WO2018041408A1 - System for sensing position and method for sensing position - Google Patents

Abstract

The invention relates to a system and to a method for sensing the position of an object, in particular a vehicle, characterized in that the system comprises the object, a camera connected to the object, and a two-dimensional optically readable code, in particular QR code, wherein the two-dimensional optically readable code is at a distance from the object, wherein the camera is designed to sense the two-dimensional optically readable code, wherein the spatial position of the two-dimensional optically readable code is known, in particular in a world coordinate system.

Description

 Situation tracking system and position sensing system

Description:

The invention relates to a system for position detection and a method for position detection.

From DE 695 18 098 T2 a method and an apparatus for reading an optical two-dimensional code are known.

From DE 10 2012 208 132 A1 a method for vehicle localization is known as the closest prior art.

From US 201 1/0121068 A1 a method for determining the position and the

Determining the spatial rotational position of an object known.

The invention is therefore based on the object of developing a system for position detection and a method for position detection, wherein the system and the method should be simplified. According to the invention the object is achieved in the system for position detection according to the features specified in claim 1 and in the method for position detection according to the features specified in claim 8.

Important features of the invention in the system for detecting the position of an object, in particular a vehicle, are that

the system the object, a camera connected to the object and a

two-dimensional optically readable code, in particular QR code, wherein the two-dimensional optically readable code is spaced from the object, the camera being arranged to detect the two-dimensional optically readable code, wherein the spatial position of the two-dimensional optically readable code, in particular in a world coordinate system, is known. The advantage here is that in the two-dimensional optically readable code information is written, such as the spatial position of the two-dimensional optically readable code in the world coordinate system and / or the size of the two-dimensional optically readable code, ie the length and width of the two-dimensional optically readable code ,

Advantageously, the two-dimensional optically readable code has positioning symbols that can be used to determine the orientation of the optically readable code in space. Thus, the two-dimensional optically readable code functions both as a storage means and as a reference point for the determination of the spatial position. Both information can be detected in a simple manner by means of the optical camera in one step.

In an advantageous embodiment, the two-dimensional optically readable code has the following information: a spatial position information of the two-dimensional optically readable code in the world coordinate system and / or

 size information of the two-dimensional optically readable code, in particular indicating the length and width of the two-dimensional optically readable code, and / or

an identity information of the two-dimensional optically readable code and / or a checksum. The advantage here is that the respective information in the two-dimensional optically readable code as brightness contrast and / or color contrast can be stored and is read out in a simple manner. The checksum improves the security of storing and reading the information. In an advantageous embodiment, the system has a storage means, in particular wherein the object has the storage means, wherein the storage means is arranged, an assignment of the two-dimensional optically readable code to the respective

Size information and / or the respective spatial position information store. The advantage here is that the two-dimensional optically readable code is compact executable, since the identity information of the two-dimensional optically readable code in the storage means with the spatial position information and / or the size information of the two-dimensional code can be linked. Thus, the spatial position information and / or the

Size information by means of the identity information when reading the memory means the two-dimensional optically readable code uniquely assignable.

In an advantageous embodiment, the system has an evaluation means, in particular wherein the object has the evaluation means, wherein the evaluation means is arranged from a captured by the camera image of the two-dimensional optically readable code and the size information, the spatial position of the two-dimensional optically readable code in a first coordinate system whose origin is in the camera to determine. The advantage here is that from the spatial position of the two-dimensional optically readable code in the first coordinate system, the spatial position of the object relative to the two-dimensional optically readable code by means of the evaluation by means of determinable and therefrom with the spatial position of the two-dimensional optically readable code in the world coordinate system spatial position of the object in the world coordinate system by means of the evaluation means can be determined. In an advantageous embodiment, the object is a driverless transport vehicle, wherein the movement of the driverless transport vehicle by means of the system for position detection is controllable, in particular wherein the evaluation means as a control means of the driverless

Transport vehicle is executed. The advantage here is that the driverless

Transport vehicle has all the means for control and navigation in the world coordinate system. Thus, the driverless transport vehicle is autonomous by means of the two-dimensional optically readable code or a plurality of two-dimensional optically readable codes in the world coordinate system, in particular a warehouse and / or a factory hall,

navigable. In an advantageous embodiment, the camera is rigidly connected to the object, wherein the spatial position of the camera in a second coordinate system, in whose origin the object is located, is constant. The advantage here is that the spatial location of the

two-dimensional optically readable codes in the first coordinate system in a simple manner in the spatial position of the two-dimensional optically readable code in the second coordinate system is convertible.

