EP3857532A1 - Method for evaluating an effect of an object in the surroundings of a means of transport on a driving manoeuvre of the means of transport - Google Patents

Abstract

The present invention relates to a method for evaluating an effect of an object (40) in the surroundings of a means of transport (80) on a driving manoeuvre of the means of transport (80), said method comprising the steps: determining, by means of a first ultrasonic sensor (30) of the means of transport (80), a first distance (d1) between the object (40) and a first position (50) of the means of transport (80); determining, by means of the first ultrasonic sensor (30) of the means of transport (80), a second distance (d2) between the object (40) and a second position (55) of the means of transport (80) which deviates from the first position (50); calculating a change between the first distance (d1) and the second distance (d2) with respect to a path (s) which corresponds to a path (s) travelled between the first position (50) and the second position (55) of the means of transport (80); and, when the driving manoeuvre of the means of transport (80) is being performed, taking into account or not taking into account the object (40) in accordance with a result of the calculation.

Description

 description

title

 Procedure for evaluating the impact of an object in the environment of

Means of advancement on a driving maneuver of the means of advancement

State of the art

The present invention relates to a method and a device for evaluating an impact of an object in the environment of a

Means of transportation on a driving maneuver of the means of transportation and relates in particular to an assessment of the object's ability to be driven under by the means of transportation.

Parking and maneuvering assistance systems for means of transportation are known from the prior art, which among other things. Use ultrasound signals to capture an environment around the vehicle. One reason for the use of ultrasound signals is the high measuring accuracy associated with this technology in the near and ultra-close range. In order to better cover the area when recording an environment of the means of transportation, usually several ultrasonic sensors used in combination. In order to detect any existing blind spots during the detection, e.g. In the area of a bumper of the means of transportation to close as completely as possible, a minimum detection range and an opening angle, as well as a

Sensitivity of the ultrasonic sensors continuously improved. Modern ultrasonic sensors can therefore cover a detection range of 10 cm to 7 m, while at the same time detection angles of up to 85 ° for large ones

Objects in the vicinity of the means of transportation can be reached. Due to the high sensitivity of modern ultrasonic sensors, objects that are not critical or not relevant for the driving means of the means of transportation are frequently detected in the environment of the means of transportation, such as Gantries,

Top edges of the garage or ceiling beams in an underground car park, which requires a suitable method for their detection and fading out. DE102016213377A1 describes a method and an apparatus for

Determination of a passage height of a vertical constriction to be driven under with a vehicle on the basis of a monocular camera, whereby distinctive features of the vehicle surroundings are identified in the image sequence recorded by the camera. It is further described that a virtual 3D image of the vehicle surroundings is generated from the identified features in relation to a vehicle coordinate system, in that their displacement in the image sequence allows a conclusion to be drawn about their respective position.

DE 10201 11 13077A1 describes a method and an apparatus for

Determination of the ability to drive through an object for a vehicle using a 3D camera, corresponding information for the determination being determined from image data of the 3D camera. It is further described that a

Dimension and shape of a surface or a space to be traversed, in particular can be determined taking into account the movement of the 3D camera due to the movement of the vehicle. For this purpose, a 3D scene reconstruction can advantageously be carried out from the image data of the 3D camera, for example with the method of the optical flow.

DE 102012211034A1 describes a driver assistance system for determining a distance of a vehicle from an obstacle above a vehicle

Vehicle for determining a passage height under the obstacle, the distance being able to be determined by means of an ultrasonic sensor, which is preferably arranged on the vehicle such that the distance measurement is carried out in the vertical direction. The distance measurement by means of the sensor is based on the echo sounder method by evaluating the transit time of the ultrasound pulse to the obstacle and the echo pulse reflected by the obstacle back to the sensor. This enables the distance to the obstacle to be determined, since the position of the sensor on the vehicle is known.

