WO2010045903A1

WO2010045903A1 - Apparatus and method for controlling and/or regulating a vehicle using data on vehicles driving in adjacent lanes

Info

Publication number: WO2010045903A1
Application number: PCT/DE2009/001230
Authority: WO
Inventors: Ulrich STÄHLIN; Matthias Strauss
Original assignee: Continental Teves Ag & Co. Ohg
Priority date: 2008-10-21
Filing date: 2009-09-02
Publication date: 2010-04-29
Also published as: DE112009001740A5

Abstract

The invention relates to an apparatus for controlling and/or regulating operating parameters of a vehicle (1) using data on at least one other vehicle (2). Said apparatus comprises at least one driver warning and/or driver assistance system (10) for monitoring vehicles (2) driving in adjacent lanes (4), and an adaptive cruise control system (9). The driver warning and/or drive assistance system (10) and the adaptive cruise control system (9) are connected to transmit data in such a way that driving parameter data on vehicles (2) driving in adjacent lanes (4) and/or control and/or regulation data from the driver warning and/or driver assistance system (10) can be transmitted to the adaptive cruise control system (9).

Description

Device and method for controlling and / or regulating a vehicle using information about vehicles of adjacent lanes

The invention relates to an apparatus and a method for controlling and / or regulating an adaptive cruise control system of a vehicle using information about at least one further vehicle according to claim 1, 3 or 8.

Adaptive Cruise Control (ACC) and Fill Speed Range ACC (FSRA) are already well known to those skilled in the art. Similarly, Stop & Go ACC systems are already known from the state of the current development. Finally, lane change warning devices, also referred to as Lane Change Assist (LCA), are already well known to the skilled person from the prior art. All of these systems can be referred to as driver warning systems or driver assistance systems.

Today's ACC systems pay attention to the vehicle in front of their own vehicle and adjust the speed of their own vehicle if necessary to the speed of the preceding vehicle. Today's ACC systems are purely systems aimed at vehicles in front, other traffic situations are not intended as input information for today's ACC systems.

Today's lane change assistants (Lane Change Assist or Blind Spot Detection) monitor the rearward neighboring lanes (ie the left and right lanes of one's own vehicle) and warn the driver if a lane change due to a vehicle coming from behind would be dangerous. Today's lane change warning systems are therefore purely on vehicles of adjacent lanes directed systems, other traffic situations are not provided for today's lane change Wamsystemθ as input information. However, the aforementioned current systems are not networked, ie there is no data exchange or other interaction between these systems. So it is in the hitherto known prior art to systems that operate independently of each other and use completely different traffic situations or traffic information as input information, each of the systems is specialized in its respective traffic situation.

It is therefore an object of the present invention to improve a device or a method for controlling and / or regulating an adaptive cruise control system of a vehicle or a device for controlling and / or regulating operating parameters of a vehicle against this background.

This object is achieved by a device for controlling and / or

Control of an adaptive cruise control system of a vehicle with the features of claim 1 and a corresponding method with the features of claim 8 and by a device for controlling and / or regulating operating parameters of a vehicle according to claim 3. Further embodiments of the invention will become apparent from the dependent claims.

An essential idea of the invention is to provide an interaction, in particular a data exchange, between driver warning and / or driver assistance systems, such that information that is typically acquired and / or generated and / or used by a driver warning and / or driver assistance system now be made available to another driver warning and / or driver assistance system for its improved function. Thus, the information base for the function of a driver warning and / or

Driver assistance system in a simple and effective way broadened by already existing information from other driver warning and / or driver assistance systems in an advantageous manner be used. Thus, in particular the control and / or regulation of driver warning and / or driver assistance systems can be advantageously improved by creating a broader information base without additional hardware on wall such as additional sensors or the like.

The present invention relates in one embodiment to an apparatus for controlling and / or regulating an adaptive cruise control system of a vehicle using information about at least one other vehicle. The device according to the invention according to this embodiment has at least:

a monitoring device for monitoring vehicles of adjacent lanes,

a data generating device for generating monitoring data based on the monitoring of vehicles of adjacent traffic lanes,

a determination device for determining driving parameter data of vehicles of neighboring lanes from the monitoring data and

- A control and / or regulating device for controlling and / or regulating the Adaptive Cruise Control system based on the determined driving parameter data of vehicles of adjacent lanes.

