EP2877987A1 - Method and device for collision avoidance - Google Patents

Abstract

The invention relates to a collision avoidance device and a collision avoidance method, wherein the following are provided: one or a plurality of first environment sensors (11), the measured data from which supplies information regarding a distance of objects (4, 5) in the environment (2) of the vehicle (1); an evaluation and fusion device, which takes the measured data from the one or plurality of first environment sensors (11) to determine an environment map (30) of the vehicle (1), on the basis of which can be derived for individual regions in the environment (2) of the vehicle (1) probability information for an existence of an object (3, 4, 5) in said individual region; and a prediction device (24), which is designed to determine and make available control and/or warning information for a collision-free predicted movement of a vehicle component (61, 62) on the basis of the environment map (30), wherein the freedom from collision of the predicted movement is dependent on the probability of the existence of an object (3, 4, 5) in the at least one region (161,162) marked out, wherein at least one second environment sensor (51, 52) is coupled to the evaluation and fusion device (22), which sensor is designed to detect a movement of an object (4, 5) relative to the vehicle (1) when the vehicle is stationary at least in one zone (110) of the environment (2) of the vehicle (1), which zone comprises the at least one marked out region (161, 162), and the evaluation and fusion device is designed to modify, on detection of a motion in the one zone (110), the environment map in such a way that at least the probability that may be derived from the environment map (30) for the at least one marked out region is modified.

Description

 description

Method and device for collision avoidance

The invention relates to a method and a device for collision avoidance of movable vehicle components during a standstill of the vehicle or immediately after a standstill of the vehicle. In particular, the invention relates to a device and a

Method for preventing a collision of a door with objects and obstacles in the vicinity of the stopped vehicle.

From the prior art, it is known to detect environment of a vehicle, in particular a motor vehicle with environmental sensors. For this purpose, for example, sensors are used, which are operated by a Impulschomessverfahren. These emit a measuring pulse, which is reflected on objects in the vicinity of the vehicle. The reflected pulse is measured by a measuring sensor of the vehicle and determined on the basis of a transit time with knowledge of the propagation speed of the emitted or reflected pulse of a distance. For example, work according to this measuring principle

Ultrasonic sensors or classic radar sensors. However, many of these sensor types emit the transmit pulse in a relatively wide solid angle range and / or receive reflected pulses from a large solid angle range. Therefore, a precise localization of the object relative to the vehicle is not possible. Based on a single measurement can only be made the statement that an object on a circular sector elements or an element of an ellipse, if the transmitter and the receiver of the sensor are spaced from each other. Via a so-called measurement data fusion, which measures results of different sequential and / or detected with different sensors

Merged results, a localization of the objects relative to the vehicle can be significantly improved. It is customary to determine, based on a large number of measurements, positions of objects in the surroundings of the vehicle and to record them in a so-called environment map. For this purpose, the environment of the vehicle is divided into areas or cells. Regions or cells of the environment map are assigned probability information, which is a measure of the fact that an object is located at a location in the vicinity of the vehicle, which corresponds to the corresponding area or cell of the environment map of the vehicle.

These methods and techniques are well known in the art and therefore not further explained here. It is customary, for example, by means of ultrasonic sensors, which a

Parking assistance system are assigned, an approach to obstacles when parking recognize and signal the approach via the parking assistance system. Frequently, an environment map of the vehicle when parking in a parking space, such as a parking box detected. Here, during the parking process by means arranged at the front or the rear of the vehicle sensors, the lateral contours in adjacent

Parking boxes of parked vehicles measured and entered in the environment map. At the time when the vehicle comes to a standstill in the parking space designed as a parking box, there is thus a reliable environment map of the vehicle. This usually also contains information about areas around the vehicle, which of the or

Measuring sensors, which were used to capture the environment map, can not be currently recorded. In the area of the front bumper arranged ultrasonic sensors, for example, obstacles, which are located in a lateral distance to a driver or passenger door of a motor vehicle, do not detect in the parked, parked state.

