DE102015104582A1 - Method for calibrating a robot at a work area and system for carrying out the method - Google Patents

Abstract

The invention relates to a system and a method for calibrating a robot (14) on a work area (11), in which at least one camera (18) is arranged on an adjustable component of the robot, with the component at least one robot position (11). Rn_i) are approached so that at least one marker (M1, M2) is arranged in one image area (23) of the camera, wherein in the robot position (Rn_i) the image area is taken with the camera, to each of at least three mutually different marker image areas a marker image position (Bn_i; Bn_i ') of the marker (M1, M2) in the recorded image area (23) is determined, each with a marker robot position (Mn_i; Mn_i') as the position of the marker (M1, M2) is determined in the robot coordinate system (KOR) and in a calibration after a displacement of the robot or an insertion of another robot and / or later the steps are performed again and from again b determined marker robot positions (Mn_i ') over previously determined marker robot positions (Mn_i) a deviation (Δ) is determined.

Description

The invention relates to a method for calibrating a robot at a work area and to a system for carrying out the method.

Systems with a robot with a robot arm, in particular for handling objects, are generally known. In order to enable a particularly automated control of the robot arm and optionally further controllable system components, the robot, in particular its robot arm, is taught prior to a particular first start of operation on the work area. In particular, teaching is understood to mean that adjustable components of the robot - e.g. Gripper or a robot arm - are brought by particular manual moving to desired positions, with coordinates of the adjustable components for these positions then detected and used for a later automated control of the positions. This is a complex process which requires, among other things, a large number of handling steps on the part of an operator.

If a robot, e.g. However, if a mobile industrial robot is used again at a workplace known for this, the robot no longer reaches its known position 100% due to inaccuracies in the positioning of a robot base of the robot. As a result, all the positions he will approach with his robotic arm will be slightly displaced if the robotic positions taught during earlier use are used for control. Therefore, all robot positions, e.g. Gripping positions of the robot are manually re-taught or the inaccuracies, for. when gripping must be tolerable low.

A similar problem exists when a robot is defective and needs to be replaced. By replacing the robot and associated mechanical tolerances, the robot positions, e.g. Gripping positions of the new robot no longer match the robot positions of the old robot. Therefore, all robot positions of the new robot must be re-measured manually.

The object of the invention is to provide a method for calibrating a robot, which is easy to implement and enables reliable calibration. In particular, an automatic recovery of already taught gripping positions of a particular mobile industrial robot after a change in location of the robot is to be made possible. Suitable displacement or transformation data for coordinates should be provided in particular with as few method steps as possible.

This object is achieved by the method having the features of patent claim 1 and a system having the features of patent claim 13. Advantageous embodiments are the subject of dependent claims.

• – einem Kalibrieren nach einem Versetzen des Roboters,
• – einem Einsetzen eines anderen Roboters und
• – zu einem späteren Zeitpunkt

die Schritte erneut durchgeführt die Schritte erneut durchgeführt werden und aus zumindest einer, insbesondere zumindest drei derart erneut bestimmten Marker-Roboter-Positionen gegenüber derart zuvor bestimmten Marker-Roboter-Positionen eine Abweichung bestimmt wird. According to a preferred embodiment, a method for calibrating a robot at a work area, in which at least one camera is or is arranged on an adjustable component, in particular on an adjustable arm of the robot, with the adjustable component at least one robot position - in particular pose - is approached so that at least one stationary marker is arranged in an image area of the at least one camera, wherein in the at least one robot position of the image area is recorded with the at least one camera, wherein at least one recorded image area ( 23 ), in particular for each of at least three mutually different recorded image areas a marker image position of the marker in the recorded image area is determined, wherein at least one, in particular one marker robot position is determined as the position of the marker in the robot coordinate system, and at least one of

• A calibration after a displacement of the robot,
• - an insertion of another robot and
• - at a later time

the steps are performed again, the steps are carried out again and a deviation is determined from at least one, in particular at least three marker robot positions determined again in this way in relation to previously determined marker robot positions.

If these marker robot positions are compared with the marker robot positions at the time of the particular first-time teaching or during the initial setup of the robot system, the deviation is obtained as an offset (German: offset) of an offset transformation. This deviation corresponds to the Displacement and / or rotation of the robot base compared to the other, stationary system components by the inaccuracies in the positioning.