Disclosure of the invention

According to a first aspect, the present invention proposes a method for evaluating an impact of an object in the environment of a

Means of transportation on a driving maneuver of the means of transportation and in particular an assessment of the object's ability to drive under the vehicle. The means of transportation can be, for example, a road vehicle (eg shuttle, bus, motorcycle, e-bike, car, transporter, truck) or a watercraft. In a first step of the method according to the invention, a first distance between the object and a first position of the means of transportation, or more precisely, a position of the first ultrasonic sensor at the first position of the means of transportation is determined by means of a first ultrasonic sensor of the means of transportation, the first distance on the basis direct echoes of the ultrasound signals emitted by the first ultrasound sensor can be measured. The first

Ultrasonic sensor and also other ultrasonic sensors used for the method according to the invention can be used in this context

in particular highly sensitive ultrasonic sensors and preferred

Ultrasonic sensors with a detection range of 10 cm to 7 m and a detection angle of up to 85 °. It should be noted that this

Information is not restrictive and instead both ultrasonic sensors with larger detection ranges and detection angles and smaller detection ranges and detection angles can be used. Furthermore, the first ultrasonic sensor and possibly further ultrasonic sensors used can preferably be part of an existing driver assistance system of the means of transportation and can be arranged at any suitable positions on the means of transportation. Preferably the first

Ultrasonic sensor and other ultrasonic sensors essentially in

Front area of the means of transportation and / or in the rear area of the

Means of transportation may be arranged so that an environment of the

Means of transportation can be monitored in a suitable manner when driving forwards or backwards using the ultrasonic sensors. Of course, this does not rule out that, alternatively or additionally, ultrasonic sensors can be arranged at other positions of the means of transportation, such as on the sides of the means of transportation.

Finding the first distance and then executing it

The method steps described can take place on the basis of an evaluation unit according to the invention which is set up, signals of the first

Ultrasonic sensor and possibly further ultrasonic sensors by means of a

Receive data input. The evaluation unit can be designed, for example, as a processor, digital signal processor, microcontroller, or the like. A Logic for executing the respective method steps according to the invention can be implemented, for example, in the form of a computer program, which can be executed by the evaluation unit. The evaluation unit can preferably comprise an internal and / or external storage unit connected to the evaluation unit in terms of information technology in order, for example, to store data generated and / or received by the evaluation unit. In addition, the evaluation unit or the computer program executed by the evaluation unit can be part of an existing driver assistance system or another control device of the means of transportation.

A value for the first distance determined by the ultrasonic sensor can be stored in the memory unit using the evaluation unit. In addition, information about the first position of the means of transportation at which the first distance is measured can also be stored in the storage unit. This information can be obtained, for example, from an odometer control unit of the means of transportation via the vehicle electrical system

Means of transportation are received by the evaluation unit. The odometry control unit can determine relative changes in position, for example on the basis of an evaluation of rotations of one or more wheels of the

Calculate means of transportation in combination with an evaluation of the respective steering angle of the wheel or wheels of the means of transportation. Alternatively or additionally, the first position can also be determined on the basis of a GPS system of the means of transportation or on the basis of others

Position determination procedures (e.g. WLAN location etc.) are carried out.

In a second step of the method according to the invention, a second distance between the object and one of the first position

deviating second position of the means of transportation is determined by means of the first ultrasonic sensor. The second distance and the second position can preferably be determined analogously to the determination of the first distance and the first position. A determined value for the second distance and information about the second position can in turn in the

Storage unit can be stored.