In an advantageous embodiment, the camera is pivotally connected to the object, wherein the system comprises an angle sensor for detecting a pivot angle of the camera relative to the object, wherein the spatial position of the camera in a second

 Coordinate system, in whose origin the object lies, is dependent on the swivel angle. The advantage here is that by means of the pivotally mounted on the object camera, the two-dimensional optically readable code can be detected in a larger area than by means of a rigidly connected to the object camera.

Important features of the invention in the method for detecting the position of an object, in particular by means of a system for position detection as described above

or according to at least one of claims 1 to 7, that the method comprises the following method steps: wherein in a first method step, a two-dimensional optically readable code, in particular a QR code, is detected by a camera, wherein in a second method step, the temporally after the first method step, a size information of the two-dimensional optical code from one of the

Camera is detected image of the two-dimensional optically readable code is evaluated and from the size information and the image, the spatial position of the two-dimensional optically readable code in the first coordinate system, in the origin of the camera is determined, wherein in a third step, the time after the second method step takes place, from the spatial position of the two-dimensional optically readable code in the first coordinate system and the spatial position of the camera in a second Coordinate system, in whose origin the object is located, the spatial position of the two-dimensional optically readable code is determined in the second coordinate system, wherein in a fourth method step, which occurs temporally after the third method step, from the spatial position of the two-dimensional optically readable code in the second Coordinate system, the relative orientation of the object is determined to the two-dimensional optically readable code in the second coordinate system, wherein in a fifth process step, the time after the fourth process step or at the same time takes place with the second process step and / or the third process step and / or the fourth process step, the image is evaluated and the spatial position of the two-dimensional optically readable code is determined in a world coordinate system, wherein in a sixth method step, the time after the fourth method step and the fifth method step is carried out, the spatial position of the object in the world coordinate system is determined from the spatial position of the two-dimensional optically readable code in the world coordinate system and the relative orientation of the object relative to the two-dimensional optically readable codes in the second coordinate system.

The advantage here is that in the two-dimensional optically readable code information is written, such as the spatial position of the two-dimensional optically readable code in the world coordinate system and / or the size of the two-dimensional optically readable code, ie the length and width of the two-dimensional optically readable code ,

Advantageously, the two-dimensional optically readable code has positioning symbols that can be used to determine the orientation of the optically readable code in space.

Thus, the two-dimensional optically readable code functions both as a storage means and as a reference point for the determination of the spatial position. Both information can be detected in a simple manner by means of the optical camera in one step. In an advantageous embodiment, in the fifth method step, a

Identity information of the two-dimensional optically readable code evaluated and the spatial position of the two-dimensional optically readable code in the

World coordinate system read from a memory means. The advantage here is that the two-dimensional optically readable code is compact executable.

In an advantageous embodiment, in the second method step from the relative size of the two-dimensional optically readable code in the figure and the

Size information determines the distance of the two-dimensional optically readable code to the camera. The advantage here is that the distance of the two-dimensional optically readable code to the camera from the code itself can be determined. There is no need for another reference point.

In an advantageous embodiment is in the second step of the

perspective distortion and the position of the two-dimensional optically readable code in the figure determines the orientation of the two-dimensional optically readable code relative to the camera. The advantage here is that the two-dimensional optically readable code positioning symbols and a predetermined shape, in particular a rectangular shape, in particular square shape, from which the perspective distortion in a simple manner by means of the figure can be determined.

