EP1689615A1

EP1689615A1 - Method and device for warning the driver of a motor vehicle

Info

Publication number: EP1689615A1
Application number: EP04762454A
Authority: EP
Inventors: Dirk Meister; Ulrike Ahlrichs; Ulf Wilhelm; Paco Haffmans
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2003-11-28
Filing date: 2004-07-22
Publication date: 2006-08-16
Also published as: DE10356309A1; US20070282530A1; JP4974220B2; US7363155B2; JP2007512598A; WO2005054008A1

Abstract

The invention relates to a method and a device for warning the driver of a motor vehicle of a traffic situation with a high collision risk. According to the invention, signals of at least one object detector, which represent the displacement variables of detected objects, in addition to the signals of at least one displacement sensor system of the driver's vehicle, can be fed to an evaluation device. The calculation unit calculates displacement trajectories for a predetermined duration for all detected objects and the driver's vehicle, taking into consideration maximum acceleration or deceleration values and maximum temporal modifications to acceleration or deceleration values. If an imminent collision is identified, the driver is issued with a warning that greater acceleration or deceleration values and/or temporal modifications to acceleration or deceleration values are required, in order to avoid a collision.

Description

Method and device for warning the driver of a motor vehicle

The present invention relates to a method and a device that warns the driver of a motor vehicle that there is a traffic situation with an increased risk of collision. For this purpose, signals of at least one object detector, which represent motion variables of detected objects, and signals of at least one of their own motion sensors can be fed to an evaluation device. The calculation device calculates in advance all possible movement trajectories for all detected objects and for one's own vehicle, taking into account maximum acceleration values or deceleration values and maximum temporal acceleration change values or deceleration change values, and, when it detects that a collision is imminent, issues a warning to the driver that higher Acceleration values or deceleration values and / or

Acceleration change values or deceleration change values are necessary in order to avoid a collision. Hierbai this can be calculated in advance for a predetermined period of time, but a fixed time frame is not absolutely necessary for the calculation in advance.

State of the art

From WO 03/006291 a method and a device for triggering and executing a deceleration of a vehicle to avoid a collision is known, in which objects in the sensor detection area are recognized by means of a device for distance and speed control of the vehicle and measurement variables are determined for each recognized object , the recognized objects based on the determined, associated measured variables of different object classes are assigned and the movement trajectories of the objects are predicted on the basis of the assignment of the recognized objects to the respective class.

WO 03/006290 discloses a method and a device for controlling deceleration devices of a vehicle during a braking operation, in particular a vehicle, which is equipped with a sensor for adaptive cruise control. During the braking operation, hazard measurements are determined on the basis of dynamic vehicle models that are individualized by signals from the environment sensors.

Core and advantages of the invention

The essence of the present invention is to warn the driver of a motor vehicle equipped with an object detection device of driving situations with an increased risk of collision, in which the driver is informed in good time that acceleration or deceleration values and / or acceleration or deceleration change values are used Avoidance of a collision are necessary, which represent a movement dynamics of the vehicle, which lie above the vehicle dynamics felt to be comfortable. This signals to the driver that he has to implement highly dynamic vehicle accelerations or vehicle decelerations in the longitudinal and / or transverse direction in order to defuse an impending collision with another vehicle. According to the invention, this is solved by the features of the independent claims. Advantageous further developments and refinements result from the subclaims.

The maximum acceleration values or deceleration values and the maximum temporal acceleration change values or deceleration change values are advantageously dimensioned such that the driver just perceives them as comfortable.

Furthermore, it is advantageous that different maximum values and temporal change maximum values are provided for the longitudinal vehicle acceleration, the longitudinal vehicle deceleration and the lateral vehicle acceleration. The maximum acceleration values or deceleration values and the maximum temporal acceleration values or deceleration change values can advantageously be varied as a function of the instantaneous vehicle speed. For example, it can be provided that at higher longitudinal vehicle speeds, higher acceleration or deceleration values and / or higher temporal acceleration or Delay change values are provided.

Furthermore, it is advantageous that the maximum acceleration values or deceleration values and the maximum temporal acceleration change values or deceleration change values can be varied depending on the driving situation recognized by the object detector.

Furthermore, it is advantageous that, in addition to the driver warning, an automatic intervention in the vehicle drive devices, the vehicle deceleration devices and / or the vehicle steering devices can be output.

The at least one object detector is advantageously a radar sensor, a laser sensor, an ultrasonic sensor or a video sensor or a combination thereof.

It is also advantageous that the motion sensor system is at least one speed sensor, an acceleration sensor and / or a yaw rate sensor.