In a third step of the method according to the invention, there is a change between the first distance and the second distance with respect to a distance which is a distance covered between the first Position and the second position of the means of transportation is calculated. In the event that the first position and the second position are determined on the basis of odometry data, the one between the two can

Positions covered are calculated by subtracting the respective values for the first position and the second position. A change in the first distance and the second distance with respect to the distance covered can be expressed and calculated using the following formula:

D2d = (d1 - d2) / s, where D2d stands for “Distance to Drive Distance Coefficient” and a quotient according to the invention for evaluating one

Accessibility and / or passability of an object through the

Means of transportation represents, where d1 and d2 represent the first distance and the second distance, respectively, and where s is the distance traveled

Distance between the first position and the second position is represented. In the event that the object to be evaluated with regard to a passability and / or passability is more or less exactly in the area of the

Main emission axis or main reception axis of the first ultrasonic sensor (hereinafter also referred to as “sensor axis”) in front of the ultrasonic sensor or the means of transportation, a value for the change between the first distance and the second distance (d1-d2) corresponds to a value for the distance covered Distance. The quotient from these values thus results in a value of 1 and therefore represents a maximum risk of collision with an object arranged at the level of the means of transportation. The further the object is from the sensor axis, the smaller a value for a change between the first distance and the second distance with respect to the distance covered between the two measurements for the first distance and the second distance. That is, the further the object is located in the horizontal and / or vertical direction from the sensor axis, the smaller the quotient D2d and the lower the risk of a collision

Means of transportation can be classified with the object.

In a fourth step of the method according to the invention, the object is dependent on a result of the calculation described above in the third method step when the driving maneuver is carried out

Means of transportation taken into account or not taken into account. The driving maneuver can be, for example, a parking process in a parking garage, objects that are not collision-sensitive, such as a ceiling beam detected by the first ultrasonic sensor, preferably not for issuing a warning message (eg should give an acoustic warning via a sound system of the means of transportation and / or a visual warning on a display of the means of transportation).

The evaluation unit according to the invention can evaluate collision relevance by comparing the previously determined D2d value for a respective detected object in the environment of the means of transport with a predefined threshold value which can be stored in the storage unit. This predefined threshold value can preferably be a vehicle-specific threshold value, which can be determined taking into account a maximum extent of the means of transportation (height, width and possibly also length) and an arrangement and orientation of the first ultrasonic sensor in relation to the means of transportation. The threshold value is preferably defined with regard to a predefined distance between the first position and the second position, so that all reference values for determining a collision relevance of a respective object are fixed.

This means that the measurement of the first distance and the measurement of the second distance to the respective object can preferably be carried out taking into account the predefined distance between the first position and the second position.

An evaluation of a collision relevance of a respective object carried out in this way can be transmitted by the evaluation unit according to the invention in the form of collision information to a parking and / or maneuvering assistance system, so that this object can be taken into account or not taken into account by the driver assistance system depending on the assessment. Alternatively or additionally, the collision information can also be sent to a control unit for a partially or fully automatic ferry operation of the

Means of transportation are transmitted so that this control unit can adapt a driving maneuver currently to be carried out in a suitable manner to the collision information.

The method described above presupposes that an object detected by the first ultrasonic sensor in the environment of the means of transportation can be identified as one and the same object between a first distance measurement at the first position and a second distance measurement at the second position, so that the respective measured object Distances can be related. For this purpose, numerous methods are known from the prior art

Object identification or object recognition and object localization are known, which can be used in this context and are therefore not described in detail here.

The subclaims show preferred developments of the invention.

In a further advantageous embodiment of the present invention, a horizontal position of the object with respect to a trajectory of the

Locomotion means determined based on at least a second ultrasonic sensor and an object localization algorithm. The second ultrasonic sensor can be arranged, for example, in the horizontal direction next to the first ultrasonic sensor in the front area of the means of transportation. Due to an essentially parallel alignment of the first and second ultrasonic sensors in the direction of travel of the means of transportation, potentially collision-relevant objects can usually are detected both by the first ultrasonic sensor and by the second ultrasonic sensor. Furthermore, the second

Ultrasound sensor, preferably analogously to the first ultrasound sensor, can be connected to the evaluation unit according to the invention in terms of information technology. This means that the evaluation unit can receive measurement signals from the first ultrasonic sensor and the second ultrasonic sensor in the course of an environment detection at a respective position of the means of transportation. Using a suitable algorithm, the evaluation unit can insert one and the same object into the

