EP1656282A1

EP1656282A1 - Motor vehicle provided with a pre-safe system

Info

Publication number: EP1656282A1
Application number: EP04763891A
Authority: EP
Inventors: Wilfried Bullinger; Michael Fehring; Florent Résidence L'Orée du Parc PAVIOT; Alfred Wagner
Original assignee: DaimlerChrysler AG
Current assignee: Mercedes Benz Group AG
Priority date: 2003-08-23
Filing date: 2004-08-06
Publication date: 2006-05-17
Also published as: US20070131468A1; WO2005021337A1; DE10338760A1; JP2007533521A

Abstract

The invention relates to a motor vehicle (1) provided with a pre-safe system (2) comprising active and/passive safety devices (13, 14) which are actuated according to information received by at least one environmental detecting device (4) of the vehicle and by a driving situation data recording device (5), said information being analysed by a data evaluation device (10). At least one element of the active and/passive safety devices (13, 14) is actuated when information of the environmental detecting devices (4) of the vehicle displays a potential collision object (11) and when the driving situation data input device (5) predicates a collision plausibility.

Description

Motor vehicle with a pre-safe system

The invention relates to a motor vehicle with a pre-safe system according to the closer defined in the preamble of claim 1. Art.

Passenger cars and commercial vehicles of recent design have active and passive safety devices that allow the driver to better control his vehicle even in critical situations and thereby possibly to avoid an accident of the vehicle. Furthermore, such safety devices in the event of a crash contribute to a reduction in the severity of the accident.

Safety systems that are already preventively effective against a possible accident and a so-called pre-crash phase, d. H. a period from detection of a high probability of accidents by appropriate detection systems in the vehicle to the actual impact, to use to extend occupant protection through the use of additional security measures and to reduce the severity of accidents are referred to as pre-safe systems.

An essential component of such a Pre-Safe Syste s is a vehicle environment detection sensor, which is known in various designs. For example, EP 0 952 459 A2 describes an object detection apparatus for motor vehicles, which has a distance sensor system formed by a plurality of distance sensors, wherein the distance sensors are arranged on the motor vehicle such that they scan the surroundings of the motor vehicle , Furthermore, an evaluation unit is provided which determines the trajectory and the speed of an object relative to the motor vehicle from the data of the distance sensor system, wherein the distance sensors can be selectively controlled by the evaluation unit and the range and / or the measurement repetition frequency and / or the Resolution and / or the operating mode of the distance sensors are variable. This device can simultaneously or sequentially provide data for various driver assistance devices and be used as a pre-crash sensor.

DE 197 29 960 AI describes a method for impact detection, especially in motor vehicles for activating occupant protection devices, wherein at least one pre-crash sensor is provided, which changes the relative speed and / or the relative distance of objects within a predetermined short range of Vehicle environment registered. If the change in the relative speed detected by the pre-crash sensor exceeds at least one predefined threshold value and / or the relative distance falls below a predefined threshold value, this is recognized as a safety-critical condition and the triggering threshold is reduced.

Another method for impact detection in a motor vehicle is known from DE 101 00 880 AI, which are provided as pre-Chrash sensors radar sensors by means of whose signals determine an effective mass of a target object. The effective mass is compared with predetermined thresholds for classifying the impact object, the classification then determining the use of restraints.

A further method for triggering restraint means in a motor vehicle in the event of an impact or a collision with an object is described in DE 100 65 518 A1. In the context of this known method, the time profile of the acceleration in the form of at least one acceleration signal is detected and generated from the acceleration signal, the time course of a speed. A triggering of restraint means adapted to the specific impact situation is achieved by determining the impact velocity and the impact instant before the impact with the aid of a pre-crash sensor, classifying the impact situation on the basis of the impact velocity, and classifying the impact situation a triggering time window is determined, in which the time profile of the speed is generated, and that, in parallel to this, a threshold value for the speed is determined from the acceleration signal, the classification of the impact situation being taken into account. If this pre-crash sensor system comprises at least two suitably arranged pre-crash sensors, the offset, that is to say the impact point and the impact angle, can additionally be determined by means of a triangulation method. As part of the pre-crash sensing, for example, radar measurements, infrared measurements or optical measuring methods can be used here.

An example of a pre-crash sensing system with an image capture device for optical detection of spaced objects is disclosed in DE 198 42 827 AI.