In this case, the control and / or regulating device for controlling and / or regulating the Adaptive Cruise Control system can be designed as part of the Adaptive Cruise Control system itself, but it can also be designed as a device of another driver warning and / or driver assistance system. In principle, the control and / or regulating device can also be designed as a separate device outside of existing driver warning and / or driver assistance systems. All of the above applies in principle for the

Monitoring device, the data-generating device and / or the detection device, but at least one of these devices as a separate, separate from the Adaptive Cruise Control system Device is formed. Consequently, according to this embodiment of the invention, additional information for broadening the information base for the operation of the Adaptive Cruise Control system can be made available to the Adaptive Cruise Control system, namely information about vehicles of adjacent lanes.

An embodiment of the invention provides that at least the monitoring device and / or the data generation device and / or the determination device and / or the control and / or regulating device is designed as a device of another driver warning and / or driver assistance system. A special embodiment of this provides that the further driver warning and / or driver assistance system is designed as a lane change warning system.

In accordance with a further embodiment, the present invention relates to a device for controlling and / or regulating operating parameters of a vehicle using information about at least one further vehicle, comprising at least

a driver warning and / or driver assistance system for monitoring vehicles of adjacent lanes,

an adaptive cruise control system

- Wherein the driver warning and / or driver assistance system and the Adaptive Cruise Control system are connected in terms of data that driving parameter data of vehicles of adjacent lanes and / or control and / or control data from the driver warning and / or driver assistance system to the Adaptive Cruise Control system are communicable.

Also, according to this embodiment of the invention, therefore, the Adaptive Cruise Control System additional information for

Broadening the information base provided for the operation of the Adaptive Cruise Control system, namely - either directly or indirectly by way of control and / or regulation data - information about vehicles of neighboring lanes. A special embodiment of this provides that the driver warning and / or driver assistance system is designed as a lane change warning system.

An embodiment of the invention provides that the device and / or the system for determining driving parameter data is designed to determine speed parameter data of vehicles of adjacent lanes. In this case, the device and / or the system for determining driving parameter data may in particular be designed to determine average speeds and / or minimum speeds and / or maximum speeds and / or speed differences of vehicles of adjacent lanes and / or speed differences to vehicles of adjacent lanes and / or from the traffic density of vehicles of adjacent lanes. The driving parameter data can thus relate purely to the speed parameters of other vehicles, or also to a relation of speed parameters of the own vehicle to speed parameters of other vehicles. On the other hand or in addition, traffic densities such as e.g. Vehicles per unit time, per unit length or per unit angle are used.

With the monitoring of the adjacent lanes by the Fahrerwam- and / or driver assistance system, in particular by a lane change warning system such as the speed and the average speed of the vehicles are determined on these adjacent lanes, alternatively or additionally, the traffic density. The behavior of the ACC is adapted to these speeds or traffic density. Likewise, the information about the speed of the adjacent lane may be used if a speed limit is detected. If this speed limit is lower than the speed of the adjacent lane and is the vehicle in an overtaking process, for example, the ACC controls the speed limit only after the end of the overtaking process.

In one embodiment of the invention in this sense, it is provided that the Adaptive Cruise Control system in dependence on the

Speed parameter data can be controlled and / or regulated such that the acceleration behavior of the Adaptive Cruise Control system is variable as a function of this speed parameter data.

Thus, the behavior of the Adaptive Cruise Control system, e.g. when performing a lane change, to be adapted to speed parameters of vehicles of adjacent lanes and so on

Track changes are performed optimized.

Thus, e.g. On a multi-lane road, the average speed and / or the lowest speed of the adjacent lane are used to adjust the acceleration behavior of the Adaptive Cruise Control system to the difference between the current speed and the average speed or lowest speed of the secondary lane.

If, for example, it has been recognized that another vehicle has overtaken just before a lane change, then the acceleration can be adapted to the differential speed, ie low acceleration at low differential speed. Conversely, when approaching from behind a vehicle with a large differential speed and shears its own

Vehicle still off, so an adapted acceleration is selected.