For example, to warn a driver or passenger to get out of the vehicle without causing them to collide with an obstacle, such as a nearby parked vehicle, when opening the door, a warning of such an obstacle is desirable. The previously collected information about the environment is necessary and helpful. The same applies to automatically or from the inside reveal tailgates and / or trunk lid etc.

US Pat. No. 7,209,221 B discloses a method for determining vehicles in a blind spot, which describes different measuring methods for detecting the surroundings.

From DE 10 2008 040 041 A1 a method for determining a distance between a first vehicle and an object is proposed. The method comprises a step of providing a transmission signal of the first vehicle at a first time at an interface, wherein the transmission signal comprises a signal sequence and an identification of the first vehicle. Furthermore, the method comprises a step of receiving a

Response signal from one object at a time over the interface. In addition, the method includes a step of determining a distance between the first vehicle and the object from the first and second times and a delay time, the delay time defining a time duration between receiving the transmit signal and transmitting the response signal through the object. In addition, information about the object of the first vehicle can be transmitted in the response signal. Such a system requires active interaction of the vehicles and can not be applied to passive objects and objects such as trees or pillars or the like become. Furthermore, DE 10 2008 040 041 A1 proposes capacitive distance sensors in order to be able to detect a lateral approach of an object.

From DE 10 2008 036 009 A1 a method for collision protection of a motor vehicle and a parking garage assistant are known. There, a method for protecting a vehicle from a collision in the parking and maneuvering area is described, wherein the vehicle has a

Environment sensor for detecting objects in the environment of the vehicle has, and the method comprises the following steps:

 Detecting the sensor information of the environment sensor of the vehicle, creating a

Environment map from the sensor information of the environment sensors, determining the

Vehicle self-movement, and determining the collision probability of the vehicle with environmental objects located in the environment of the vehicle from the environment objects depicted in the environment map, taking into account the vehicle own movement. It is also described to check using the environment map even when the vehicle is stationary, whether a door would collide when opening with an environment object according to the information of the environment map. In particular, a maximum permissible door opening angle for a collision-free opening of the door can be determined in this way. However, situations in which the environment changes immediately after the vehicle has come to a standstill, due to an intrinsic movement of the objects, are not taken into account. If a driver or a passenger leaves a certain time after parking and stopping the vehicle before it starts with a door opening, then in this interval in the adjacent parking box, which was previously free, a vehicle may be parked. It is also possible that during this time a vehicle is uncovered and by another

Vehicle, which is then parked in a different position than the vehicle previously located in the parking space, which was measured during the parking process by a distance sensor. Thus, the environment map at the time is no longer up to date, to the actual exit process and the opening of the vehicle door done. Therefore, information derived from the environment map, such as a maximum door opening angle for a collision-free door opening, may be incorrectly detected, resulting in inadvertent collisions without a driver or passenger warning.

The invention is therefore based on the technical object to provide an improved method and improved apparatus for collision avoidance.

The object is achieved by a device with the features of

Patent claim 1 and a method having the features of claim 5 solved. Advantageous embodiments of the invention will become apparent from the dependent claims. The invention is based on the idea of validating the environment map after the vehicle has come to a standstill for a region in which there are areas of the environment map which are not detectable by those environmental sensors, which are referred to here as first environment sensors, which represent the original detection of the environment Environment map are used. For example, if a vehicle has ultrasonic sensors in the area of a front and a rear bumper, the contours of vehicles parked in adjacent parking boxes can be detected during the parking process by the ultrasonic measurement sensors in the front or rear bumper and displayed correctly in the environment map. However, at the time when the vehicle comes to a standstill, there are some areas which are in a swivel range of, for example, vehicle doors that can not be detected by the ultrasonic sensors disposed on the front or rear bumpers and inspected for existence of obstacles and objects , In general, individual distance sensors, such as ultrasound sensors operating according to the pulse-echo method, can only adequately determine a contour of adjacent objects when interacting. A contour can only due to the proper movement of the

Vehicle and the associated large number of detection positions for

Distances in the fixed reference frame can be detected precisely. For an area that includes at least one of these areas, its object freedom for a collision-free

Movement of a vehicle component is important, is now monitored with a second sensor or a plurality of second sensors, if there is a movement of objects in this area relative to the stationary vehicle. If this is the case, then the environment map is modified accordingly, for example, the areas of the so surveyed area as no longer current and no longer reliable or marked as invalid. This information can be used to provide control or warning information for a collision-free

Adjust the door opening accordingly.