Of particular importance is the implementation of the method according to the invention in the form of a control element which is provided for a control device. In this case, a program is stored on the control device, which is executable on a computing device, in particular on a microprocessor or signal processor, and is suitable for executing the method according to the invention. In this case, the invention is thus implemented by a program stored on the control element, so that this control element provided with the program represents the invention in the same way as the method for the execution of which the program is suitable. In particular, an electrical storage medium, for example a read-only memory, can be used as the control element.

Further features, possible applications and advantages of the invention result from the following description of exemplary embodiments of the invention, which in the figures of the drawing are shown. All of the features described or illustrated, individually or in any combination, form the subject matter of the invention, regardless of their summary in the patent claims or their relationship, and regardless of their formulation or representation in the description or in the drawings.

drawings

Embodiments of the invention are explained below with reference to drawings. Show it

1 shows an exemplary traffic situation in which the device according to the invention and the method according to the invention can be used, FIG. 2 shows a model of the situation shown in FIG. 1 with the areas of stay derived from the possible movement trajectories, FIG. 3 shows a schematic block diagram of an embodiment of the device according to the invention and FIG. 4 a flow diagram of an embodiment of the method according to the invention.

Description of exemplary embodiments

FIG. 1 shows a single-lane road on which a false lane is provided for each direction of travel. Of course, the method according to the invention and the device according to the invention can also be used for oncoming traffic in driving situations on multi-lane roads with or without lanes. You can see your own vehicle 1, which is equipped with an object detector 2. This object detector 2 can be, for example, a radar sensor, a laser sensor, a video sensor, an ultrasound sensor or a combination thereof and can be attached, for example, in the vehicle front area or in the area of the windshield. The object detector 2 is advantageously aligned such that the sensor detection area 3 detects the area in front of the vehicle 1 and detects objects 5, 6 located therein. A preceding vehicle 5, which in the present case is moving in the same direction at speed VI, drives in front of one's own vehicle 1, which is moving on the road at speed V. There is also another vehicle 6 available, which moves at the speed V2 in the opposite direction. The object detector 2 now recognizes the vehicles 5, 6 and can determine the distance d between these vehicles and their own vehicle, their relative speed vrel with respect to their own vehicle 1 and the azimuth angle alpha, which in combination with the distance d relates to the position of the vehicles 5, 6 the vehicle longitudinal axis of the own vehicle 1 is determined. Furthermore, a coordinate system 4 is shown, which is advantageously a world coordinate system, that is to say represents a stationary coordinate system. Here, a first X axis is provided in the vehicle longitudinal direction and a further Y axis which is aligned in the vehicle transverse direction.

FIG. 2 shows the coordinate system 4, which corresponds to the world coordinate system from FIG. 1. The X-axis, which is aligned in the vehicle longitudinal axis and the Y-axis, which is aligned in the vehicle transverse direction, can again be seen in FIG. At the origin of the coordinate system 4, there is a model of one's own vehicle 1, on the X-axis in the range of positive X values is the model of the preceding vehicle 5 shown in front and the oncoming vehicle 6, which positions with an offset in the direction of negative Y values is. A movement trajectory is calculated for a predetermined, future period of time t for the maximum accelerations or maximum decelerations as well as the maximum temporal acceleration changes or deceleration changes which are just perceived as comfortable by an average driver. Combinations of deceleration, acceleration or steering intervention by the driver are also considered here, so that all the maximum attainable points within the calculation period t are determined, which are entered with respect to the coordinate system moving with the vehicle 1. For this purpose, the relative speed vrel of the other vehicles 5, 6 and their absolute speeds VI, V2 are also taken into account, which can be calculated from knowledge of the relative speeds and the speed V of the driver's own vehicle 1. If these points are plotted in the fixed coordinate system 4, regions 7, 8, 9 result around the recognized vehicle stop positions 1, 5, 6, which are also at different distances in different directions. For example, a driver still feels a vehicle deceleration as comfortable if it is greater in terms of amount than the maximum longitudinal acceleration value that the driver feels just barely comfortable. An average driver is essential when it comes to lateral vehicle acceleration more sensitive, so that the distances between the maximum trajectory areas 7, 8, 9 in the vertical direction to the vehicle movement direction are smaller than in the vehicle longitudinal direction, the maximum trajectory area opposite the vehicle movement direction being larger than the maximum trajectory area in the vehicle movement direction, since the driver perceives larger longitudinal deceleration values as comfortable , the longitudinal acceleration values and the acceleration and deceleration values, which are considered to be absolute, are comfortable as lateral transverse accelerations, such as occur, for example, as a result of steering maneuvers. This results in maximum movement trajectory regions 7, 8, 9, as are recorded in FIG. 2. These maximum trajectory areas take the form of deformed ellipses, the main ellipse axes being aligned in the vehicle longitudinal direction and the ellipse minor axes being aligned in the vehicle transverse direction. The main ellipse axes have much larger areas in the deceleration direction, which can be referred to as an elliptical tail, because the driver considers decelerations larger in magnitude to be comfortable than, for example, accelerations that represent the shorter main ellipse axes in the direction of travel and the amount of the minor ellipse axes is smaller than the main ellipse axes because an average driver reacts very sensitively to vehicle lateral accelerations and finds them uncomfortable even with small amounts.