The present invention relates in a further embodiment to a method for controlling and / or regulating an adaptive cruise control system of a vehicle using information about at least one further vehicle. The method has at least the following, automatically performed steps: monitoring of vehicles of adjacent lanes, Generation of monitoring data based on the monitoring of vehicles of adjacent traffic lanes,

Determination of driving parameter data of vehicles of neighboring lanes from the monitoring data and control and / or regulation of the Adaptive Cruise Control system on the basis of the determined driving parameter data of vehicles of neighboring lanes.

For this embodiment according to the invention, the previously said analog, i. Thus, additional information can be provided to the Adaptive Cruise Control system to broaden the information base for the operation of the Adaptive Cruise Control system, namely, information about vehicles of adjacent lanes. Again, the control and / or regulation of the Adaptive Cruise Control system can be performed in the Adaptive Cruise Control system itself, but it can also be performed in a facility of another driver control and / or driver assistance system or in a separate device.

An embodiment of the invention provides that, as part of the determination of driving parameter data, a determination of speed parameters of vehicles of adjacent traffic lanes takes place. In particular, in the context of the determination of driving parameter data, a determination of average speeds and / or minimum speeds and / or maximum speeds and / or

Speed differences of vehicles of adjacent lanes and / or speed differences to vehicles of adjacent lanes and / or the traffic density of vehicles of adjacent lanes occurs. The determination of the driving parameter data can thus extend purely to the speed parameters of other vehicles, or even to a relation of speed parameters of the own vehicle to speed parameters of others Vehicles. On the other hand or in addition, it is also possible to use traffic densities such as vehicles per time of day, per unit of length or per angular unit, as has already been carried out in the context of the devices according to the invention.

In one embodiment of the method according to the invention, it is provided that the Adaptive Cruise Control system is controlled and / or regulated as a function of the speed parameter data in such a way that the acceleration behavior of the Adaptive Cruise Control system is changed as a function of this speed parameter data. This in turn allows the behavior of the Adaptive Cruise Control system, e.g. when performing a lane change, be adapted to the speed parameters of vehicles adjacent lanes and so a lane change optimized to be performed.

A corresponding embodiment of the method according to the invention provides that speed parameter data of vehicles of adjacent lanes are compared with driving parameter data of the vehicle and checked for the presence of possible dangerous situations for the vehicle. This comparison may be e.g. based on stored models, optimal values or limits on driving parameter data and speed parameter data. If possible dangerous situations such as an accident or collision hazard are detected, the acceleration behavior of the Adaptive Cruise Control system is controlled and / or regulated in such a way that the dangerous situation is avoided. Alternatively or additionally, the driver can be warned visually or acoustically, for example, of the dangerous situation.

An embodiment of this inventive method provides that before a lane change driving parameter data on the acceleration behavior of the Adaptive Cruise Control system with Speed parameter data - eg regarding average speeds of vehicles of adjacent lanes and / or speed differences to vehicles of adjacent lanes - are compared. When recognizing possible dangerous situations - eg if that

Acceleration behavior is not sufficient for a lane change - in order to avoid a dangerous situation, the acceleration behavior of the Adaptive Cruise Control system is controlled and / or regulated in such a way that the vehicle is braked.

An alternative embodiment of the aforementioned method according to the invention provides that when obstacles are detected in the lane of the vehicle (for example with the aid of the abovementioned monitoring device) driving parameter data about the acceleration behavior of the Adaptive Cruise Control system with speed parameter data - e.g. relating to average speeds of vehicles of adjacent lanes and / or speed differences to vehicles of adjacent lanes. Upon detection of possible dangerous situations - e.g. if it is not possible to avoid the adjacent lane, the acceleration behavior of the Adaptive Cruise Control system is controlled and / or regulated in such a way that the vehicle is braked.

The invention thus comprises an adaptation of the behavior of an ACC to the speed and average speed of vehicles as well as the traffic density, which are determined by monitoring the lateral tracks by a lane change warning sensor system on these tracks.

Thus, on a multi-lane road, the average speed and / or the lowest lateral lane speed can be used to estimate the ACC's impact behavior on the difference adjust between current speed and average speed or lowest speed of the secondary lane.

If it has been recognized that another vehicle has overtaken just before the lane change, then the acceleration is adapted to the differential speed, ie low acceleration at low differential speed.