In particular, transformation data with which position data of robot positions stored and to be controlled in the system can be adapted to a changed position of a newly placed or exchanged robot in the work area are thus provided.

The adjustable component of the robot is understood in particular to be an arm of the robot, which is adjustable or movable in particular relative to a base of the robot. As far as an arm is listed, this is for ease of description accordingly for the adjustable component. Such a base is again relative to e.g. a socket positionable, which is designed for positioning of such a robot as spatially fixed device in the system surrounding the robot.

This is made possible in particular by a further development by setting up and solving a system of equations according to M (n_i) = R (n_i) * B (n_i) with M (n_i) as a marker robot position for an ith pose to an nth marker as a position of the marker in the robot coordinate system, R (n_i) as a robot position for an ith pose to an nth marker tem marker as position to be controlled of the robot in the robot coordinate system and B (n_i) as image position for an ith pose to nth marker as position of the marker in the image or image coordinate system.

By means of a calculation algorithm, the relative position of the camera on the robot, in particular in the robot gripper, with respect to the coordinate system of the mark can thus be determined. According to one embodiment, the result is the deviation, in particular a displacement of the coordinate system of the robot with respect to the coordinate system of the markers.

Thus, images of markers that have been recorded under different robot positions or so-called poses are taken into account.

A further development is a method and an arrangement in which the marker as body has a defined contour, for example a two- or three-dimensional body, e.g. in the form of a star, cuboid, heart or so-called QR code forms. This is advantageous for determining the position data during image processing of the image data captured by the camera in order to determine the marker image position within the recorded image area. However, other contours, e.g. rectangular contours suitable detectable and processable, if they allow an exact location and / or orientation of the marker in the workspace coordinate system and / or in the robot coordinate system.

In particular, a pose completely describes the position and orientation of the robot, in particular its coordinate system. In particular, the pose describes the position and orientation of all components of the robot between its base and its front arm or handling section, in particular also of additional components and tools attached thereto in the three-dimensionally clamped space. In addition to pure static coordinates of one or more points, in particular of the robot and / or the camera and / or the image positions, alignment and angle data are thus also provided for such points in particular. In the case of adjusting the arm or the camera through the space, the pose also describes, in particular, the temporal and / or spatial course of the orientation and orientation of the individual components of the robot and of the camera at least temporarily arranged thereon.

According to one development, the data from the different poses are equal and there is no pose that is treated specially. However, an unambiguous assignment of the respective pose or robot position or robot orientation to respective image areas can be produced with the image data which is used in the calculation or determination of the transformation data for calibrating the robot relative to its surroundings, in particular the work area.

If, according to a further development, e.g. If it is determined that the image quality is poor when taking a camera of a marker, for example due to blurring or that the marker is only very small visible, then this recording can not be included equally and optionally with a lower priority in the calculation.

An embodiment of the method is that the deviation is used as a correction variable for subsequently to be used in operation robot positions.

This allows position data to be used for subsequent or during a subsequent robot control, which are assigned to the robot positions and these can be controlled to correct the deviation.

An embodiment of the method is that data values of the deviation are applied to position data to be subsequently used, in particular calculated, in particular added up or subtracted therefrom, and position data adjusted in this way during further operation for activating positions of the robot and / or its at least one adjustable component, especially to use arm.

Instead of the original or previously used position data to be used by a controller, previously adapted position data which were corrected for the deviation are thus used for the robot controller.

An embodiment of this method is that the adapted further position data are stored in a memory, wherein at least one control program for controlling positions of the robot and / or its at least one movable component in operation accesses the position data previously adapted, in particular before the start of the control program ,

As a result, a calculation of corrected position data for part or all of the control programs to be carried out before the program start, in particular directly during the calibration of the robot, can be carried out. The position data are, for example, position data retrievable from the memory by a control program during its initialization or its execution.

An embodiment of the method is that a control program, in particular a software for controlling the robot and / or its at least one movable component is adjusted depending on the deviation or of the adapted further position data.

As a result, a calculation of corrected position data for part or all of the control programs to be carried out can be carried out, in particular directly during the calibration of the robot. Thus, the control program is corrected as such with regard to its integrated position data.

An embodiment of the method is that at least two mutually different robot positions are approached so that is arranged in the respective image area of the at least one camera one of two mutually different stationary markers and the other of the two markers at least partially, in particular completely outside the image area is arranged.