Ideally, clearly identify measurement signals of the first ultrasonic sensor and ideally in the measurement signals of the second ultrasonic sensor. Since the

Evaluation unit also a distance between the first

Ultrasound sensor and the second ultrasound sensor is known (e.g. by values stored in the storage unit for the arrangement and alignment of the ultrasound sensors on the means of transportation), this can be done by a

then applying a suitable object location algorithm, which may be a lateration algorithm, for example, a horizontal one

Determine the position and a distance of a respective object with respect to the trajectory of the means of transportation. On the basis of the information determined about a horizontal position of a respective object, a lateral passability of the respective object can also be assessed and information derived therefrom about a collision relevance analogous to the above described process steps are applied. Remaining objects, that is to say objects which are potentially collision-relevant on the basis of a current trajectory of the means of transport and on the basis of their horizontal position, can then be assessed using the method steps according to the invention with regard to being accessible.

It should be noted that all of the method steps described above are not limited to the use of a first and / or second ultrasonic sensor, but that further ultrasonic sensors (for example third, fourth or more) can also be used in order, inter alia, to a

Improve object localization and / or ensure a larger detection area by a plurality of ultrasonic sensors.

It should also be pointed out that the assessment of the ability to drive under and / or passability of an object by the means of transportation is preferably carried out on the basis of the measurement signals of the first ultrasonic sensor and the second ultrasonic sensor used for the horizontal position determination, which are used for a subsequent evaluation of the ability to drive under and / or passability can be buffered in the storage unit and can be retrieved from there accordingly. In this way, it is not necessary to measure the first distance and the second distance again at the first and second positions.

In a further advantageous embodiment of the present invention, the calculation of the change between the first distance and the second distance with respect to the distance covered is carried out as a function of the falling below a predefined distance by the first distance and / or the second distance. In other words, a calculation of the D2d value by the evaluation unit according to the invention for a specific object can be omitted if a determined first and / or second

Distance is greater than the predefined distance. The predefined

Distance can also be stored in the storage unit and correspond to a value that represents a distance of 6 m or 7 m, for example. The predefined distance can also be adjusted depending on a current speed of the means of transportation. In this way, objects can be located further away with respect to the means of transportation are classified by the evaluation unit as not relevant to the collision as long as they are further away than the predefined distance.

In a further advantageous embodiment of the present invention, the means of transportation moves toward the object while covering the distance between the first position and the second position, essentially while maintaining a current direction of travel. In this way, it can be achieved that objects identified in the environment of the means of transportation can be assessed more reliably with regard to driving under them and / or passability, since the means of transportation are approached in a predefined manner. Frequent changes in direction of the

Means of transportation can identify one and the same object in the measurement signals of the first distance measurement and the second

Distance measurement complicate, since a viewing angle on the object and a position of the means of transportation with respect to the object changes accordingly between the respective measurements. In particular, in the event that the method according to the invention is used in connection with an autonomously driving means of transportation, the control device for autonomous driving can preferably be adapted such that a

Approach of the means of transportation to potentially collision-relevant objects - if possible - is accompanied by an essentially rectilinear trajectory of the means of transportation.

In a further advantageous embodiment of the present invention, the result of the calculation comprises information about the ability to drive under and / or passability of the object, taking into account a position of the object with respect to a trajectory and an extension of the

Means of transportation. This information can be transmitted to the parking and / or maneuvering assistance system by the evaluation unit, so that the parking and / or maneuvering assistance system can issue corresponding warnings for collision-relevant objects in the means of transportation and / or suggest and / or control an adapted trajectory for the means of transportation. An assessment of the passability of an object can also include the case that an object is directly on a through the

Means of transportation is arranged and due to a low height (e.g. a curb) through the

Means of transportation can be run over. Such information can likewise determined on the basis of the method according to the invention and transmitted to a driver assistance system.

Furthermore, the method according to the invention can be supported by the use of additional and / or alternative sensors for environment detection, the detected environment information of which can be included in the assessment of the ability to drive under and / or passability of an object by the means of transportation. LIDAR and radar sensors, cameras, and also other sensor types in question.

