of the preceding claims, wherein in

 Sensor information (110) of the rear-facing

 Ultrasonic sensors (102) mapped wind noise and / or objects using the detected wind noise and / or detected objects are compensated.

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

 Sensor information (110) of the side-facing ultrasonic sensors (102) wind noise and / or road conditions using the detected wind noise and / or the detected road condition are compensated.

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

Sensor information (110) from pairwise symmetric to one Vehicle longitudinal axis (106) of the vehicle (100) arranged

 Ultrasonic sensors (102) are evaluated together.

A method according to claim 6, wherein the sensor information (110) of the vehicle side ultrasound sensors (102) is used to detect on the vehicle side passing or outdated other vehicles.

Device (104), wherein the device (104) is designed to implement, implement and / or control the method according to one of the preceding claims in corresponding devices.

A computer program product adapted to execute, implement and / or control the method of any of claims 1 to 7.

10. Machine readable storage medium on which the

 Computer program product according to claim 9 is stored.