In particular, it is a development that in the other robot position then this one marker is partially or completely disposed within the image area and the other of the two markers is located entirely outside in the image area.

An embodiment of the method is that the at least one robot position to be approached is determined so that the image area completely captures the marker and an additional image area in at least part of the environment of the marker.

As a result of the additional image area, even if the robot is positioned in the working area in an inaccurate manner, it is ensured that the marker is preferably detected completely or at least to a proportion in the image area which is sufficiently large for the determination of its position in the image area.

An embodiment of the method is that the at least one marker is arranged stationarily on a system component, wherein the system component is spaced apart from the robot and its components and is designed to be stationary relative to the work area.

Such system components are, for example, a robot receiving device such as a robot mounting base, a work surface to be placed on the objects to be handled or processed or relative to the work area in stationary, especially rigid connection related components, such as a conveyor belt. In the system components and thus the stationary arranged thereon Markers are thus preferably objects or markings which do not change spatially between the various determinations of the marker robot positions, in particular do not change them spatially relative to one another.

In a mobile robot, the marker or the system component is fixed in particular only in certain states when the robot is stationary. As soon as the mobile robot moves with its base, the distances change.

An embodiment of the method is that the at least one camera is arranged on the adjustable component, in particular an arm, in particular a gripper of the robot and a respective camera position relative to a particular front-side portion of the adjustable component in determining the marker robot positions and the again certain marker robot positions is taken into account.

In particular, taking into account the camera position for determining the marker robot positions allows a temporary attachment of a camera, if necessary even another camera to the particular arm, without having to have exactly the same position of the camera on the arm during the later calibration procedure, such as in the previous or previous determination of the marker robot positions. This is made possible in particular by a further development by setting up and solving a system of equations according to M (n_i) = R (n_i) * C * B (n_i) with C as the camera position or position vector of the camera position. During computation, a deviation of the camera position and camera orientation of the camera relative to a defined point at the former mounting location of the camera on the robot is thus automatically excluded.

An embodiment of the method is that the recording of image areas for at least one marker with the at least one camera from at least two viewing angles or robot positions or poses is performed.

This is achieved in particular by the fact that at least two or three mutually different robot positions are approached with the arm. Overall, it is thus preferable to produce two, three or more mutually different images or images which show a marker and are recorded from mutually different viewing angles. According to a preferred embodiment, the viewing angles are different with respect to an orientation in a spatial coordinate system of the work area to each other. For example, mutually different poses or robot positions with a sufficient number of mutually different viewing angles onto a single marker can be used.

An embodiment of the method is that the taking of image areas for at least two markers with the at least one camera from at least two viewing angles, robot positions or poses is performed.

Thus, it is also possible to use two or more markers which are detected or recorded by the camera with a total of a sufficient number of mutually different viewing angles.

An embodiment is also a method in which the adjustable component at least three mutually different robot positions - in particular poses - are approached so that at each robot position in an image area of the camera at least one stationary marker is arranged, wherein in each the robot positions the image area is captured with the camera.

If several cameras are simultaneously arranged on the robot and used for recording, then with a robot pose correspondingly a plurality of images from different viewing angles can be recorded simultaneously in time. The number of poses needed can be reduced to a single pose.

A sufficient number of recorded image areas is given, in particular, when a system of equations set up for determining the marker robot positions can be solved. In particular, each robot position is in space coordinates by 3 position values or position coordinates and by 3 Orientation values or orientation coordinates defined. Depending on the configuration but also less or more coordinates can be used.

A system for carrying out a method according to any preceding claim with a work area, a robot, an installed or installable camera, at least one stationary marker, which is arranged in an adjustable image area of the camera, and a control device, wherein the control device programmed and / or designed to perform a method according to any preceding claim.

In particular, the control device is set up not only for processing the marker robot positions and marker image positions and camera position data and robot positions obtained in this way, but also for determining the robot positions or corresponding position data including, in particular, activation of the instantaneous movements and the corrected future movements of the robot.

In particular, at the first such determination, the robot and / or its arm can optionally be moved manually to the positions to detect corresponding position data there. For calibration, the robot positions or their position data are used as control data in order to move the robot and / or its arm, in particular automatically by machine, or optionally also manually, to the robot positions.

The positions are understood in particular as position data which define a defined orientation of the robot and / or its arm in space, in particular in the working area. Such position data may be acquired and / or used as control data for automatically moving the robot and / or the arm to the robot position defined by the position data, depending on the method step and type of position.