In an advantageous embodiment, the spatial position of the two-dimensional optically readable code in the first coordinate system is determined from the distance of the two-dimensional optically readable code to the camera and the orientation of the two-dimensional optically readable code relative to the camera. The advantage here is that from the spatial position of the two-dimensional optically readable code in the first coordinate system, the spatial position of the object relative to the two-dimensional optically readable code can be determined. In an advantageous embodiment, in the second method step

Identity information of the two-dimensional optically readable code evaluated from the image, wherein the size information associated with the identity information of the two-dimensional optically readable code is read from the memory means. The advantage here is that the two-dimensional optically readable code is compact executable. Further advantages emerge from the subclaims. The invention is not limited to the combination of features of the claims. For the expert, further meaningful combination options of claims and / or individual arise

Claim features and / or features of the description and / or figures, in particular from the task and / or the task by comparison with the prior art task.

The invention will now be explained in more detail with reference to figures:

FIG. 1 schematically shows a system according to the invention for position detection.

Figure 2 shows a method according to the invention for position detection in a schematic

Presentation.

The position detection system shown in FIG. 1 has a two-dimensional optically readable code 3, in particular a QR code, and an object 1, in particular a vehicle, which is movable in space. The object 1, whose spatial position is detected by means of the system, has a camera 2, an evaluation means and a storage means.

The spatial position of an object is the combination of position and orientation of the object in space. In three-dimensional space, the position in the Cartesian coordinate system is given by three coordinates (x, y, z). The orientation is defined by another coordinate system and its angular offset from the coordinate system. The spatial position is thus specified by means of six coordinates. The camera 2 is rigidly connected to the object 1. An objective of the camera 2 is arranged so as to be deflected by the object 1 on the camera 2. The spatial position of the camera 2 relative to the object, that is to say in a second coordinate system 5 whose origin lies in the object 1, is known and stored in the storage means. The orientation of the objective in the second coordinate system 5 is also known and stored in the storage means.

The two-dimensional optically readable code 3 is spaced from the object. The two-dimensional optically readable code 3 has the following information: a spatial position information of the two-dimensional optically readable code 3 in a world coordinate system 6 and / or

size information indicating the length and width of the two-dimensional optically readable code 3 and / or an identity information of the two-dimensional optically readable code 3 and / or a checksum.

The world coordinate system 6 designates the origin coordinate system with which the associated relative coordinate systems, ie the first coordinate system 4 and the second coordinate system 5, are referenced. The world coordinate system 6 gives

For example, the spatial location in an industrial plant, such as warehouse or

Factory hall. In a preferred embodiment, the identity information and the spatial location information of the two-dimensional optically readable code 3 are in the

World coordinate system 6 and the size information stored in the storage means, so that the two-dimensional optically readable code 3 has only the identity information, in particular the identity information and the checksum. The evaluation means reads out from the storage means the spatial position information of the two-dimensional optically readable code 3 associated with the identity information in the world coordinate system 6 and the size information.

The codes 3 are stationary in the world coordinate system 6, that is immovable, arranged.

The camera 2 has a first coordinate system 4 whose origin lies in the camera 2. From a photograph of an object taken by the camera 2 and the actual size of the object, the spatial position of the object in the first coordinate system 4 can be determined by means of the evaluation means.

In a further embodiment, not shown, the camera 2 is pivotally connected to the object 1. In this case, the tilt angle of the camera 2 by means of a

Angle sensor detected. The spatial position of the camera 2 depends on the

Swivel angle. To determine the spatial position of the camera 2 in

World coordinate system 6, the position of the camera 2 and the swivel angle are used.

Preferably, the object 1 is designed as a driverless transport vehicle. The driverless transport vehicle is controlled by the evaluation, wherein the Evaluation means the spatial position of the driverless transport vehicle in the

World coordinate system 6 determined by means of the two-dimensional optically readable codes 3 and so controls the direction of travel of the driverless transport vehicle. The inventive method for position detection of an object shown in FIG. 2 has the following temporally successive method steps:

In a first method step A, the two-dimensional optically readable code 3 is detected by the camera 2.