If a vehicle approaches from behind with a large differential speed and nevertheless shears off its own vehicle, an adapted acceleration is selected.

Also, the information about the speed of the sub-track may be used if a speed limit is detected. If this speed limit is lower than the speed of the secondary lane and if the vehicle is currently in an overtaking maneuver, the ACC will only adjust to the speed limit after the end of the overtaking maneuver.

Further advantages and possible applications of the present invention will become apparent from the following description in conjunction with the embodiments illustrated in the drawings.

In the description, in the claims, in the abstract and in the drawings, the terms and associated reference numerals used in the list of reference numerals recited below are used.

The drawings show in

1 control or regulation of an Adaptive Cruise Control

System with a control and / or regulating device arranged in a driver warning system Fig. 2 alternative control or regulation of an adaptive cruise

Control system with a control and / or regulating device arranged in the Adaptive Cruise Control system itself

In the following, identical and / or functionally identical elements can be provided with the same reference numerals. The absolute values and dimensions given below are only exemplary values and do not limit the invention to such dimensions.

1 shows the control or regulation of an adaptive cruise control system 9 (hereinafter also referred to for short as "ACC") of a vehicle 1 which is located on a first lane 3. In this case, information about at least one further vehicle 2, A control and / or regulating device 8 carries out a control and / or a regulation of the Adaptive Cruise Control system 9 on the basis of driving parameter data, which in relation to the at least one further Vehicle 2 were determined on the adjacent lane 4. As Fahrparameter- data here speed parameter data and possibly also or alternatively traffic density data of the adjacent lane 4 are used.

In order to achieve this, a monitoring device 5 is provided for monitoring vehicles 2 which are located on an adjacent lane 4. This monitoring device 5 is connected to a data generating device 6 for generating monitoring data based on the monitoring of vehicles 2 adjacent lanes 4 data technically. Furthermore, a determination device 7 for determining driving parameter data of vehicles 2 of adjacent lanes 4 from the monitoring data is provided, which in turn is connected to the data generation device 6 and to the control and / or regulating device 8 in terms of data technology. According to FIG. 1, the monitoring device 5, the data generation device 6, the determination device 7 and the control and / or regulating device 8 are designed as devices of a driver warning system 10 already present in the vehicle 1, namely as devices of a lane change warning system. It can therefore be used to implement the invention according to the embodiment of FIG. 1 simply on existing hardware. There are therefore no additional hardware requirements in the form of additional environmental sensors or the like.

FIG. 2 shows, as an alternative to the exemplary embodiment according to FIG. 1, an implementation of the invention in which the control and / or regulating device 8 is designed as a device of the Adaptive Cruise Control System 9. Again, can be used to implement the invention on existing hardware.

In the embodiments according to FIGS. 1 and 2, the driver warning system 10 (here in the form of a lane change warning system) and the adaptive cruise control system 9 are connected in terms of data technology such that speed parameter data and possibly also or alternatively traffic density data of the adjacent lane 4 of the driver warning system 10 to the control and / or regulating device 8 and the Adaptive Cruise Control System 9 can be transmitted.

For example, the average speed and / or the lowest speed of the vehicles 2 on the adjacent lane 4 may be used to determine the acceleration behavior of the adaptive cruise control system 9 to the difference between the current speed and the average speed or lowest speed of the adjacent lane 4 adapt. If it has now been recognized, for example, that another vehicle has overtaken just before a lane change of the vehicle 1, then the ACC 9 is automatically controlled or regulated such that the acceleration is adapted to the differential speed, ie low acceleration at low differential speed. If, on the other hand, a vehicle 2 approaches from behind with a large differential speed and nevertheless shears off its own vehicle 1, then the ACC 9 is automatically selected or regulated in such a way as to select a suitable acceleration.

1st example:

The vehicle 1 drives with activated ACC 9 on a highway and has set as Setspeed 200 km / h. However, the front vehicle only allows a speed of 130 km / h. On the left secondary lane 4 drives a vehicle 2 with 150 km / h over. The driver of the vehicle 1 shears shortly behind this vehicle 2 on the adjacent lane 4. By knowing the difference speed to the vehicle 2, the ACC 9 accelerates only moderately.