In particular, a determination of the various method steps also includes calculating position data.

The work area is also referred to as a workspace in which the robot is used. Accordingly, the system and method provide a simple and reliable workspace calibration of a robot, particularly an industrial robot.

Thus, according to a first particularly preferred variant of use, the use of a mobile robot, in particular a mobile industrial robot, in a production with a plurality of fixed work places is made possible in whose working area the robot is set up and used. Thus, according to a second particularly preferred embodiment, the use of a particularly mobile robot, in particular an industrial robot, which is used instead of a robot, which is used e.g. is defective and needs to be replaced. In all such cases, the robot is used in the work area, if necessary. Set up with suitable programs for the purpose and position data and then calibrated according to the procedure.

An embodiment will be explained in more detail with reference to the drawing. Here, the same reference numerals are used in the various figures for the same or equivalent components and method steps, so that reference is made in this regard instead of a new description to the description of the other figures. Show it:

1 a workspace, robot and camera system in a first step of a method of calibrating a robot by means of a camera,

2 the system in a second step of the process,

3 the system at a third step of the process and

4 the system at a fourth to sixth step of the process.

The figures show a system 10 with a workspace 11 a robot 14 and a camera 18 ,

The workspace 11 is for example a support area 12 to which a transport device 27 leads. By means of the transport device 27 can objects 13 to the workspace 11 towards and / or from the work area 11 be led away. At the objects 13 For example, they may be objects generated by the robot 14 to handle or manipulate.

The robot 14 includes an adjustable component, eg an arm 15 , which is articulated in particular in itself. The arm 15 has a front arm or arm portion 16 on, which can be designed in particular as a handling section. On the arm 15 , in particular on its front-side arm portion 16 are in particular devices for handling or manipulating such objects 13 locatable.

For the purpose of calibrating and performing the method of calibrating the robot relative to a stationary position or component in the system, particularly relative to the work area 11 is the camera 18 on the arm 15 , in particular on the front-side arm portion 16 arranged. In particular, the camera 18 detachable on the adjustable component, for example on a gripper 17 of the arm 15 arranged. The camera 18 preferably has an optical sensor or is designed as an optical sensor.

The camera 18 is located in particular in a defined position and orientation relative to the arm 15 or to the front arm portion 16 and other components of the robot 14 , In particular, camera position data C, C 'of the camera 18 relative to the adjustable component, in particular the arm 15 known or herausrechenbar by the preferred method.

For calibration, one or preferably several markers M1, M2, M3 are also arranged in the system. For example, a first such marker M1 is located at a position x, y, z in the working area 11 on the support area 12 , A second such marker M2 is located at the edge of the workspace 11 on a wall 28 , which are on the edge of the support area 12 extends upwards. A third such marker M3 is located on the housing of the transport device 27 ,

All markers M1, M2, M3 are arranged to be from a respective image area 23 the camera 18 are detectable in particular are completely detectable. By way of example, as markers M1, M3, star-shaped images or as markers M2 serve as a heart-shaped image, which stand out sufficiently from the background to give it image data of the camera 18 to be recognizable as such.

For processing image data by the camera 18 be recorded, and to control the robot 14 and for location and orientation determination of its components, including the arm 15 is preferably a common control device 20 , However, the camera can 18 and the robot 14 also have independent control devices or processors, in which case preferably one of these autonomous control devices or a further control device, a data processing for the determination of transformation data for calibration of the robot 14 and a fixed component of the system.

A store 21 in particular with the control device 20 is connected, is used to store control programs for the robot 14 and further system components as well as the storage or intermediate storage of recorded image data, which are to be processed, of position data, marker image positions Bn_i, robot positions Rn_i and / or marker robot positions Mn_i. Alternatively, the various data to be stored may be stored in multiple memories.

From the camera 18 recorded image data of a recorded image area 23 the camera 18 are in particular associated with a camera or image coordinate system KOB. Alignments of the arm 15 and possibly further robot components KOR and robot coordinates xr, yr, zr are described in particular by means of a robot coordinate system. Optional is also the workspace 11 assigned to a workspace coordinate system KO. In the workspace 11 , especially the support area 12 arranged to be handled objects 13 are thus the coordinate system of the work area and / or after calibration optional the coordinate system of the robot 14 assignable.

