WO2018086728A1 - High-beam assistance system - Google Patents

Abstract

The invention relates to a high-beam assistance system in a vehicle (1) having an optical camera (3), wherein control of an automatic high beam is performed in accordance with data (19) captured by the camera (3). The high-beam assistance system according to the invention is characterized in that at least one further environmental sensor (7, 8, 9) is provided, which monitors at least one region not sensed by the camera (3), wherein alternative control of the automatic high beam is performed in accordance with data (19) captured by the at least one further environmental sensor (7, 8, 9).

Description

 High beam assistance system

The invention relates to a high-beam assistance system with an optical camera according to the type defined in greater detail in the preamble of claim 1. The invention also relates to the use of such a high-beam assistance system.

A high-beam assistance system or a so-called high-beam assistant is known from the general state of the art. The high-beam assistance system is a safety / comfort element which is used in vehicles to automate the focussing and dimming of the high beam in the dark. About a typically mounted in the front of the mirror is the camera

Headlamp oncoming and the taillight of preceding vehicles registered to a relevant distance from the vehicle. The high-beam assistant then automatically switches the high beam on and off or changes the light distribution generated by the high beam in front of the vehicle, depending on whether other road users have been recognized or not. Without the driver of the vehicle must be actively involved in the operation of the automatic high beam, so on the one hand, a good view can be achieved, and on the other hand, the dazzle of others

Road users are avoided by the high beam.

The driving of an automatic high beam via a camera as a sensor for detecting other road users can not be sufficient in certain traffic situations to dazzle another road user,

especially a preceding lighted vehicle safely exclude. This depends, for example, on the laterally restricted viewing angle of the camera and, depending on the installation height of the camera, possibly restricted viewing angle in the vertical direction. In addition, certain visual impairments such as For example, misted windows or the like impair the functionality of the camera as a sensor for the high-beam assistance system.

The object of the present invention is now a

To further improve high beam assistance system and in particular to minimize the above-mentioned disadvantages.

According to the invention, this object is achieved by a high-beam assistance system having the features in claim 1. In claim 10, a particularly preferred use is given for this purpose.

The high-beam assistance system according to the invention uses an optical camera similar to the above-mentioned prior art. According to the invention, at least one further environmental sensor monitors at least one area not covered by the camera. Such an area not covered by the camera can, for example, be an area laterally next to the vehicle or laterally in front of the vehicle, which due to the typically restricted viewing angle of the camera is not or not completely detected. In order to detect a vehicle in this area via the camera, for example a vehicle on the adjacent lane, in particular one which has just overtaken the vehicle with the high-beam assistance system, it would be necessary for the vehicle to control the vehicle and its taillights and, in particular, the road below to recognize the vehicle. This is in an overtaking vehicle depending on the time at which it is on the track of the vehicle with the

High-beam assistance system switches in, not or only delayed possible. In this case, the high beam is then typically switched off too late via a conventional high beam assist system. For this reason, such an area not detected by the camera can now be monitored via the at least one further environmental sensor. This sensor may be, for example, a radar, a lidar, ultrasonic sensors, laser scanners or the like.

Be about this at least one more environment sensor another

Road users detected in the area monitored by him, then this can be actuated accordingly via an alternative control of the automatic high beam, switched off in the described embodiment. The high beam assistant thus ensures that the high beam is dimmed, even if the potentially blinded road users by the camera is not yet detected.

As already mentioned, it can be provided in an advantageous embodiment of the high-beam assistance system according to the invention that the at least one further

Environmental sensor is mounted so that it monitors an area to the side of the vehicle. In particular, the region facing the counter-track area may be preferred here, since vehicles which are to be overtaken, for example, or the like, are to be expected on this side. According to a very advantageous development of the idea, it can also be provided that two environmental sensors are mounted so that they monitor both areas laterally next to the vehicle.