In a further advantageous embodiment of the present invention, information about a changed extent of the means of transportation is taken into account in connection with the method according to the invention. In other words, predefined information about a maximum height, width and length, which is adapted to a respective means of transportation, and which is preferably stored in the storage unit, can be changed, for example, by means of a user input

Means of transportation to be adjusted. This can be particularly advantageous if, for example, a height of the means of transportation changes due to the use of a roof rack, or a width, height and length of the means of transportation changes due to the use of a trailer (e.g. a caravan). In response to the input of such changed values for an expansion of the

Means of transportation by a user, the evaluation unit can have an adapted predefined threshold value for evaluating a

Determine drive-under and / or passability. As an alternative or in addition, the storage unit can also include a table which holds corresponding predefined threshold values for a plurality of height, width and length combinations for an expansion of the means of transportation.

According to a second aspect of the present invention, a device for evaluating an impact of an object in the environment of a

Proposed means of transportation on a driving maneuver of the means of transportation. The device comprises an evaluation unit with a

Data input and a data output. The evaluation unit can

for example as a processor, digital signal processor, microcontroller, or the like. A logic for executing the respective inventive Method steps can be implemented in the form of a computer program, for example, which is executed by the evaluation unit. The evaluation unit can preferably comprise an internal and / or external storage unit connected to the evaluation unit in terms of information technology in order, for example, to store data generated and / or received by the evaluation unit. In addition, the evaluation unit or the computer program executed by the evaluation unit can be part of an existing driver assistance system or a further control device of the

Be a means of transportation. Furthermore, the evaluation unit is set up in connection with the data input a first distance between the object and a first position of the means of transportation by means of a first

Ultrasonic sensor and a second distance between the object and a different from the first position of the second position

Means of transportation by means of the first ultrasonic sensor

To determine means of transportation. Furthermore, the evaluation unit is set up to calculate a change between the first distance and the second distance with respect to a distance covered by a distance

Distance between the first position and the second position of the

Means of transportation. In connection with the data output, the evaluation unit is additionally set up to take into account or not to take the object into account when carrying out the driving maneuver of the means of transportation depending on a result of the calculation.

Brief description of the drawings

Exemplary embodiments of the invention are described in detail below with reference to the accompanying drawing. Show:

Figure 1 is a flow diagram illustrating steps of a

 Embodiment of a method according to the invention;

Figure 2 shows an example of determining a drive-under

 Object by means of transportation; and

Figure 3 is a block diagram of a device according to the invention in

Connection with a means of transportation. Embodiments of the invention

Figure 1 shows a flow diagram illustrating steps of a

Embodiment of a method according to the invention. In step 100, a horizontal position of an object 40 with respect to a current trajectory of the object is determined by means of a first ultrasonic sensor 30 and a second ultrasonic sensor 35 in conjunction with an object localization algorithm

Means of transportation 80 determined. The determination is carried out on the basis of an evaluation unit 10 according to the invention, which in this exemplary embodiment is a microcontroller. In step 200, a first distance d1 between the object 40 and a first position 50 of the means of locomotion 80 is determined on the basis of the measurement signals generated by the first ultrasonic sensor 30 for determining the horizontal position of the object 40. Analogously, a second distance d2 between the object 40 and a second position 55 of the means of transportation 80 is determined in step 300. In step 400, a change between the first distance d1 and the second distance d2 is calculated with respect to a distance s which is covered

Distance s between the first position 50 and the second position 55 of the means of transportation 80 corresponds. The distance s traveled is based on a signal received by the evaluation unit 10

Vehicle odometer control unit 80 is calculated. In step 500, the object 40 is taken into account or not taken into account when performing a current driving maneuver of the means of transportation 80 depending on a result of the calculation. In the event that the object 40 is potentially collision-relevant for the means of transportation 80, corresponding information about the object 40 is sent to a parking and

Maneuvering assistance system of the vehicle 80 transmitted.