The robot 14 is located at a robot location 19 , The robot site 19 on which the robot 14 is at least temporarily used in the system fixed coordinates x, y, z. The robot 14 is from the robot site 19 temporarily removable or against another robot 14 interchangeable.

After or at an insertion of the robot 14 at the robot site 19 will be a calibration of the robot 14 performed against against a robotic base of the robot 14 adjustable components of the robot 14 like the arm 15 to be able to control selectively by means of position data for the adjustable component.

1 shows the robot 14 with his arm 15 in a first pose predefined or definable for a first method step S1 22 , The adjustable components are in this pose 22 arranged in a particular multi-dimensional writable robot position R1_1. Such robot positions define, in particular during later operating sequences, positions of the robot to be controlled in the robot coordinate system KOR. In this pose 22 is the camera 18 directed in the direction of the first marker M1 that the first marker M1 in the image area 23 the camera 18 located.

In this first pose 22 is with the camera 18 the picture area 23 recorded and corresponding image data are the controller 20 and / or the memory 21 fed.

Subsequently or in a later method step, a marker image position B1_1 of the captured marker M1 in the image area 23 certainly. The image data of the captured image area 23 in particular image coordinates xb, yb, zb are assigned in the image coordinate system KOB. This marker image position B1_1 is stored in memory 21 stored for use in later calibration procedures.

2 shows the robot 14 with his arm 15 in a second pose predefined or definable for a second method step S2 24 , The adjustable components are in this pose 24 in a relation to the previous robot position R1_1 different robot position R1_i with i = 2 arranged. The index i stands for the poses used. In this pose 24 is the camera 18 again, but directed from a different direction or component position in the direction of the first marker M1, that the first marker M1 in the image area 23 the camera 18 located.

In this second pose 24 is with the camera 18 the picture area 23 recorded and corresponding image data are the controller 20 and / or the memory 21 fed.

Subsequently or in a later method step, this further pose is posed for the image data 24 a marker image position B1_i of the captured marker M1 in the image area 23 certainly. This marker image position B1_i is also stored.

3 shows the robot 14 with his arm 15 in a second pose predefined or definable for a third method step S3 25 , The adjustable components are in this pose 25 in a relation to the previous robot positions Rn_i with i ≠ 3 different robot position Rn_i with i = 3 and n = 1 arranged. The index n stands for the marker M1 used. In this pose 25 is the camera 18 again, but directed from a still different direction or component position in the direction of the first marker M1, that the first marker M1 in the image area 23 the camera 18 located.

In this third pose 25 is with the camera 18 the picture area 23 recorded and corresponding image data are the controller 20 and / or the memory 21 fed.

Subsequent to or in a later process step, this still further pose for the image data 25 a marker image position Bn_i of the captured marker M1 in the image area 23 certainly. This marker image position Bn_i is also stored.

4 shows the robot 14 with his arm 15 in a fourth pose predefined or definable for a fourth method step S4 26 , The adjustable components are in this pose 26 in a relation to the previous robot positions Rn_i different robot position Rn_i with eg i = 1 and n = 2 arranged. In this pose 26 is the camera 18 directed in the direction of the second marker M2 that the second marker M2 in the image area 23 the camera 18 located.

In this fourth pose 25 is with the camera 18 the picture area 23 recorded and corresponding image data are the controller 20 and / or the memory 21 fed.

Subsequent to or in a later process step, this still further pose for the image data 26 a marker image position Bn_i of the captured marker M2 in the image area 23 certainly. This marker image position Bn_i is also stored.

In a fifth method step S5 marker robot positions Mn_i are determined, which stand for the ith pose to the nth marker as the position of the marker in the robot coordinate system KOR. In particular, a system of equations is set up and solved in accordance with M (n_i) = R (n_i) * C * B (n_i).

Like the determination of the marker image positions Bn_i, the determination of the marker robot positions Mn_i can also be carried out at a later time, possibly before or together with a later calibration when the robot is recalibrated 14 or another robot.

In the various process steps, the adjustable components can automatically be placed in the appropriate poses by means of the robot control or manually 22 . 24 . 25 . 26 be put.

If at a later time after, for example, replacement of the robot or reinstallation of the robot at the robot site 19 a re-calibration is performed, the above-mentioned process steps are repeated. In this case at this later time again certain marker image positions Bn_i 'can also the determination of the marker robot positions Mn_i' are marked with a "'". This also applies correspondingly to the camera position data C, C '.