Another extraordinarily favorable development of the idea according to the invention now provides, as an alternative or in addition thereto, for the at least one further one

Environmental sensor is mounted in a different installation height from the installation height of the camera. Cameras are typically suitable for center and far field detection of the environment of the vehicle. Depending on the installation height of the camera, this detection starts, for example, in the direction of travel, a certain distance in front of the vehicle and is typically within its maximum range

Visibility dependent. In particular, the beginning of the detection of a certain distance in front of the vehicle is disadvantageous when objects are located between the vehicle and this beginning of the camera detection. These can not be detected by the camera, so that a gap in the detection arises here, in particular if the objects do not move within this range in time, if the detection range of the camera has already passed this section while the vehicle is moving.

This applies in particular to the application in commercial vehicles. Here the cameras are similar to passenger cars mounted behind the windshield of the vehicle to be protected by this and to benefit from the windshield wipers in the rain. If it happens that a vehicle that has passed the lorry, before this einschert, then it may happen that this vehicle is still between the truck and the area in which the center and far field detection begins by the camera , The vehicle is therefore not recognized as such, so that the conventional high beam assistance system in Case of detected in front of the truck vehicle responded. In such a situation, the further environmental sensor according to the invention is now used. The sensor data acquired by the further environmental sensor fill the gap remaining in the captured data of the camera between the vehicle and the beginning of the range of its detection.

In order to reliably detect, for example, a passenger car via a camera system, which drives in front of a truck or after one

Overtaking precedes this, typically the vehicle and the road below the vehicle in the captured image data is necessary. If the vehicle now collapses in such a way that only a part of the roof and, for example, the rear rear window are located in the perspective of the camera, then the vehicle can not be recognized as such.

By means of the high-beam assistance system according to the invention, such situations are now prevented by the fact that vehicles located in this gap of the detection by the camera are recognized as such via the at least one further environmental sensor, which according to an advantageous development of the idea may be a radar. By using the data of both sensors, not in the form of a redundancy, but in the form of an OR operation to improve the range, the desired functionality of dimming can be reliably triggered in the context of a high-beam assistance.

According to an advantageous development of the idea, the at least one further environmental sensor can be a radar system, as already mentioned above. According to an advantageous development of the idea, the radar system in addition to a

Front radar also include one or more side radars, for example, to be able to detect an overtaking vehicle at a very early stage and before the end of shearing in front of the vehicle with the high beam assistance system.

According to a further very advantageous embodiment of the idea, it is further provided that the at least one further environmental sensor is positioned below the camera. Such a construction can be of decisive advantage, in particular for commercial vehicles. Typically, the camera system is positioned at the top or bottom of the windshield so that it can enjoy the effect of windshield wipers comes. If the further environmental sensor is now positioned below, then it can exactly fill in the gap that results from the very high installation point of the camera, especially in the case of commercial vehicles. According to an advantageous development of the idea, the further environmental sensor is positioned more than 0.9 m, preferably more than 1 m, below the optical camera.

In another very favorable development of the idea, it is beyond

provided that the horizontal angle of view of at least one other

Ambient sensor is greater than the camera's angle of view. Cameras typically have a viewing angle which allows safe and reliable detection in the mid and long range already mentioned. Such a viewing angle of the camera can be, for example, in the order of 50 °. In many cases, this is then not enough to reliably detect objects located close to or in front of the vehicle, this is especially true with a correspondingly high installation height of the camera in the vehicle. By now using at least one further environmental sensor, this gap can be closed. It makes sense if this ambient sensor in the horizontal has a larger viewing angle than the camera, to ensure not only in the vertical, due to its preferably below the camera installation position, a horizontal in relation to the camera larger detection area so by a merger of

Sensor data to close the gaps remaining in the field of view of the camera reliably.

According to an advantageous development of this idea, provision may also be made for additional sensor data to be included in the control, in particular in a decision to suppress the automatic high beam. Further sensor data can thus be used to keep the lighting system dimmed and to avoid the high beam from fading out. Such data can come in particular from other sensors or be data which from the evaluation of the particular

Camera image or other sensors such as a

Navigation system or the like can be detected. Thus, for example, it is possible to suppress the high beam on the day when the environment has been detected, for example, by a twilight sensor or as "bright." For example, if street lights have been detected by the vehicle's optical camera, city driving or tunneling may occur Another option is to switch the high beam light on at all times fade when a certain speed of the vehicle is reached, for example, a speed of more than 50 km / h, so typically can be assumed that a trip outside the city.