FIG. 2 shows an example for determining whether an object 40 can be driven under by a means of transportation 80, the object 40 being at a height h with respect to a first ultrasonic sensor 30 of the means of transportation 80, which prevents the object 40 from being driven under

Means of transportation 80 allows. The first ultrasonic sensor 30, which is in the direction of travel of the means of transport 80 on a bumper of the

Locomotion means 80 is arranged to be highly sensitive

Ultrasonic sensor designed with a detection range of 10 cm to 7 m and a detection angle of up to 85 °. This also includes Transport means 80 an evaluation unit 10, which by means of a

Data input 12 is connected to the first ultrasonic sensor 30 in terms of information technology. Because of the relatively high sensitivity and due to the relatively large detection angle of the first ultrasonic sensor 30, the first ultrasonic sensor 30 also detects objects 40 in the vicinity of the

Locomotion means 80 detected, which are uncritical or not relevant with regard to a passability and / or passability through the means of transportation 80. For this reason, using the evaluation unit 10, an algorithm according to the invention is carried out by the evaluation unit 10 in the form of a computer program, which is able to determine these non-critical or irrelevant objects 40 in order for them to be processed in a downstream process by the evaluation unit 10 coupled

Driver assistance system 90 not to be taken into account. In this way it is prevented that due to these irrelevant objects 40 by the

Driver assistance system 90 unnecessary warnings and / or instructions are issued to a driver of the means of transportation 80 and / or an unnecessary automatic adaptation of a ferry operation (e.g. braking or changing the direction of travel) of the means of transportation 80 is carried out.

For this purpose, the evaluation unit 10 according to the invention receives a first value at a first position 50 of the moving means 80 in motion by the first ultrasonic sensor 30, which represents a measured first distance d1 between the object 40 and a sensor surface of the first ultrasonic sensor 30. The first value is stored by means of the evaluation unit 10 in an external storage unit 20 connected to the evaluation unit. After a predefined distance s (e.g. 50 cm) has been covered by the means of transport 80, the method is analogous to

Distance measurement of the object 40 at a second position 55 of the

Vehicle 80 again measures the distance between object 40 and vehicle 80 using the first

Ultrasonic sensor 30 performed. A second value, determined in this way and received by the evaluation unit 10, for a second distance d2 between the object 40 and the means of transportation 80 is likewise stored in the storage unit 20. In addition, the evaluation unit 10 is connected via an on-board network of the means of transportation 80 to an odometry control unit, which the evaluation unit 10 uses a CAN bus system

Information about a journey made by the vehicle 80 Distance s provides. In this way, the evaluation unit 10 is able to determine a value over the distance s traveled between the first position 50 and the second position 55 in order to also store this in the storage unit 20. The evaluation unit 10 then determines a change in the first distance d1 and the second distance d2 in the form of a value d: d = d1-d2. This value is set in relation to the distance s traveled to calculate a quotient D2d (“Distance to Drive Distance Coefficient”) according to the invention: D2d = d / s. The quotient D2d is compared by the evaluation unit 10 with a predefined threshold value, which represents a vehicle-specific value for underrunability by the means of transportation 80, which is stored in the storage unit 20. In the event that the D2d value is less than or equal to the predefined threshold value, it can be assumed that the object 40 can be driven under. Due to the

The ability to drive under the object 40 is not transmitted to the driver assistance system 90 for further processing and thus for a current one

Ferry operation or a current driving maneuver of the means of transportation 80 is not used.