As a result, a multiplicity of marker robot positions Mn_i from the first sequence of method steps S1-S5 and a corresponding multiplicity of marker robot positions Mn_i 'from the newly executed sequence of method steps S1-S5 are available in the system.

In a sixth method step S6, a deviation Δ of the new and possibly changed positions of the robot 14 opposite the position of the robot 14 during the first sequence of method steps S1-S5. In particular, a system of equations can be solved according to Δ (n_i) = M (n_i) - M (n_i ').

In a subsequent method step, the deviation Δ determined in this way is used to transmit position data or robot positions Rn_i to the optionally changed position of the robot 14 adapt. This can in particular be done by using the determined deviation Δ in the memory 21 stored such position data or robot positions Rn_i be adapted or corrected before their use or adapted or corrected during their use by a control program.

The number of process steps and poses will depend on the complexity of the robot 14 and its adjustable components.

To perform the procedure for calibrating the robot 14 and the workspace 11 relative to each other is compared to a then usual robot operation the camera 18 used. The camera 18 serves in particular for determining the position of the at least one marker M1, M2, M3 in the work area 11 , So that the robot 14 later, for example after re-installation, for example, an object 13 The components become robots 14 and especially the workspace 11 or another stationary component of the system using the camera 18 and this procedure calibrated to each other.

In particular, both determined and calculated quantities are vectorial sizes or matrices, the dimensions of which depend on the number of degrees of freedom of the base of the robot, and in particular 6.

Hereinafter, preferred components and method steps will be described with reference to a partially modified embodiment.

Preparing a fixation of visually recognizable markers is made. At least one marker is needed to enable a method performing algorithm. For the increase of the accuracy also more, eg 3 markers can be used. Markers can be positioned eg at all workstations of the mobile robot at fixed positions or at the base frame or the robot location 19 of the robot.

In addition, a camera for automatic image processing on the gripper 17 of the robot 14 attached. Possibly. an existing camera can be used. Between the position of the camera 18 and the flange of the robot 14 there may also be a shift with corresponding camera position data C.

In the case of a robot 14 who is being used on a known workstation, the following steps are performed:
As one-off preparatory work, a tapping in of all gripping positions is carried out, which corresponds to a conventional teaching of the robot positions. In addition, a recording of the optical marker M1-M3 with the camera 18 in the gripper 17 performed from at least one viewing angle.

The robot 14 Now move the camera 18 in the gripper 17 to the known positions of the markers M1-M3 at the workplace. In particular, since the markers are not image-filling, they are also shifts and / or tilts in the recorded image of the image area even if the entire robot is displaced 23 or in the image data.

At least one marker or several markers are used to take pictures from different poses or angles. In each case the internal robot position is saved. At the same time, the position of the marker in the image is determined and stored by the image processing software. For example, the following data pairs are created: Marker M1: Robot position R1_1 Image position of the marker, ie marker image position B1_1 Robot position R1_2 Marker image position B1_2 Robot position R1_3 Marker image position B1_3 Marker M2: Robot position R2_1 Marker image position B2_1 Robot position R2_2 Marker image position B2_2 Robot position R2_i Marker image position B2_i etc.

The relative position of the camera is subsequently determined by means of a calculation algorithm corresponding to the above equations 18 determined in the robot gripper with respect to the coordinate system KO of the marks M1, M2. The result is the displacement or deviation Δ of the coordinate system of the robot gripper or of the robot 14 with respect to the particular working area coordinate system KO of the markers M1, M2.

In setting up the exemplary system of equations Mi = Rn * C * Bn, Rn is the nth robot flange position, C is the camera position relative to the flange, Bn is the nth marker position in the camera system, and Mi. Position of the i-th marker in the robot system. The positions each include a position in space and an orientation in space.

The corresponding image data Bn are measured for the different approached robot positions Rn. With the equation system, the marker robot positions Mn and C are then calculated as the sought-after size.

From a comparison of these marker robot positions Mn and, if necessary, C with the marker robot positions Mn and if necessary C at the time of initial teaching or during the initial setup of the robot system, an offset transformation follows. This offset (German: offset) corresponds to the displacement or deviation Δ of the robot base due to the inaccuracies in the positioning.

In particular, in calculation, matrix calculations are optionally also performed, for example, when the robot position Rn has shifted to the initial robot position Rn (0) by one or more rotation angles.