In principle, the high-beam assistance system is suitable for every type of vehicle. It has already been explained on the basis of the example above that it can ideally solve existing problems, in particular, if the installation heights of the optical camera on the one hand and the other environmental sensor on the other hand differ considerably. Such a situation occurs in particular in the field of commercial vehicles, as they have a much greater height than passenger cars and typically have the driver and thus the windshield and the camera installed behind her at a much higher installation height. The particularly preferred use of the high-beam assistance system according to the invention is therefore in a commercial vehicle, in particular in a truck without a so-called snout or hood. Above all, but not exclusively in such applications arises for the camera a gap in their detection immediately in front of the vehicle, which in the

The high-beam assistance system according to the invention can now be ideally closed by the at least one further environmental sensor.

Further advantageous embodiments of the idea will become apparent from the

Embodiment, which is described below with reference to the figures.

Showing:

 Fig. 1 is a principle side view of a situation for the use of

 High-beam assistance system according to the invention;

Fig. 2 is a principle plan view of a situation for the use of

 High-beam assistance system according to the invention;

3 shows an exemplary representation of the used control unit network; and

4 is a functional diagram of the high beam assistant.

The high-beam assistance system according to the invention is described below purely by way of example for a commercial vehicle, in the form of a heavy goods vehicle. The

However, the high-beam assist system according to the invention is not preferred for this purpose Embodiment limited, but can of course be used for any vehicles.

In the illustration of Figure 1, a truck 1 as a commercial vehicle and a passenger car 2 is shown in more detail as an object to be recognized. In which

Truck 1 is such that an optical mono or stereo camera 3 is mounted behind an indicated windshield 4. The assembly can be done comparable to most passenger cars in the upper part of the windshield 4. Ideally, the camera 3 is due to the very high construction of the

Truck 1, however, as shown here mounted on the lower edge of the windshield 4. The optical axis of the camera 3, which in the representation with the

Designated by reference numeral 5 and indicated by a dash-dotted line, typically deviates by a certain angle α from the designated by the reference numeral 6 and shown in two-dot-dashed horizontal. The camera 3 is thus inclined slightly downwards, for example, at an angle of about 5 ° in the installation shown here at the lower end of the windshield 4. In a commercial vehicle 1, the installation height of the camera 3 is H in the illustration of the figure the roadway nevertheless comparatively large, it is for example in the order of about 1, 5 m up to more than 3 m in the case of installation at the top of the

Windshield 4.

The viewing angle of the camera is to ensure a reliable detection, in particular in the range of a medium and greater distance with a viewing angle ß of, for example, about 50 °. When the passenger car 2 the

Truck 1 has now just overtaken, for example, and einschert in front of the truck 1 again, it can come to the situation shown in Figure 1. in the

Viewing angle ß of the camera 3 is of the passenger car 2, only the upper

Rear. In order to reliably recognize the passenger car 2 as a vehicle, at least the complete recognition of its taillights, in particular the recognition of both the vehicle and the roadway below the vehicle, is necessary. This would be possible at the angle shown here only in a distance marked L. However, the actual distance I, which is smaller than the distance L, is lower. The passenger car 2 is thus not in the area which can be reliably detected by the camera 3. A coupled to the presence of the passenger car 2 functionality of the High-beam assistance system can therefore not be used because the passenger car 2 is not recognized as such. The dimming of the high beam would therefore only take place in this situation when the distance between the truck 1 and the passenger car 2 has grown to the distance L. In this time, a strong glare of the driver of the car 2 would take place. This is highly undesirable.

In order to remedy this problem, a further ambient sensor, in the illustrated exemplary embodiment of FIG. 1, a radar system with a front radar 7, is now additionally used. This front radar 7 is installed at a much lower installation height h above the road than the camera. The installation height h is typically on the order of 0.3 to a maximum of 1 m above the surface of the road. This front radar 7 now detects by way of example the region indicated by the dotted lines, which has at least within the distance I in front of the front of the truck 1 only a comparatively small overlap with the viewing angle β of the camera 3.