In particular, there is proposed a device for a vehicle for collision avoidance, in particular for collision avoidance of a vehicle door with an object of the environment during opening, which comprises: one or more first environment sensors whose measurement data provide information about a distance of objects in the surroundings of the vehicle, and an evaluation and fusion device, which determines an environment map of the vehicle on the basis of the measurement data of the one or more first environment sensors, on the basis of which a probability indication for an existence of an object in this single area can be derived for individual areas in the environment of the vehicle, as well as a

Prediction device, which is designed to determine and provide control and / or warning information for a collision-free predicted movement of the vehicle component, wherein the collision freedom of the predicted movement of the probability of existence of an object in at least one excellent area depends, wherein at least one second environment sensor is coupled to the evaluation and fusion device, which is designed to detect after a standstill of the vehicle movement of an object relative to the vehicle at least in an area of the environment of the vehicle, which comprises the at least one excellent area and the evaluation - And fusion device is adapted to change the environment map at a detected movement of an object relative to the vehicle in the one area so that at least derive from the environment map for the at least one excellent area

Probability indication is changed. An identification of the environment map or of areas of the environment map as invalid represents such a change. Such a device is capable of plausibility with the at least one second environment sensor the environment map for a large area and in case of a detected movement in the monitored area to provide information indicating that the environment card information is no longer reliable. The control and warning information, which can be used either for controlling, actively limiting a door opening or only for outputting a warning signal in conjunction with a recognized opening by a corresponding opening angle, can thus be adapted adequately to the current situation. Far away the at least one excellent area is usually not in the current one

Measuring range of the one or more first environment sensors. In particular, when this additional condition is satisfied with respect to the at least one designated area, plausibility of the probability information for that at least one designated area with the first environmental sensors is not possible.

A corresponding method for collision avoidance of components of a vehicle comprises the steps: acquiring surrounding data by means of first environmental sensors during the driving operation of the vehicle, creating an environment map by measuring data fusion, with reference to which for individual areas in the environment of the vehicle one

Probability indication for an existence of an object in this single area is derivable, predicting a collision-free movement of the vehicle or a

Vehicle component based on the environment map, the collision freedom of the predicted movement of the likelihood of an object in at least one

excellent area and providing tax and / or

Warning information for the predicted collision-free movement, wherein by means of at least one second environmental sensor is measured at standstill of the vehicle, whether in an area comprising the at least one excellent area, an object relative to the

Vehicle moves, and if this is the case, the environment map in the one area is changed so that at least that from the environment map for the at least one

excellent range derivable probability is changed. This affects the derivation of the control and warning information required for the predicted collision-free motion a vehicle component can be determined via the vehicle itself after a standstill or during standstill. This method is particularly advantageous if, on the basis of the environment map, it is possible to derive a probability indication for at least one excellent area that is not in the current measuring range of the one or more surroundings sensors.

Particularly preferably, the first environment sensors are measurement sensors which operate according to an echo pulse measurement method. For example, these may be ultrasound sensors, which are installed, for example, in a front and / or a rear bumper of the vehicle and are used in a parking assistance system, for example for approach recognition to objects.

The at least one second environment sensor is preferably a Doppler radar sensor. In this, a frequency shift between the transmitted radar signal and the received reflected radar signal is evaluated to be at

Use of the Doppler law one associated with the frequency shift

Derive relative speed. With such a sensor, a relatively large

Measuring range can be reliably monitored for relative movements of objects in the environment.

In contrast to most other assistance systems known in vehicles, it is preferably provided that detection of the surroundings by means of the at least one second surroundings sensor is carried out for a predetermined period of time after the vehicle has come to a standstill and is at a standstill, even if the ignition of the vehicle is stopped Vehicle is switched off. Within this predetermined period of time, which may preferably be a few minutes, for example up to 5 minutes or 15 minutes, the environment of the vehicle is monitored. A vehicle user who does not get off immediately after reaching a standstill, for example, just because also in a neighboring parking space or parking box another vehicle on or off, can rest assured that the control and / or warning information, which to avoid Door collisions with objects in the environment are used correctly, and inconsistencies in the environment map, which can lead to a derivation of incorrect or incorrect control or warning information, are reliably avoided.