2nd example:

The vehicle 1 drives with activated ACC 9 on a highway and has set as Setspeed 200 km / h. However, the front vehicle only allows a speed of 130 km / h. Therefore, the driver of vehicle 1 shears off on the adjacent lane 4. Shortly before, however, the system 9, 10 has recognized that from behind a vehicle 2 approaches at 180 km / h. Therefore, the ACC 9 accelerates greatly to avoid a dangerous situation.

Example 3: A vehicle 1 is driving on a motorway with activated ACC 9 and has entered a set speed of 200 km / h. However, the front vehicle only allows a speed of 130 km / h. Therefore, the driver of vehicle 1 shears off on the adjacent lane 4. About the lateral sensors, so the monitoring device 5, the data generating device 6 and the detection device 7 was previously recognized that the

Average speed on this track is about 160 km / h, but not overly dense traffic. Therefore the ACC 9 accelerates only moderate and only up to a little over 160 km / h, so as not to force unnecessary braking.

Example 4: The vehicle 1 drives on a motorway with activated ACC 9 and has entered 200 km / h as Setspeed. However, the front vehicle only allows a speed of 130 km / h. Therefore, the driver of vehicle 1 shears off on the adjacent lane 4. By means of the lateral sensors, that is to say the monitoring device 5, the data generation device 6 and the determination device 7, it was previously recognized that the

Average speed on this adjacent lane 4 is about 160 km / h, but with very dense traffic. Therefore, the ACC 9 accelerates sharply to get as fast as possible on the average speed of the adjacent lane 4 and to allow a liquid traffic.

5th example:

The vehicle 1 with activated ACC 9 overtakes a preceding vehicle 2 on a single-lane road. First of all, therefore, both vehicles are located on a common traffic lane 4. The vehicle here drives 90 km / h. In the middle of the overtaking process both vehicles 1, 2 reach a zone with an allowed speed of 80 km / h. The system of the vehicle 1 recognizes that there is still a vehicle 2 - now on an adjacent lane 4 - located next to the vehicle 1 and vehicle 1 is in an overtaking process and therefore sets the

Speed limit not in ACC 9 um. Only after the overtaking process is completed and vehicle 1 is back in the original lane 1, the ACC 9 controls the speed limit of 80 km / h.

6th example

The vehicle 1 drives with activated ACC 9 on a highway and has set as Setspeed 200 km / h. The front vehicle, however, leaves only one Speed of 80 km / h too. On the adjacent lane 4 a very high average speed of 180 km / h is determined. If the acceleration behavior of the vehicle 1 is not sufficient to reliably perform a lane change, then the driver is already warned when approaching (that is, when accelerating). Should it nevertheless come to a dangerous situation, the vehicle 1 can also brake at the last possible moment to avoid an accident.

7. Example The vehicle 1 drives on a motorway with activated ACC 9 and has entered 200 km / h as Setspeed. However, the front vehicle only allows a speed of 130 km / h. Suddenly the front vehicle brakes hard. At the same time it is recognized that there is no possibility to dodge on the secondary lanes. In such a situation, emergency braking by the activated ACC 9 can take place more autonomously and earlier and a threatening accident can be avoided.

reference numeral

1 vehicle 2 additional vehicle

3 lanes

4 adjacent lane

5 monitoring device

6 Data generating device 7 Determining device

8 control and / or regulating device

9 Adaptive Cruise Control Systems

10 driver warning and / or driver assistance system

Claims

claims

A device for controlling and / or regulating an adaptive cruise control system (9) of a vehicle (1) using information about at least one further vehicle (2), comprising at least

- A monitoring device (5) for monitoring vehicles (2) adjacent lanes (4), - a data generating device (6) for generating

Monitoring data based on the monitoring of vehicles (2) of adjacent traffic lanes (4),

- A determination device (7) for determining driving parameter data of vehicles (2) of adjacent lanes (4) from the monitoring data and

- A control and / or regulating device (8) for controlling and / or regulating the Adaptive Cruise Control System (9) on the basis of the determined driving parameter data of vehicles (2) adjacent lanes (4).