The front radar 7 is able to recognize the passenger car 2 as such, so that by using the sensor data of the camera 3 or the front radar 7, a structure becomes possible, which suppresses the fade in the

High-beam assistant allows so that the driver of the passenger car 2 after overtaking the truck 1 is not blinded by its Femlicht, which remains suppressed. For detection by front radar 7, the

Passenger cars 2 not completely included in the opening angle of the radar. Rather, it is sufficient if the object to be detected, here so the

Passenger car 2, is only partially in the detection area to be reliably detected. In addition, via the front radar 7, moving vehicles, such as the passenger car 2, and already recognized as moving and later stopped vehicles can be reliably detected.

In the illustration of Figure 2 is a plan view of a similar situation is shown. This shows that a detection even at a greater distance between the truck 1 and the passenger car 2 with respect to the horizontal viewing angle of the camera 3, which is again denoted here by ß, may be difficult. In the illustrated embodiment, the passenger car 2, which is still at the shearing in front of the truck 1 after overtaking, not quite and therefore not reliably recognized as such. It would be desirable, however, already in this situation, according fade down the flared main beam, so suppress the actual high beam request. This is achieved in turn comparable to the example described above in that the front radar 7 typically has a much larger horizontal viewing angle γ. If the angle of view of the camera 3 in the horizontal as well as the angle of view in the vertical, for example, 50 °, then the viewing angle of the radar γ can be in particular about 90 ° and recorded, as can be seen from the illustration, the

Passenger cars 2 already much earlier.

Optionally, it is conceivable here that, in addition to the front radar 7, further radar sensors 8, 9 belong to the radar system, which are designed as so-called side radars, and detect the area laterally next to and obliquely in front of the truck 1. Their chosen in the representation of Figure 2 positioning is to be understood purely by way of example. Such side radars 8, 9 are often also used on the side of the vehicle, for example in the area of the wheel arches. Of course, such built directly on the side of the vehicle side radar also fall under the definition and idea of the invention. The additional use of the data of these optional side radars 8, 9, the detection can be further improved, and in particular the detection of the passenger car 2 at an even earlier date than when only the front radar 7 is used accordingly. It goes without saying that in an overhauling passenger car 2, as shown in a top view during the shearing in the representation of Figure 2, the vertical detection range explained in Figure 1 in addition to the horizontal detection range as shown in Figure 2.

Furthermore, it is possible to detect passenger cars 2 via the radar system and in particular the side radar 8, 9, which are exclusively located next to and not in front of the truck 1, so that it is not necessary to react to them. Of course, this also applies to unlit vehicles, which are parked or parked at the roadside. Again, such a vehicle can be sorted out very quickly and reliably via the radar system, since the missing movement is detected here. By the camera 3, this is in principle also possible, in which case a recognition of the unlit vehicle will primarily take place, since this is much better due to the camera capture as if the vehicle is moving or not. Here is the radar 7 and the radar system with the radars 7, 8 and 9, if available, an advantage.

The illustration of FIG. 3 shows an exemplary and preferred control unit network for implementing the functionality, again using the example of a high-beam assistant. The box marked 3 again symbolizes the camera 3, which could also be referred to as a front camera 3. In addition, the radar system 7 is in the form of the front radar. Dashed lines are also the optional

Side radars 8 and 9 shown on the left and right of the truck 1. Via a bus system 10, in particular the already existing CAN bus of the vehicle, the front camera 3, the front radar 7 and the two side radars 8, 9 are now connected to an assistance system control unit 11. This assistance system control unit 11 serves to control the high-beam assistant. Again via the CAN bus or possibly also an alternative bus system are this

 Assistance system control unit 11 more data known. Of course, the assistance system control unit 11 could also be designed differently and designed to be integrated in one of the environmental sensors 7, 8, 9 or the radar system or the camera 3, for example. In the illustration of FIG. 3, for example, the box labeled 12 symbolizes the communication interfaces to operating elements such as, for example, a light switch and the position of the high-beam lever. The box denoted by 13 symbolizes the communication interface for controlling the light, ie the active use of the high beam on the one hand or the low beam on the other hand. In addition, a status display is symbolized by the box designated 14, so that it is displayed in the cockpit that the high beam assistance system is active, and whether this is currently in one or the other mode. Part of such a control can also be a function for activating or deactivating the high-beam assistant. This can be performed, for example, in the box 14 with integrated, or be connected as an independent function on the bus system.