In one embodiment, it is provided that the measurement of the environment is set by means of a second environment sensor, if one or all vehicle components whose

collision-free predicted motion is dependent on the likelihood of existence of an object in the at least one designated area or another designated area, the further distinguished area not being within the current measuring range of the However, one or more first environmental sensors lies in the area in which the at least one second environmental sensor detects movement of an object, is opened and closed again. In this case, it is assumed that the person has left the vehicle and a renewed exit process is not expected.

In order to be able to validate the information known from the environment map when the door is opened, it is provided in one embodiment, the at least one second

Surround sensor to be arranged on the movable vehicle component, for which a

Movement is predicted. If, for example, it is a vehicle door, then the at least one second environment sensor, for example a Doppler radar sensor, on the

Vehicle door arranged. The arrangement is such that it is preferably arranged in a region of the door which has the greatest possible distance from the pivot axis of the door. In the event that according to the environment map no objects are arranged laterally adjacent to the door in the environment, a plausibility check during the door opening can be characterized in that even when opening the door no relative movement of the at least one second sensor which is attached to the door detected becomes. However, if an object is present next to the vehicle, then a second environment sensor, which is designed as a Doppler radar sensor, due to the proper movement of the vehicle component during opening, for example, the swung open door, detect a relative movement between this swung door and the stationary object located in the surrounding.

A Doppler radar initially only provides velocity information. However, it is also desirable to determine a distance information. Therefore, it is provided in a particularly preferred embodiment that at least during the movement of the

Vehicle component for which a predicted collision-free movement has been determined, the reflected radar signal is evaluated only in evaluation time windows which are shorter than the transmission time window during which the radar signal is emitted. The location and length of the evaluation time window relative to a start of the transmission time window, i.e., at the beginning of the radar signal transmission, determines the distance range in which an object can be located which has caused the reflection of the radar signal. Here, only the onset of the reflected radar signal is important because a transmission of the radar signal, i. a transmission duration is longer than the time span which requires a radar signal to travel the distances relevant for a collision warning. The decisive factor is whether in one

Auswerteintervall the onset of a reflection signal can be determined. Since very short distances are of interest, an evaluation window is as close as possible to a beginning of the

Send time window. An object freedom or an object existence can also be determined by means of a Doppler radar. In order to comply with the legal requirements regarding a frequency width of the radar signal emitted, this is repeatedly transmitted in the form of a CW signal. A sampling frequency of the reflected signal must be adjusted according to the sampling theorem so that a frequency shift due to the Doppler effect can be determined. The

Radar transmission, although executed in repeated steps, is considered CW transmission because a transmission duration is much greater than a period of the transmitted vibrations.

If a sampling takes place in a detection time window which is close enough to the start of transmission and has a time-limited duration, it is possible to deduce from the onset of the reflection signal a distance of the object at which the reflection took place.

In another embodiment, an amplitude of the reflected radar signal is evaluated to derive a distance therefrom. The smaller the amplitude, the greater the distance to the object where the reflection took place. However, this method is less accurate because the amplitude also includes properties of the object which influence a reflection strength.

The invention will be explained in more detail with reference to a drawing. Hereby show:

Fig. 1 is a schematic representation of a vehicle at a standstill in a

 Parking environment and

Fig. 2a - 2d a vehicle at a standstill in a parking lot environment, wherein the

 represent different figures in time sequence resulting environment situation.