However, all known types of vehicle environment recognition devices have the common disadvantage that, depending on the technology and system design, they more or less frequently detect an object that is only apparently present and thus trigger a "false alarm", which is an undesirable activation of numerous active and passive safety systems z. As reversible belt tensioner, movable bumper, hard-adjustable impact elements and provided for a crash case control of a level control or the braking and steering system can result.

On the other hand, in the known, highly faulty vehicle environment recognition devices, an actual crash-relevant object may not be detected, whereby the deployment of occupant protection systems is delayed and possibly only during the impact itself, so that there is no time for optimal conditioning of vehicle restraint systems and inmates to the imminent accident remains.

An example for driving a reversible occupant protection means in a motor vehicle in a pre-safe system is disclosed in DE 101 21 386 C1. In this case, the driving state data are monitored with regard to an emergency braking state, and when the emergency braking state is determined, the passenger protection system is activated. A data processing device additionally determines a state of oversteer and a state of understeer. If the state of emergency braking and / or the state of oversteer and / or the state of understeer is detected by the data processing device, the reversible occupant protection system is actuated. A disadvantage of this solution, however, is that only vehicle-side data are processed by using already existing in the vehicle sensors without the inclusion of environmental data. Thus, it is not possible to carry out the deployment of the occupant protection means depending on the type of impact situation and the collision object.

It is therefore an object of the present invention to provide a motor vehicle with a pre-safe system according to the aforementioned type, which benefits the advantages of a vehicle environment recognition device and in which a false alarm rate of the pre-safe system with an unnecessary activation is reduced by presumptive occupant protection systems.

In a motor vehicle with a pre-safe system according to the type mentioned in the preamble of claim 1, this object is achieved in that an activation of at least a portion of the active and / or passive safety devices takes place when the information of the vehicle environment detection device is a potential Represent collision object and the data of a driving situation data acquisition device represent a driver behavior which is predefined for a collision plausibility.

In the solution according to the invention, consequently, the signals of the sensors of the vehicle environment recognition device with certain characteristics that describe the driver behavior, linked and used only to trigger the active and / or passive safety devices of the motor vehicle, if in the presence of a collision object and a corresponding driver behavior is present. Through plausible The detection of the findings of the vehicle environment recognition device by means of the driver's usually occurring reaction when the latter himself recognizes the collision object can advantageously drastically reduce the number of false triggering.

To the driver behavior in a collision object detection by the driver itself representing data include an accelerator pedal position and / or an accelerator pedal movement, a brake pedal position and / or a brake pedal movement, a steering movement, oversteer or understeer of the vehicle with respect to the steering angle or physiological data, which on a Crushing reaction and thus a detection of a potential collision object by the driver close. Thresholds and combinations may be specified for all of these quantities which must be exceeded in order to obtain a response from the vehicle environment.

Recognizer recognized collision object to plausibility.

Thus, in an advantageous embodiment of the invention, the data evaluation device can output a collision plausibility if a brake pedal actuation occurs at a brake pedal speed greater than a predefined threshold value, as is the case, for example, in so-called emergency braking.

Furthermore, the data evaluation device can conclude a collision object detection by the driver when the accelerator pedal is moved at a speed to a minimum position or to a maximum position or full throttle, which exceeds a predefined speed threshold, and within a predetermined time of preferred speed. For example, a brake pedal actuation takes place a few 100 ms after a gas release.

Collision object detection by the driver may also be assumed when calculating a limit for a steering wheel speed and / or a steering wheel acceleration in relation to an intrinsic speed of the motor vehicle, and one or both of the variables together exceed the corresponding limit for a certain time. In this case, a manipulated variable can be determined from the steering wheel speed or the steering wheel acceleration or from both variables and a plausibility of a collision object detection by the driver response can be assumed if the manipulated variable exceeds an adjustable value.

In an advantageous embodiment of the invention, it can also be provided that the data evaluation device outputs a collision plausibility when an operating activity of a control element exceeds a predefined time. It has been shown in empirical studies that when operating controls such. B. a radio or other entertainment device, an air conditioner, a telecommunication device or other system or switch by the driver a brief distraction of the driving task is given, which causes a higher probability of accident. Therefore, with a z. B. over a GAN bus recognizable operating activity that exceeds a certain, adjustable time, a plausibility of Kollisionsobjereskennung be accepted by the vehicle environment detection device.