An evaluation device 10 is shown in FIG. 3, which has, among other things, an input circuit 11. Input signals are fed to the evaluation device 10 by means of the input circuit 11. On the one hand, signals from an object detector 2 are provided as input signals, which can be designed, for example, as a radar sensor, laser sensor, ultrasound sensor, video sensor or as a combination of these sensor types. This object detector 2 detects objects 5, 6 which move within the detection area 3 and determines their distance d from the own vehicle 1, the relative speed V _re ι of the objects 5, 6 with respect to the own vehicle 1 and the azimuth angle alpha at which the objects 5, 6 currently stop with respect to the axis of symmetry of the detection area 3. It is also possible to determine further variables using the object detector 2, for example what type of object it is, for example whether this is a moving vehicle or a stationary object on the roadside or whether it is a passenger vehicle, a truck or a vehicle Two-wheeler deals. These determined quantities are from the object detector 2 of the input circuit 1 1 of the evaluation device 10 fed. Furthermore, a speed sensor 12 is provided, which determines the speed V of one's own vehicle 1 and feeds it to the evaluation device 10. Knowing one's own speed V makes it possible to convert the relative variables Vrel determined by means of the object detector 2 into absolute variables VI, V2. A speed sensor 12 provided specifically for this purpose can be provided as the speed sensor 12, or a speed sensor 12 can be used which is provided for further vehicle functions, for example for an anti-lock device of the vehicle 1 or a driving dynamics control. Furthermore, a signal of an acceleration sensor 13 is fed to the evaluation device 10 via the input circuit 11, which advantageously detects longitudinal accelerations and lateral accelerations of the own vehicle 1 separately and feeds them to the evaluation device 10. The acceleration sensor 13 can alternatively also be dispensed with and the acceleration signal a can be calculated from a temporal differentiation of the speed signal V of the speed sensor 12. In addition to the devices described for providing input variables, it is also possible for further devices 14 to be provided, for example an operating device by means of which the driver of the vehicle 1 can change the operating states of the evaluation device 10 or adjust its settings to his individual wishes. The input signals fed to the input circuit 11 are forwarded by means of a data exchange system 15 to a computing device 16, which can be designed, for example, as a microprocessor or signal processor. Depending on the input signals supplied to it, the calculation device 16 determines manipulated variables for output to downstream actuators 18, 19, 20, in which the input variables are processed according to the method according to the invention and output variables are determined therefrom. The output variables determined by the calculation device 16 are fed to an output circuit 17 by means of a data exchange system 15, by means of which the evaluation device 10 outputs manipulated variables to downstream actuators 18, 19, 20. As an actuator, for example, an acoustic and / or visual warning device is provided, which is given to the driver in the form of a warning light or a plain text display, which can be attached, for example, in the area of the dashboard of the vehicle and by means of which a warning can be issued. Furthermore, the acoustic and / or optical warning device can emit an acoustic warning signal, which can be, for example, a signal tone or a text output that explicitly states the reason for the warning to the driver. It is also possible alternatively or in combination to provide reversible belt tensioners 19 as a warning device, which signal by one or more pretensioning of the seat belt of the driver or all vehicle occupants that the comfort limits with regard to vehicle acceleration or deceleration and / or the comfort limits with regard to the rate of change in acceleration or deceleration change over time have been exceeded , and higher accelerations or decelerations and / or higher temporal acceleration or deceleration change values are necessary to prevent a collision situation. Furthermore, as an alternative or in combination, it is also possible, by means of the delay devices 20, to which an output signal from the evaluation device 10 can be fed, to notify the driver of a corresponding warning signal by briefly decelerating the vehicle. The provision of a short deceleration by means of the deceleration devices also has the advantage that this brief braking of the vehicle allows the coefficient of friction of the road to be determined and that the coefficient of friction of the road is known with regard to a later, sharp deceleration of the vehicle to prevent a collision, and accordingly Delay can be controlled. In addition, the driver is informed intuitively by briefly braking the vehicle that there is a dangerous situation.