In Fig. 1, a vehicle 1 is shown schematically in an environment 2 in a parking lot. The vehicle 1 is parked on a parking box 301, which is partially bounded at a front end 302 by a wall 3. The wall 3 represents an object in the environment 2 of

Vehicle 1 is located laterally next to the vehicle 1 at the time of parking a neighboring vehicle A 4, which is parked in a neighboring parking box 303. The vehicle 1 comprises a parking assistance system 10, which comprises first environmental sensors 11, which are arranged on a front bumper 12 and a rear bumper 13. At least some of the first environmental sensors 11 are designed to be in use during the

Einparkvorgangs also objects, such as the neighboring vehicle A 4 capture while driving sideways. The first environment sensors 11 are preferably measuring sensors which operate according to a pulse-echo measuring method. For example, it may be ultrasonic sensors. These emit a short ultrasonic pulse and evaluate a time between the emission of the ultrasonic pulse and a reception of a reflected ultrasonic pulse. In this way, a distance to an object 3, 4 in the environment 2 of the vehicle 1 from the corresponding first environment sensor 1 1 can be determined. An environment map 30 can be created via a measurement data sensor fusion of many measurements. This is done by an evaluation and

Fusion device 22 of a controller 20 executed.

This control unit 20 additionally evaluates information about the intrinsic motion of the vehicle in order to be able to fuse the measurement data acquired at different times and at different positions in the surroundings of the vehicle assumed to be stationary.

In Figure 1, the environment map 30 is shown schematically, which has detected the vehicle 1 during the parking process of the environment 2. In addition to the own vehicle 31, the detected wall 32 and the other vehicle A 33 are recognizable as contours. A person skilled in the art knows from the prior art how an environment map can be derived on the basis of measurement data of first environment sensors 11 which operate according to a pulse-echo measurement method. This is preferably subdivided into individual cells or regions, for which, based on the measurement data, probability information for the individual regions or cells is derived, which indicate whether an object is located in the region of the environment to which the cell or the region of the environment map is assigned or the corresponding area is free of objects. As a rule, only the outer contours of the objects 3, 4 in the environment 2 of the vehicle 1 are of interest for collision avoidance.

A collision avoidance device 40, which is at least partially implemented by means of the control device 20, additionally comprises a prediction device 24, which can predict movement based on data from the environment map 30 for a vehicle component, for example a front vehicle door 61 or a rear vehicle door 62. The

Prediction device 24 determines which movements of the vehicle components, here the doors 61, 62, are possible without colliding with one of the objects 3, 4 in the environment 2 of the vehicle 1. In this case, the prediction device 24 determines, for example, those region of the environment or the associated environment map through which the vehicle component moves during a movement. Checked on the basis of the probability data of the environment map, whether a collision with an object is to be expected or not. In Figure 1, the vehicle components, the front door 61 and the rear door 62 are each shown in an open position. About circular arcs 63, 64 are the corresponding

Swivel radii indicated. It can be seen that immediately after parking the vehicle 1 in the parking box 301, both the front vehicle door 61 and the rear vehicle door 62 can be opened without any risk of collision with the

Neighboring vehicle A 4 exists. Remains the driver or a passenger after the immediate parking still for a certain time in the vehicle, so the environment 2 of the vehicle 1 may change. For example, the neighboring vehicle A 4 can park out of the neighboring parking box 303 and park another neighboring vehicle B 5 in the same neighboring parking box 303, but come to a standstill in another position. Furthermore, the further neighboring vehicle B 5 has different dimensions and thus a different outer contour 7 than the neighboring vehicle A 4 originally located in the neighboring parking box 303. It can be clearly seen that swiveling the doors 61, 62 now leads to a collision with the other one

Neighboring vehicle B 5 would lead.

The collision avoidance device, which is partially implemented in the controller 20, should help to avoid these situations. For this purpose, at least one second surroundings sensor, in the illustrated embodiment, two further second environment sensors 51, 52 are provided, which are arranged on the vehicle doors 61, 62 as close as possible to those locations which define the maximum pivot radius. The second environment sensors 51, 52 are as