2. Device according to claim 1, characterized in that at least the monitoring device (5) and / or the data generating device (6) and / or the detection device (7) and / or the control and / or regulating device (8) as a device of another Driver warning and / or driver assistance system (10) is formed.

3. Device for controlling and / or regulating operating parameters of a vehicle (1) using

Information about at least one further vehicle (2), comprising at least

- A driver warning and / or driver assistance system (10) for monitoring of vehicles (2) of adjacent lanes (4),

an Adaptive Cruise Control System (9),

- Wherein the driver warning and / or driver assistance system (10) and the Adaptive Cruise Control System (9) are connected in terms of data, driving parameter data of vehicles (2) adjacent lanes (4) and / or control and / or control data from the driver warning and / or driver assistance system (10) to the Adaptive Cruise Control System (9) can be transmitted.

4. Apparatus according to claim 2 or 3, characterized in that the driver warning and / or driver assistance system (10) is designed as a lane change warning system.

5. Device according to one of claims 1 to 4, characterized in that the device (7) and / or the system (10) for determining driving parameter data is designed to determine speed parameter data of vehicles (2) of adjacent lanes (4). ,

6. The device according to claim 5, characterized in that the device (7) and / or the system (10) for determining driving parameter data is designed to determine

Average speeds and / or minimum speeds and / or maximum speeds and / or speed differences of vehicles (2) of adjacent lanes (4) and / or speed differences to vehicles (2) of adjacent lanes (4) and / or traffic density of vehicles (2) adjacent Lanes (4).

7. Device according to one of claims 5 or 6, characterized in that the Adaptive Cruise Control System (9) is controllable and / or controllable in dependence on the speed parameter data such that the acceleration behavior of the Adaptive Cruise Control System (9) is variable as a function of this speed parameter data.

8. A method for controlling and / or regulating an adaptive cruise control system (9) of a vehicle (1) using information about at least one further vehicle (2), comprising at least the automatic steps

Monitoring of vehicles (2) of adjacent lanes (4),

Generation of monitoring data based on the monitoring of vehicles (2) of adjacent lanes (4), determination of driving parameter data of vehicles (2) of adjacent lanes (4) from the monitoring data and

- Control and / or regulation of the Adaptive Cruise Control System (9) on the basis of the determined driving parameter data of vehicles (2) adjacent lanes (4).

9. The method according to claim 8, characterized in that in the context of the determination of driving parameter data, a determination of speed parameters of vehicles (2) of adjacent lanes (4).

10. The method according to claim 9, characterized in that within the determination of driving parameter data, a determination of average speeds and / or minimum speeds and / or maximum speeds and / or speed differences of vehicles (2) adjacent lanes (4) and / or speed differences to vehicles (2) adjacent lanes (4) and / or the traffic density of vehicles (2) adjacent lanes (4).

11. The method according to any one of claims 9 or 10, characterized in that the adaptive cruise control system (9) in response to the speed parameter data is controlled and / or regulated so that the acceleration behavior of the Adaptive Cruise Control System (9) in Dependence of this speed parameter data is changed.

12. The method according to claim 11, characterized in that

Velocity parameter data of vehicles (2) of adjacent lanes (4) are compared with driving parameter data of the vehicle (1) and checked for the presence of possible danger situations for the vehicle (1) and that, when possible dangerous situations are identified, the acceleration behavior of the adaptive cruise control system ( 9) is controlled and / or regulated such that the dangerous situation is avoided and / or the driver of the vehicle (1) is warned of the dangerous situation.

13. The method according Anspuch 12, characterized in that prior to a lane change driving parameter data on the

Acceleration behavior of the Adaptive Cruise Control system (9) with speed parameter data of vehicles (2) of adjacent lanes (4) are compared and on detection of possible dangerous situations, the acceleration behavior of the Adaptive Cruise Control System (9) is controlled and / or regulated so that the Vehicle (1) is braked.

14. The method according Anspuch 12, characterized in that upon detection of obstacles in the lane (3) of the vehicle (1) driving parameter data on the acceleration behavior of the Adaptive Cruise Control System (9) with speed parameter data of vehicles (2) adjacent lanes (4) are compared and the acceleration behavior of the Adaptive Cruise Control System (9) is controlled and / or regulated in such a way that the vehicle (1) is braked when recognizing possible dangerous situations.