In a second method step B, the size information is evaluated from an image of the two-dimensional optically readable code 3 recorded by the camera 2. From the size information and the map of the two-dimensional optically readable code 3, the spatial position of the two-dimensional optically readable code 3 in the first

Coordinate system 4 determined. In this case, from the relative size of the two-dimensional optically readable code 3 in the image and the size information, the distance of the two-dimensional optically readable code 3 to the camera 2 is determined. From the

perspective distortion and the position of the two-dimensional optically readable code 3 in the figure, the orientation of the two-dimensional optically readable code 3 relative to the camera 2 is determined. Subsequently, the spatial position of the two-dimensional optically readable code 3 in the first coordinate system 4 is determined from the distance to the camera 2 and the orientation relative to the camera 2.

In a third method step C, the spatial position of the two-dimensional optically readable code 3 in the second coordinate system 5 is determined from the spatial position of the two-dimensional optically readable code 3 in the first coordinate system 4 and the spatial position of the camera 2 in the second coordinate system 5.

In a fourth method step D, the relative position of the spatial position of the two-dimensional optically readable code 3 in the second coordinate system 5 becomes

Object 1 to the two-dimensional optically readable code 3 in the second coordinate system 5 determined. In a fifth method step E, which takes place after the fourth method step D or at the same time as the second method step B and / or the third method step C and / or the fourth method step D, the identity information of the

evaluated two-dimensional optically readable code 3 and read the spatial position of the two-dimensional optically readable code 3 in the world coordinate system 6 from the memory means.

In a sixth method step F, which takes place after the fourth method step D and the fifth method step E, the spatial position of the two-dimensional optically readable code 3 in the world coordinate system 6 and the relative orientation of the object 1 relative to the two-dimensional optically readable code 3 in FIG the second

Coordinate system 5 determines the spatial position of the object 1 in the world coordinate system 6 as a method result G. In a further exemplary embodiment, which is not illustrated, the identity information of the two-dimensional optically readable code 3 is evaluated temporally after the first method step and before the second method step from the image of the two-dimensional optically readable code 3 detected by the camera 2. Thereafter, the information associated with the identity information of the two-dimensional optically readable code 3

Size information is read from the storage means.

LIST OF REFERENCE NUMBERS

1 object, in particular vehicle

 2 camera

 3 two-dimensional optically readable code, in particular QR code

4 first coordinate system

 5 second coordinate system

 6 world coordinate system

A first process step

B second process step

C third process step

D fourth process step

E fifth process step

 F sixth method step

G Process result

Claims

claims:

1 . System for detecting the position of an object (1), in particular of a vehicle, characterized in that the system comprises the object (1), a camera (2) connected to the object (1) and a two-dimensional optically readable code (3), in particular QR code. Code, wherein the two-dimensional optically readable code (3) is spaced from the object (1), the camera (2) being adapted to detect the two-dimensional optically readable code (3), the spatial position of the two-dimensional optically readable code (3), in particular in a world coordinate system (6), in particular therefore the first coordinate system, is known. in particular, where the world coordinate system (6) is the one

Origin coordinate system, with which associated relative

Coordinate systems, ie the first coordinate system 4 and the second

Coordinate system 5, are referenced.

2. System for position detection according to claim 1,

characterized in that

the two-dimensional optically readable code (3) comprises: a spatial position information of the two-dimensional optically readable code (3) in the world coordinate system (6) and / or

 size information of the two-dimensional optically readable code (3), in particular indicating the length and width of the two-dimensional optically readable code (3), and / or

 an identity information of the two-dimensional optically readable code (3) and / or a checksum.

3. Positioning system according to claim 2,

characterized in that

the system comprises a memory means, in particular wherein the object (1) comprises the memory means, wherein the memory means is arranged to store an association of the two-dimensional optically readable code (3) with the respective size information and / or the respective spatial position information.

4. System for position detection according to at least one of the preceding claims, characterized in that

the system has an evaluation means, in particular wherein the object (1) the

Having evaluation means, wherein the evaluation means is set up, from an image captured by the camera (2) of the two-dimensional optically readable code (3) and the size information, the spatial position of the two-dimensional optically readable code (3) in a first coordinate system (4), whose origin is in the camera (2) to determine.