Doppler radar sensors formed. These are able to monitor each a larger area 1 10 laterally adjacent to the vehicle 1 with respect to moving objects relative to the vehicle. This area 10 comprises at least one excellent area 162 which, on the one hand, is essential for a collision-free movement possibility

corresponding vehicle component, eg. B. the front door 61 or rear door 62, and on the other hand is not in the measuring range of the first environment sensors 1 1 at a standstill of the vehicle 1. Schematically, two such excellent areas 161, 162 are indicated in FIG. In the closed state of the doors 61, 62, the second environment sensors 51, 52 monitor at the same time, alternately, the area 110, which includes at least excellent area 161, 162, which is necessary for the collision-free movement of the vehicle component, the second environment sensor 51, 52 is assigned. In general, a second

Environment sensor 51, 52, the area 1 10 with regard to possible movements that make an environment map implausible, take over for several moving vehicle components. It is possible that a second environment sensor 51, 52 several movable

Vehicle components are assigned to plausibility monitoring environment map and several excellent areas 161, 162 by means of a single second

Envelope detection sensor is detected and monitored. Is after parking and standstill of the vehicle 1 by means of the second environment sensors 51, 52 or only one of these second environment sensors 51, 52 a

Relative movement of an object, for example, detected here the ausparkenden neighboring vehicle A 4, the information in the environment map 30, the objects laterally adjacent to the vehicle 1, 31, marked as invalid.

While the prediction device 24 immediately after parking in the parking box 301 for opening the front vehicle door 61 and the rear vehicle door 62 each predicts that they can be opened up to a maximum possible opening angle and this information as control and / or warning information about a Provided interface 26, after the detection of the vehicle movement and the invalidation of part of the environment information of the environment map 30 by the prediction means 24 modified control and / or warning information is provided via the interface 26.

The control and / or warning information can be forwarded, for example, to a further control unit 70 which monitors angle measuring sensors 81, 82. The further control device 70 thus determines a current opening angle of the front vehicle door 61 via the

Angle measuring sensor 81 and the rear vehicle door 62 via the angle measuring sensor 82nd

Are the vehicle doors 61, 62 opened immediately after parking, to a

Time at the environment map 30 is still fully valid, no warning signal is issued in the situation shown. On the other hand, if the prediction unit had determined that only a limited door opening angle range would be available for one of the two vehicle doors 61, 62

Is available, at least at a certain opening angle, which is smaller than this determined opening angle, a warning signal at an output device 100, which is designed for example as a speaker output. It is also possible, via an actuator 91 or 92, which are associated with the vehicle doors 61 and 62, a door opening up to the determined maximum allowable angle for a collision-free opening at the request of a vehicle occupant causes. Likewise, the actuators may be configured to prevent opening of the doors 61, 62 beyond the determined maximum opening angle for collision-free opening of the corresponding vehicle doors 61, 62.

At a later time, after the information in the environment map 30 are invalidated at least in some areas, for example, when opening the vehicle door immediately a warning signal via the output device can be issued to inform the driver or the passenger that the collision avoidance device 40th is unable to determine the maximum allowable angle for a collision-free opening. In order to support the driver or front passenger in such situations, the second environment sensors 51, 52 can also be operated so that they are used during the opening movement of the vehicle components, here the vehicle doors 61, 62, to a

Approaching an object in the environment 2 to capture. If the second environment sensors 51, 52 are designed as Doppler radar sensors, then, for example, only a very short

Time window are evaluated after a start of the transmission of the radar signal to received reflected radar signals. This makes it possible, only a specific one

Distance range before the second environment sensor 51, 52 with regard to existing objects or an approach to objects evaluate. It is likewise possible to set and evaluate a plurality of different time windows one after the other or in an iterative manner in order to determine in each case for different distance intervals whether an approach to an object located in the respective distance interval is detected. If an object is determined, for example, in the shortest monitored distance interval, control and / or warning information is provided via the prediction unit, which causes the further control unit 70 to output a warning signal via the output device 100 or a movement of the front vehicle door or the rear vehicle door to limit the corresponding associated actuator 91 and 92, respectively.

Another way of approaching an object while moving the front vehicle door or the rear vehicle door on the measurement signals of the corresponding

to detect associated second environment sensors 51 and 52, is to evaluate an amplitude of the detected reflected radar signal or the corresponding Doppler radar signal. The greater the amplitude, the closer the object is in the environment 2 of the vehicle 1 to the corresponding moving second environment sensor 51 or 52.