In a further embodiment of a motor vehicle designed according to the invention, the data evaluation device can also Issue a collision plausibility, if ^' physiological data of the driver match predetermined physiological data representing a collision object detection by the driver. In a so-called startle response, which occurs upon detection of an imminent driver accident, numerous physiological data of the driver changes significantly, including, for example, easy-to-measure data such as heart rate and transpiration behavior. The determination of such a startle reaction z. B. by a measurable increase in the driver's pulse by means of integrated sensors in the steering wheel, as they are known, for example, in sports equipment, provides an unmistakable plausibility proof of the actual presence of a detected by the vehicle environment detection device collision object.

In a motor vehicle according to the invention, a basic plausibility check of all collision objects determined by the vehicle environment recognition device can be carried out via the driver reaction, i. H. that protective measures are only activated when it is clear from the data situation on the part of the vehicle environment recognition device that an object is approaching with respect to relative distance and speed and a driver reaction is present.

In order not to rule out all collisions in which there is no reaction of the driver, it may also be provided in an advantageous embodiment of the invention that the data evaluation device outputs a collision plausibility if an intrinsic velocity of the collision object relative to the intrinsic speed of the motor vehicle is greater than a predefined limit value is. The link with the driver's activity is therefore only valid for collision objects that have no or only a low intrinsic velocity. within the given range, eg. B. +/- 1 km / h have. This range depends on the measuring accuracy of the speed measurement of the environment sensor system, wherein the speed of the own motor vehicle is reference.

With such an embodiment of the motor vehicle according to the invention is achieved that z. As a vehicle-vehicle collision in which drive both vehicles, is detected as a relevant collision and the appropriate security measures are activated.

The controllable safety devices include z. B. common restraint, such as an airbag and a seat belt with belt tensioner and movable impact body, pillows and headrests, which can be changed by means of a control in size, hardness, shape and location. Furthermore, the occupants can be controlled in a position favorable for the accident position facilities, such as an electric seat adjustment, a KopfStützenverstellung, a seat belt tightener and movable upholstery.

Furthermore, the protection of collision partners such as pedestrians and cyclists serving protective means can be activated, such. As an adjustable bonnet, movable bumpers and hardness adjustable baffles on the vehicle's outer skin. Also, appropriate intervention in the level control and the braking and steering system can be provided.

Further advantages and advantageous embodiments of a motor vehicle according to the invention are the description, the drawings and the claims removed. In the single figure of the drawing, an embodiment of a motor vehicle equipped according to the invention is shown in principle, which will be explained in more detail in the following description.

The figure of the drawing shows a schematic plan view of a motor vehicle 1, which may be a passenger car or a commercial vehicle, with essential components of a pre-safe system 2 according to the invention.

The pre-safe system 2 has as an essential component a safety sensor system 3 which comprises a vehicle environment recognition device 4 and a driving situation data acquisition device 5 with a driving state sensor 6, an impact sensor 7 and an interior sensor 8. The safety sensor 3 of the motor vehicle 1 is applied here in dependence on the risk level for the motor vehicle 1 in different stages. The components of the safety sensor 3 can be embodied in a known construction, for example in one of the types described in the cited patent documents.

Thus, in the present case, the vehicle environment recognition device 4 represents a per se known 24 GHz radar near field sensor system with a range of approximately 20 m to 30 m and a tracking range of approximately 6 m, which has a plurality of distance sensors 9 whose Number is selected so that the environment around the motor vehicle 1 is completely detected.

The signals of the distance sensors 9 as well as the signals of the other sensor systems are processed in a data evaluation device 10, wherein the signals of the distance sensors 9 to information about distances and relative speeds to a possible collision obstacle 11, which another res motor vehicle, may be an immobile obstacle or a pedestrian, and be processed over a possible impact angle.

The distance sensors 9 emit highly concentrated electromagnetic waves in the form of short pulses. When an object is hit, these waves are reflected, and by measuring the transit time of the pulse between the motor vehicle 1 as a transmission location and the obstacle 11 as an echo location, the distance between these two objects can be determined. With the aid of the Doppler effect, a speed of the object 11 relative to the motor vehicle 1 can thus also be measured.

Of course, other known systems can be used for the design of the vehicle environment recognition device.

Already in normal operation, the driving condition sensor 6 analyzes important driving dynamics variables, such. As a vehicle speed, wheel speeds, vehicle longitudinal and vehicle lateral acceleration, a yaw rate, a compression and Ausfederweg, the vehicle level and for the present Pre-safe system 2 particularly significant sizes, such as the accelerator pedal accelerator pedal movement, the brake pedal position and the brake pedal movement and the Steering wheel speed and steering wheel acceleration. In this case, actual values of these variables are compared with predetermined desired values and threshold values. Because of these comparisons driving dynamics systems, such. As an anti-lock braking system and an electronic stability program are activated, which have the task to assist the driver in driving critical situations to avoid an accident. The impact sensor 7 detects an expected impact within a few milliseconds and forwards information about the severity of the accident to the data evaluation device 10 on. As is known, acceleration sensors, pressure sensors, intrusion sensors and contact sensors are used here, which serve to control, for example, pyro-technical restraint systems.