FIG. 3 shows a block diagram of a device according to the invention in connection with a means of transportation 80. The device comprises an evaluation unit 10, which in this example is a microcontroller. The microcontroller executes a computer program which is able to carry out the method steps according to the invention. The evaluation unit 10 has a data input 12, via which the evaluation unit 10 is connected to a first ultrasonic sensor 30 and a second ultrasonic sensor 35 in terms of information technology. In this way, the evaluation unit 10 is set up to receive and process signals representing an environment of a means of transportation 80. The received signals and / or

Calculation results and possibly further data are stored in a

External storage unit 20 connected to the evaluation unit 10 in terms of information technology. In addition, the evaluation unit 10 has a data output 14, via which the evaluation unit 10

information technology with a driver assistance system 90 des

Means of transportation 80 is connected. The evaluation unit 10 is set up to allow objects 40 to pass under the environment of the means of transportation 80 evaluate and only forward information about collision-relevant objects 40 to the driver assistance system 90.

Claims

Expectations

1. Method for evaluating an impact of an object (40) in the environment of a means of transportation (80) on a driving maneuver of the

 Means of transportation (80) comprising the steps:

 Determining (200) a first distance (d1) between the object (40) and a first position (50) of the means of transportation (80) by means of a first ultrasonic sensor (30) of the means of transportation (80),

 Determining (300) a second distance (d2) between the object (40) and a second position (55) of the means of transport (80) deviating from the first position (50) by means of the first ultrasonic sensor (30) of the means of transport (80),

 • Calculating (400) a change between the first distance (50) and the second distance (55) with respect to a distance (s) which corresponds to a distance covered (s) between the first position (50) and the second position (55) of the Means of transportation (80), and

 • Taking into account (500) or not taking into account (500) the object (40) when carrying out the driving maneuver of the

 Means of transportation (80) depending on a result of the calculation.

2. The method of claim 1 further comprising determining (100) one

 horizontal position of the object (40) with respect to a trajectory of the means of transportation (80) based on at least a second one

 Ultrasonic sensor (35) and an object localization algorithm '.

3. The method according to any one of the preceding claims, wherein the first

Distance (d1) and the second distance (d2) between the object (40) and a sensor surface of the first ultrasonic sensor (30) are determined on the means of transportation (80).

4. The method according to any one of the preceding claims, wherein the

 Taking into account or not taking into account the object (40) on the basis of a comparison of the result of the calculation with a

 predefined threshold.

5. The method according to any one of the preceding claims, wherein the determination of the first distance (d1) and the second distance (d2) is additionally based on at least the second ultrasonic sensor (35).

6. The method according to any one of the claims, wherein the calculation of

 Change between the first distance (50) and the second

 Distance (55) with respect to the distance covered (s) in

 Dependency on falling below a predefined distance by the first distance (50) and / or the second distance (55).

7. The method according to any one of the preceding claims, wherein the

 Movement means (80) when covering the distance (s) between the first position (50) and the second position (55) are moved towards the object (40) essentially while maintaining a current direction of travel.

8. The method according to any one of the preceding claims, wherein the result of the calculation is an information about a passability and / or a lateral passability of the object (40) taking into account a position of the object (40) with respect to a trajectory and an extension of the means of transportation (80) includes.

9. The method according to claim 8, wherein information about a changed extension of the means of transportation (80) is taken into account.

10. Apparatus for evaluating an impact of an object (40) in the

 Environment of a means of transportation (80) on a driving maneuver of the means of transportation (80) comprising:

 • an evaluation unit (10),

 • a data input (12), and

 A data output (14),

 the evaluation unit (10) being set up,

• in connection with the data input (12) o a first distance (d1) between the object (40) and a first position (50) of the means of transportation (80) by means of a first ultrasonic sensor (30) of the

 Locomotion means (80) to determine, and

 o to determine a second distance (d2) between the object (40) and a second position (55) of the means of transportation (80) deviating from the first position (50) by means of the first ultrasonic sensor (30) of the means of transportation (80),

· A change between the first distance (d1) and the second

Calculate distance (d2) with respect to a distance (s) which corresponds to a distance (s) between the first position (50) and the second position (55) of the means of transport (80), and • in connection with the data output (14) the object (40) when performing the driving maneuver of the means of transport (80) in

Dependency of a result of the calculation to be considered or not to be considered.