FIG. 4 shows an embodiment of the method according to the invention, which can run, for example, in the form of a control program in the computing device 16. After the start of the method at the “start” point, the object data which, for example, the object detector 2 has determined and is made available to the evaluation device 10 are read in in method step 21. In the subsequent method step 22, the movement data of the own vehicle 1, for example the own vehicle speed, are read V as well as your own vehicle acceleration A. Furthermore, it is possible to infer a specific driving situation of the vehicle 1 based on detected, stationary or moving objects within the detection area 3, for example whether it is a single-lane or multi-lane road, whether the road in the further driving course has curves or is recognized more as a straight, highway-like road, and possibly how large the traffic density in the section of the road ahead is due to the data supplied to the evaluation device 10 in the further method step 23 motion trajectory jectories for the recognized vehicles 5, 6 and the own vehicle 1 are calculated. When calculating the movement trajectories, the determined driving situation is taken into account on the one hand and the maximum is assumed on the other Vehicle longitudinal and lateral accelerations or maximum temporal longitudinal or lateral acceleration change values, wherein the accelerations can also be decelerations, which calculate the maximum reachability of the objects within the time period t, while adhering to assumed comfort limits. In a further step 24, it is determined whether a collision can be avoided. In this case, an increase in the vehicle acceleration or deceleration and / or an increase in the temporal acceleration change values or deceleration change values is required, as a result of which the movement trajectory regions 7, 8, 9 are enlarged by larger regions being created by highly dynamic vehicle maneuvers, by means of which a collision can be avoided. If it was determined in step 24 that a collision can be avoided, for example in that there is a remaining area of the trajectory areas 7, 8, 9 that has no overlap, the flowchart branches to “yes” and continues at step “end”. If it was determined in method step 24 that a collision while maintaining the comfort limits is unavoidable, for example because there is no remaining area without overlap taking the comfort limits into account, then step 24 branches to "No" and in the subsequent method step 25 a driver warning is issued by means of one or more of the Warning devices 18, 19, 20. After the driver warning has been issued in step 25, the flowchart is continued in step "End" and branches again to "Start", from where it is run through again.

Claims

claims

1. A method for warning the driver of a motor vehicle (1) that there is a traffic situation with an increased risk of collision, in that signals can be fed to an evaluation device (10) of at least one object detector (2), which represent movement variables of detected objects (5, 6); by supplying signals to at least one of its own motion sensors (12, 13) to an evaluation device (10), characterized in that the evaluation device (10) takes into account all possible motion trajectories for all detected objects (5, 6) and for one's own vehicle (1) maximum acceleration values or deceleration values and maximum temporal acceleration change values or deceleration change values, calculated in advance (23), and upon detection that a collision is imminent, the driver is given a warning (18, 25) that higher acceleration values or deceleration values (amax) and / or acceleration change values or deceleration change values (amaxpunkt) are necessary to avoid a collision.

2. The method according to claim 1, characterized in that the maximum acceleration values or deceleration values (amax) and the maximum temporal acceleration change values or deceleration change values (amaxpunkt) are dimensioned such that the driver just feels them as comfortable.

3. The method according to claim 1 or 2, characterized in that different maximum values and temporal change maximum values are provided for the longitudinal vehicle acceleration, the longitudinal vehicle deceleration and the lateral vehicle acceleration.

4. The method according to any one of the preceding claims, characterized in that the maximum acceleration values or deceleration values (amax) and the maximum temporal acceleration change values or deceleration change values (amaxpunkt) can be varied depending on the current vehicle speed (v).

5. The method according to any one of the preceding claims, characterized in that the maximum acceleration values or deceleration values (amax) and the maximum temporal acceleration change values or

Deceleration change values (amaxpunkt) can be varied depending on the driving situation detected by the object detector (2).

6. The method according to any one of the preceding claims, characterized in that in addition to the driver warning (18) an automatic intervention in the vehicle drive devices, the vehicle deceleration devices (20) and / or the vehicle steering devices can be issued.

7. Device for warning the driver of a motor vehicle (1) that there is a traffic situation with an increased risk of collision, which has an evaluation device (10), at least one object detector (2), can be determined by means of the movement variables of detected objects (5, 6) and Evaluation device (10) can be fed in that at least one motion sensor system (12, 13) is provided, by means of which signals can be fed to the evaluation device (10), which represent the movement of one's own vehicle (1), characterized in that the evaluation device (10) for all detected objects (5,6) and for your own vehicle (1) all possible movement trajectories, taking into account maximum acceleration values or deceleration values (amax) and maximum temporal acceleration change values or deceleration change values (amaxpunkt), calculated in advance, and a driver warning device by the evaluation device ( 18, 19) can be activated, the Driver reports that higher acceleration values or deceleration values and / or acceleration change values or deceleration change values are necessary in order to avoid a collision.

8. The device according to claim 7, characterized in that the at least one object detector (2) is a radar sensor, a laser sensor, an ultrasonic sensor, a video sensor or a combination thereof.

9. The device according to claim 7 or 8, characterized in that the movement sensor system (12, 13) is at least one speed sensor, an acceleration sensor and / or a yaw rate sensor.