In the illustration of Figure 4 is now a functional representation of the merger of

Sensor data shown. A designated 15 box stands for the recognition of a lighted vehicle through the front camera 3. About the designated 16 box a moving vehicle is detected via the front radar 7. In addition to this, optionally via the side radars 8, 9 in the designated 17 box a corresponding Detection done. These data are now combined in box 18 via an OR link. As soon as a vehicle has been detected via the camera 3 or one of the radar sensors 7, 8, 9, a signal designated by 19 that a vehicle is ahead is thus generated. Via the communication interface 12 according to FIG. 3, further data can then be acquired and queried. Thus, for example, within the scope of the detection designated by the box 20, which can be effected in particular by a brightness sensor or the image processing of the data of the camera 3, it can be recognized whether it is light or dark. In the case of high brightness, the high beam is basically suppressed. The box marked 21 thus symbolizes that a day trip has been recognized. The box 22 asks more conditions. For this purpose, for example, images of the camera 3 can be evaluated, for example, so as to detect street lamps, for example. If street lamps are present, then in box 23, a trip is detected and passed on, for example, within the city or within a tunnel. The box 24 designates further alternative data, which may be included here, for example, the driving speed of the truck 1 or the like. In box 25, all these data 19, 21, 23, 24 are combined with each other via an OR operation. In the event that one of the data records is satisfied, then as indicated by the box 26, it comes to a suppression request for the automatic high beam. In addition, more features in the

Assist system control unit 11 with, for example, in the box 27, if the running light is turned on, in the box 28, the position of the main beam lever and in the box 29, if an automatic high beam is required, or if the driver would rather make the operation of the high beam itself ,

The high-beam assistance system is particularly advantageous if the headlights are designed so that they completely differentiate between an opened and a dimmed mode. This would be for example for halogen or

Xenon / bixenon headlights or so-called full-LED headlights are an advantage. Here is the preferred use of the high beam assistance system.

Claims

 claims

High-beam assistance system in a vehicle (1) with an optical camera (3), in which, depending on acquired data (19) of the camera (3) a

Control of an automatic high beam takes place

characterized in that

at least one further environmental sensor (7, 8, 9) is provided, which monitors at least one area not covered by the camera (3), wherein as a function of acquired data (19) of the at least one further

Environment sensor (7, 8, 9) an alternative control of the automatic high beam takes place.

High-beam assistance system according to claim 1,

characterized in that

the at least one further environmental sensor (7, 8, 9) is mounted so as to monitor an area laterally of the vehicle (1).

High-beam assistance system according to claim 2,

characterized in that

two environmental sensors (8, 9) are mounted so that they monitor both areas of the side of the vehicle (1).

High-beam assistance system according to claim 1, 2 or 3,

characterized in that

the at least one further environmental sensor (7, 8, 9 in one of a

Installation height (H) of the camera (3) deviating installation height (h) is mounted.

5. High-beam assistance system according to claim 4,

 characterized in that

 the further environmental sensor (7, 8, 9) is positioned below the camera (3).

6. High-beam assistance system according to one of claims 1 to 5,

 characterized in that

 the at least one further environmental sensor is a radar system (7, 8, 9).

7. High-beam assistance system according to claim 6,

 characterized in that

 the radar system comprises at least one front radar (7).

8. High-beam assistance system according to claim 6 or 7,

 characterized in that

 the radar system comprises at least one side radar (8,9).

9. High-beam assistance system according to one of claims 1 to 8,

 characterized in that

 Add further sensor data (21, 23, 24) from the vehicle (1) in the control of the automatic high beam.

10. Use of the high beam assistance system according to one of claims 1 to 9, in a commercial vehicle (1).