Initial robot positions Rn (0) are e.g. tabulated as a software file. The calibration adjusts the content of the file and results in the new, changed robot positions. A manual Nachteachen is no longer necessary.

In the case of a robot 14 , which is used in place of a defective robot, for example, at a workstation, the following steps are carried out on the basis of the same principle:
On one to the robot 14 fixed environment, eg the robot location 19 as a pedestal on which the robot 14 stands, the marks M1-M3 are attached. After replacement of the robot 14 become the brand positions with the camera 18 approached.

Image acquisition, storage of the positions and calculation are carried out as in the previous case. The result here too is an offset that indicates how much the new robot has shifted compared to the old one. If the offset to all known robot positions is calculated, a continued operation of the system is made possible and a manual Nachteachen the positions avoided.

A variety of modified embodiments can be implemented.

Instead of the camera 18 Recordings of a first marker M1 from three different poses 22 . 24 . 25 and from a second marker M2 from yet another pose 26 and to evaluate the image data Bn_i, more or less markers M1, M2, M3 and / or more or less poses can also be made 22 . 24 - 26 per marker M1 for recording with the camera 18 be used. It is crucial that a sufficient number, in particular at least three independent image data are created and evaluated with regard to at least one marker.

One-dimensional, two-dimensional and even higher-dimensional markers can be used.

In addition to the exemplary three spatial coordinates shown, other and / or additional coordinates can be used. For example, angle coordinates and / or coordinates for individual robot components relative to each other in particular at least one of the image coordinate system KOB and the robot coordinate system KOR can be used.

Accordingly, the vectorial dimensions or number of scalar coordinate values, in particular of the marker image positions Bn_i, the marker robot positions Mn_i and the robot positions Rn_i, can also be greater, in particular greater than three.

The double indexing, each with an index n for the marker under consideration and an index i for the various poses to this marker serves primarily to simplify the illustration of the basic principle. Instead of double indexing, it is also possible, for example, to use a single continuous index to which the various poses and information relating to the respectively considered markers are assigned.

Can be used according to an embodiment, a camera with output of 3D data (3D: three-dimensional) instead of 2D data (2D: two-dimensional) of a conventional 2D area camera.

The three-dimensional output data of a camera additionally contain depth information in addition to the 2D image data described above. Such additional information can be included in the calculation. In the ideal case, only a camera image of a marker in exactly one robot pose is required to carry out the calibration.

The mathematical calculation M (n_i) = R (n_i) * C * B (n_i) remains the same from the basic idea, but the dimension of the system of equations decreases. In particular, the indices (n_i) run less widely, ideally n = i = 1, making the calculation even easier.

LIST OF REFERENCE NUMBERS

10

System with workspace, robot and camera

11

Workspace, especially workspace

12

Support area as system component

13

object

14

robot

15

adjustable component, in particular arm

16

front arm section

17

grab

18

Camera, in particular optical sensor

19

Robot recording device

20

control device

21

Storage

22

first pose

23

Image area of the camera

24

second pose

25

third pose

26

fourth pose

27

System component, in particular transport device

28

System component, in particular wall next to 12

Bn_i

Marker image position for i-th pose to n-th marker as the position of the marker in the image or in the KOB

Bn_i '

Marker image position with new measurement

C

Camera position data relative to 16

C '

Camera position data at new measurement

i

Index for poses with 1, 2, 3, ...

KO

Workspace coordinate system

KOB

Image coordinate system

KOR

Robot coordinate system

M1, M2, M3

marker

Mn_i

Marker robot position for ith pose to nth marker as the position of the marker in the robot coordinate system

Mn_i '

Marker robot position at new measurement

Rn_i

Robot position for i-th pose to n-th marker as position to be controlled of the robot in the robot coordinate system

Δ

Deviation, especially displacement

n

Index for robot positions with 1, 2, 3, ...

x, y, z

Work area coordinates

xb, yb, eg

 Image coordinates

xr, yr, zr

 Robot coordinate

S1-S6

Steps of the procedure

Claims (13)