The described collision avoidance device 40 comprises a plurality of components, which in turn may be components of other inputs or devices. The first environment detection sensors 1 1 and the control unit 20 with the evaluation and

Fusion device 22, as well as the further control device 70 and the output device 100, together form, for example, the parking assistance device 10 in many vehicles. In addition to these components, the embodiment of the device for collision avoidance 40 described here comprises the second environment sensors 51, 52 and the prediction device 24 ,

The individual devices can be used in different control devices, here with the

Reference numerals 20 and 70 are marked, or a control device to be formed.

In particular, the evaluation and fusion device 22 and the prediction device 24 can with one or more specialized electronic circuit, a programmable processor unit coupled to a memory, or a combination of both. To store the environment map memory is provided in any case. This can be combined with a memory of a

Processor unit or be formed separately from such.

With reference to Figures 2a to 2d is for a similar situation, as described above in the

In connection with FIG. 1, once again be graphically represented as a time sequence. In FIG. 2 a, the vehicle 1, which comprises first environment sensors 11 and second environment sensors 51, 52, is next to one in a parked situation

Neighboring vehicle A 4 shown. During the parking process, an outer contour 6 of the neighboring vehicle A 4 is measured.

FIG. 2 b shows the situation in which the neighboring vehicle A 4 leaves its parking position. The outer contour 6, in which the vehicle was originally located, which is measured by means of the first environmental sensors 11, is also shown in FIG. 2b. The second environment sensors 51, 52 or one of the two second environmental sensors 51, 52, which are designed as Doppler radar sensors, already detect during the Ausparkvorgangs the neighboring vehicle A 4 movement in the environment 2, which implies that the determined contour 6 of the neighboring vehicle A 4 not is more valid.

FIG. 2 c shows the situation in which another neighboring vehicle B 5 is parked next to the vehicle 1. Its contour 7 is unknown.

FIG. 2 d illustrates the situation in which the driver wishes to open the front vehicle door 61. In a defensive designed variant, the vehicle door 61 can be up to an opening angle without intervention of the collision avoidance device, d. H. without opening a mechanical limit or without issuing a warning signal that should have been possible according to the originally determined vehicle contour. A further opening is possible, or not possible, even without releasing a lock, even if during the pivoting operation no obstacle is detected by the second environment sensor 51, which would hinder further collision-free pivoting. In another embodiment, the collision avoidance device does not respond to the outdated information of the environment map, but leaves a vehicle door opening, as long as due to the second

Environment sensor 51 is detected no approach to an object 5, which could hinder a collision-free movement.

It will be apparent to those skilled in the art that only exemplary embodiments are described. In particular, the collision avoidance device can not only on a lateral Vehicle doors, but especially on tailgates, trunk lids,

Ausstelldächer or the like can be applied, it is advantageous if the first environment sensors detect not only information in a plane, but also, for example, for a ceiling height or the like.

LIST OF REFERENCE NUMBERS

vehicle

 environment

 Wall (object)

 Neighboring vehicle A

 Neighboring vehicle B

 Contour of the neighboring vehicle A

Contour of the neighboring vehicle B

Parking assistance device first environment sensors

 front bumper

 rear bumper

 control unit

 Evaluation and fusion device

prediction

 interface

 environment map

 own vehicle

 Wall

 Vehicle A

 Collision avoidance device, 52 second environment sensors

 front vehicle door

 rear vehicle door

 Circular arcs (swivel radius)

 Arc (swing radius)

 another control unit

 Angular position sensor

 Angular position sensor

, 92 actuators

0 output device

0 area

1 excellent area

2 excellent area

1 parking box

2 front end

3 neighbor parking box

Claims

 claims

A collision avoidance apparatus for a vehicle (1) comprising:

one or more first environment sensors (1 1), whose measurement data provide information about a distance of objects (3, 4) in the environment (2) of the vehicle (1), and an evaluation and fusion device (22) based on the measurement data of the one or more first environment sensors (1 1) determines an environment map (30) of the vehicle (1), by means of which for individual areas in the environment (2) of the vehicle (1) a respective probability indication for an existence of an object (3, 4) is derivable in this single area, wherein on the basis of the environment map a