5. System for position detection according to at least one of the preceding claims, characterized in that

the object (1) is a driverless transport vehicle, wherein the movement of the driverless transport vehicle is controllable as a function of the position values detected by the system for position detection, in particular wherein a position value detected at a respective time is adjusted to a predetermined desired position value by appropriate activation the drive and / or the steering unit of the vehicle, in particular wherein the evaluation means is designed as a control means of the driverless transport vehicle.

6. System for position detection according to at least one of the preceding claims, characterized in that

the camera (2) is rigidly connected to the object (1), wherein the spatial position of the camera (2) in a second coordinate system (5), in whose origin the object (1) is located, is constant.

7. System for position detection according to at least one of claims 1 to 5,

characterized in that

the camera (2) is pivotally connected to the object (1), wherein the system comprises an angle sensor for detecting a pivoting angle of the camera (2) relative to the object (1), wherein the spatial position of the camera (2) in a second coordinate system (5), in the origin of which the object (1) lies, is dependent on the swivel angle.

8. A method for detecting the position of an object (1) by means of a system for position detection according to at least one of claims 1 to 7,

comprising the method steps: wherein in a first method step (A) a two-dimensional optically readable code (3), in particular a QR code, is detected by a camera (2), wherein in a second method step (B), the time after the first Process step (A) takes place, a size information of the two-dimensional optical code (3) from one of the camera (2) detected image of the two-dimensional optically readable code (3) is evaluated and from the size information and the image, the spatial position of the two-dimensional optically readable code (3) in the first coordinate system (4), in whose origin the camera (2) is located, is determined, wherein in a third method step (C), which occurs temporally after the second method step (B), from the spatial position of the two-dimensional optically readable code (3) in the first coordinate system (4) and the spatial position of the camera (2) in a second coordinate system (5), in the Ursp tion is the object (1), the spatial position of the two-dimensional optically readable code (3) in the second coordinate system (5) is determined, in a fourth step (D), which takes place after the third step (C), from the spatial position of the two - dimensional optically readable code (3) in the second coordinate system (5) the relative orientation of the object (1) to

two-dimensional optically readable code (3) in the second coordinate system (5) is determined, wherein in a fifth method step (E), in particular the time after the fourth method step (D), the image is evaluated and the spatial position of the two-dimensional optically readable Codes (3) is determined in a world coordinate system (6), wherein in a sixth method step (F), which takes place after the fourth method step (D) and the fifth method step (E), from the spatial position of

two-dimensional optically readable codes (3) in the world coordinate system (6) and the relative orientation of the object (1) relative to the two-dimensional optically readable code (3) in the second coordinate system (5) the spatial position of the object (1) in the

World coordinate system (6) is determined, in particular wherein the world coordinate system (6) that

Origin coordinate system, with which associated relative

Coordinate systems, ie the first coordinate system (4) and the second

Coordinate system (5), are referenced.

9. A method for position detection according to claim 8,

characterized in that

in the fifth method step (E) an identity information of the two-dimensional optically readable code (3) is evaluated and the spatial position of the two-dimensional optically readable code (3) in the world coordinate system (6) is read from a memory means.

10. A method for position detection according to at least one of claims 8 to 9,

characterized in that

in the second method step (B) the relative size of the two-dimensional optically readable code (3) in the figure and the size information the distance of the

two-dimensional optically readable code (3) to the camera (2) is determined.

1 1. Method for position detection according to at least one of claims 8 to 10, characterized in that

in the second method step (B), the orientation of the two-dimensional optically readable code (3) relative to the camera (2) is determined from the perspective distortion and the position of the two-dimensional optically readable code (3) in the figure.

12. A method for position detection according to claim 10 and 1 1,

characterized in that

from the distance of the two-dimensional optically readable code (3) to the camera (2) and the orientation of the two-dimensional optically readable code (3) relative to the camera (2) the spatial position of the two-dimensional optically readable code (3) in the first

Coordinate system (4) is determined.

13. A method for position detection according to at least one of claims 8 to 12, characterized in that

in the second method step (B), the identity information of the two-dimensional optically readable code (3) is evaluated from the image, wherein the size information associated with the identity information of the two-dimensional optically readable code (3) is read from the memory means.