The vehicle situation data acquisition device 5 is supplemented by the interior sensor system 8, which in the present case provides information about the status of the occupants, the occupant position and the available restraint systems as well as physiological data of the driver. For detecting the pulse rate and thus for detecting a startle reaction in a collision object detection by the driver, corresponding sensors are embedded in a steering wheel 12 of the motor vehicle 1 in the present case.

Depending on the data evaluation by the data evaluation device 10, signals are output to active safety devices, such as here to an active chassis control control unit 13, and to passive safety devices, such as an airbag control 14.

Of course, in other embodiments, the possibility of intervention in an electronic stability program or other active and / or passive safety devices.

The activation of all or individual active and passive safety devices 13, 14 takes place when the information of the vehicle environment recognition device 4 represents a potential collision object 11 and data of the driving situation data acquisition device 5 represents a driver behavior which is predefined for a collision plausibility check. Thus, the data evaluation device 10 in the present case outputs a collision plausibility if, in addition to the detection of the collision object 11 by means of the vehicle environment recognition device 4, it is determined by the driving condition sensor 6 that a brake pedal actuation occurs with a brake pedal speed greater than a predefined threshold value, or that an accelerator pedal movement with an accelerator pedal speed greater than a predefined threshold, and a brake pedal actuation is detected within a predefined time after a throttle is removed.

Likewise, the data evaluation device 10 in the present case outputs a collision plausibility if the steering wheel speed or the steering wheel acceleration exceeds a limit value for a predefined time or if the sensors on the steering wheel 12 detect an abruptly increased pulse frequency and thus a fright reaction of the driver.

Furthermore, the service times for a control element 15 indicated here only as an example, enter the data evaluation unit 10 so that the data evaluation device 10 also outputs a collision plausibility if an operating activity of the control element 15 exceeds a predefined time when the collision object 11 is detected by the vehicle environment recognition device 4.

Claims

1. Motor vehicle with a pre-safe system, which comprises active and / or passive safety devices, which are controlled as a function of information which is recorded at least by a vehicle environment detection device and a driving situation data recording device and evaluated in a data evaluation device that at least part of the active and / or passive safety devices (13, 14) is activated when the information from the vehicle environment detection device (4) represents a potential collision object (11) and the data from the driving situation data detection device (5) represent driver behavior which is predefined for a collision plausibility check.

2. Motor vehicle according to claim 1, characterized in that the data representing a driver behavior for a collision plausibility comprise an accelerator pedal position and / or an accelerator pedal movement.

3. Motor vehicle according to claim 1 or 2, so that the data representing a driver behavior for a collision plausibility include a brake pedal position and / or a brake pedal movement.

4. Motor vehicle according to claim 3, so that the data evaluation device (10) outputs a collision plausibility if the brake pedal is actuated with a brake pedal speed greater than a predefined threshold value.

5. Motor vehicle according to one of claims 2 to 4, so that the data evaluation device (10) outputs a collision plausibility if an accelerator pedal movement occurs with an accelerator pedal speed greater than a predefined threshold value and a brake pedal actuation takes place within a predefined time after the accelerator is removed.

6. Motor vehicle according to one of claims 1 to 5, characterized in that the data evaluation device (10) outputs a collision plausibility if a predetermined value for a steering wheel speed and / or a steering wheel acceleration exceeded as a function of an inherent speed of the motor vehicle (1) for a predefined time is.

7. Motor vehicle according to one of claims 1 to 6, characterized in that the data evaluation device (10) a collision Outputs plausibility when an operating activity of an operating element (15) exceeds a predefined time.

Motor vehicle according to one of Claims 1 to 7, so that the data evaluation device (10) outputs a collision plausibility if physiological data of the driver match predetermined physiological data which represent collision object detection by the driver.

Motor vehicle according to one of claims 1 to 8, so that the data evaluation device (10) outputs a collision plausibility if an intrinsic speed of the collision object (11) in relation to the intrinsic speed of the motor vehicle (1) is greater than a predetermined limit value.