Probability indication for at least one excellent range can be derived, which is not in the current measuring range of the one or more first environment sensors (1 1) for a collision-free movement of a vehicle component, as well as a prediction device (24), which is formed, control and / or warning information for collision-free predicted movement of a vehicle component (61, 62) on the basis of the environment map (30), the collision freedom of the predicted movement being determined by the likelihood of existence of an object (4, 5) in the at least one designated area (61, 62) is dependent, characterized in that at least one second environment sensor with the evaluation and fusion device (22) is coupled, which is formed at a standstill of the vehicle (1) movement of an object relative to the vehicle at least in an area (10 10 ) of the environment of the vehicle, which d at least one excellent area, and the evaluation and fusion device (22) is adapted to change the environment map at a detected movement in the one area (1 10) so that at least derive from the environment map for the at least one excellent area Probability is changed.

Apparatus according to claim 1, characterized in that the at least one second environment sensor is a Doppler radar sensor.

Device according to one of claims 1 or 2, characterized in that the at least one second environment sensor (51, 52) on the vehicle component (61, 62) is arranged, for which a collision-free movement is predicted. Apparatus according to claim 2 or 3, characterized in that the

Doppler radar sensor is designed to detect or evaluate the reflected cw radar signal only in a receiving time window to an additional

Distance information to an object (4, 5) whose relative movement is detected to determine and / or to discriminate object movements of distant objects.

A method for collision avoidance of movable components of a vehicle with objects in the vicinity of the vehicle, comprising the steps:

Capturing environmental data using first environment sensors (1 1) during a

Driving operation of the vehicle (1) and creating an environment map (30)

Measuring data fusion, on the basis of which a probability indication for an existence of an object (3, 4, 5) in this individual area can be derived for individual areas in the environment (2) of the vehicle (1), prediction of a collision-free movement of a vehicle component (61, 62 Based on the environment map (30) of the vehicle (1), wherein the collision freedom of the predicted movement of the

Existence probability of an object (4, 5) in the at least one

Excellent range (161, 162) is dependent, and providing control and / or warning information for the predicted collision-free movement, characterized in that by means of at least one second environment sensor (51, 52) at standstill of the vehicle (1) is measured, whether in an area (110) comprising the at least one designated area (161, 162), moving an object (4, 5) relative to the vehicle, and if so, the surroundings map (30) in the one Area (1 10) is changed so that at least from the environment map for the at least one excellent area (161, 162) derivable probability is changed.

A method according to claim 5, characterized in that the vehicle component is a vehicle door (61, 62) and the pivoting movement of the vehicle door is predicted and the control and / or warning information include a maximum door opening angle to which the door collision-free due to the out of the environment map (30) derived probability information can be opened.

A method according to claim 5 or 6, characterized in that by means of the at least one second environmental sensor (51, 52) is measured for a predetermined period of time after which the vehicle (1) has come to a standstill and is at a standstill, even if the ignition of the vehicle (1) is turned off. Method according to one of claims 5 to 7, characterized in that the measuring by means of the second environment sensor (51) is set when one or all vehicle components whose collision-free predicted movement of the

Existence probability of an object (4, 5) in the at least one

Excellent range (161) or another excellent area (162) is already moved once, with a collision freedom movement of at least one other component (62) of a

Existence probability of an object (4, 5) in the further excellent area (162) is dependent.

Method according to one of claims 5 to 8, characterized in that the environment map or at least those areas of the environment map, which are in the area (1 10), which is measured by the second environment sensor, as invalid

be marked.

Method according to one of claims 5 to 9, characterized in that by means of the second environmental sensor, a radar Doppler measurement is performed and that the at least one second environment sensor (51, 52) on the vehicle component (61, 62) is arranged, whose movement is predicted , and reflected radar signal is evaluated only in evaluation time windows which are shorter than the transmission time window during which the radar signal is transmitted, and based on received reflected radar signals in the evaluation time windows, a distance information is estimated to an object which is relative to the vehicle component (61, 62). emotional.