Method for calibrating a robot ( 14 ) at a workspace ( 11 ), in which - at least one camera ( 18 ) on an adjustable component, in particular on an adjustable arm ( 15 ) of the robot ( 14 ) is arranged or is, - with the adjustable component at least one robot position (Rn_i) - in particular pose ( 22 . 24 . 25 . 26 ) - approached so that in an image area ( 23 ) of the at least one camera ( 18 ) at least one stationary marker (M1, M2) is arranged, - wherein in the at least one robot position (Rn_i) the image area ( 23 ) with the at least one camera ( 18 ), to at least one recorded image area ( 23 ), in particular to each of at least three differently recorded image areas ( 23 ) a marker image position (Bn_i; Bn_i ') of the marker (M1, M2) in the captured image area (FIG. 23 ), wherein at least one, in particular in each case a marker robot position (Mn_i; Mn_i ') is determined as the position of the marker (M1, M2) in the robot coordinate system (KOR) and - in at least one of - a calibration after a displacement of the robot ( 14 ), - inserting another robot ( 14 ) and - the steps are carried out again at a later point in time and a deviation (Δ) from at least one, in particular at least three, determined marker robot positions (Mn_i ') relative to previously determined marker robot positions (Mn_i) becomes.  Method according to Claim 1, in which the deviation (Δ) is used as the correction variable for subsequently to be used in operation robot positions (Rn_i). Method according to Claim 1 or 2, in which data values of the deviation (Δ) are applied, in particular calculated, to position data to be subsequently used, and position data adapted in this way during further operation for controlling positions of the robot ( 14 ) and / or its at least one adjustable component, in particular to use arm. Method according to Claim 3, in which the adapted further position data are stored in a memory ( 21 ), wherein at least one control program for controlling positions of the robot and / or its at least one movable component in operation accesses the position data previously adapted, in particular before the start of the control program. Method according to Claim 3 or 4, in which a control program, in particular a software for controlling the robot ( 14 ) and / or whose at least one mobile component is adapted as a function of the deviation (Δ) or of the adapted further position data. Method according to one of the preceding claims, in which at least two mutually different robot positions (Rn_i) are approached in such a way that in the respective image area ( 23 ) of the at least one camera ( 18 ) one of two mutually different fixed markers (M1; M2) is arranged and the other of the two markers (M2; M1) at least partially, in particular completely outside the image area ( 23 ) is arranged. Method according to one of the preceding claims, in which the at least one robot position (Rn_i) to be approached is determined in such a way that the image area ( 23 ) detects the marker (M1, M2) completely and an additional image area in at least part of the environment of the marker (M1, M2). Method according to one of the preceding claims, in which the at least one marker (M1, M2, M3) is fixedly attached to a system component ( 12 . 28 . 27 ), the system component ( 12 . 28 . 27 ) from the robot ( 14 ) and its components spaced and relative to the work area ( 11 ) is stationary. Method according to any preceding claim, wherein the at least one camera ( 18 ) on the adjustable component, in particular an arm ( 15 ), in particular a gripper ( 17 ) of the robot ( 14 ) and a respective camera position (C) relative to a particular front-side portion of the adjustable component in determining the marker robot positions (Mn_i) and the redetermined marker robot positions (Mn_i ') is taken into account. Method according to one of the preceding claims, in which the recording of image areas (B1_1, B1_i, Bn_i; B1_1 ', B1_i', Bn_i ') for at least one marker (M1) with the at least one camera ( 18 ) from at least two viewing angles or robot positions (Rn_i) or poses ( 22 . 24 . 25 ) is carried out. A method according to any preceding claim, wherein the taking of image areas (B1_1, B1_i, Bn_i, Bn_i; B1_1 ', B1_i', Bn_i '(n = 1), Bn_i' (n = 2)) for at least two markers (M1, M2) with the at least one camera ( 18 ) from at least two viewing angles, robot positions (Rn_i) or poses ( 22 . 24 . 25 . 26 ) is carried out. Method according to one of the preceding claims, in which - with the adjustable component at least three mutually different robot positions (Rn_i) - in particular poses ( 22 . 24 . 25 . 26 ) - be approached so that at each robot position (Rn_i) in one image area ( 23 ) the camera ( 18 ) at least one stationary marker (M1, M2) is arranged, - wherein in each of the robot positions (Rn_i) the image area ( 23 ) with the camera ( 18 ) is recorded. System for carrying out a method according to any preceding claim with a work area ( 11 ), a robot ( 14 ), an installed or installable camera ( 18 ), at least one fixed marker (M1, M2), which is located in an adjustable image area ( 23 ) the camera ( 18 ), and a control device ( 20 ), wherein the control device ( 20 ) is programmed and / or designed to perform a method according to any preceding claim.

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