DE102021213083A1 - Procedure for carrying out instructions with a work machine - Google Patents

Abstract

A method for executing instructions for action with a working machine is shown, the method including the steps: determining whether the orientation of the instruction for action corresponds to the direction of travel of the working machine within a first tolerance, determining for instructions for action with a not more than the first tolerance of different alignment to the direction of travel, in each case an absolute distance between the working machine and the respective instruction based on the position of the working machine and the respective position of the instruction, determining, for instructions with an absolute distance which is smaller than a first predefinable value, each of a relative distance between the working machine and the respective instruction for action in the direction of travel of the working machine and transversely to the direction of travel of the working machine based on the position of the respective instruction for action, the position of the working machine and the direction of travel of the working machine, and control, for instructions for action with a relative distance, which is smaller than a second predefinable value, an external control device for executing the respective instruction. A control unit and a working machine are also shown.

Description

technical field

The technical field relates to a method for carrying out instructions for action using a working machine, and a control unit which is set up to carry out the method for carrying out instructions for action, and a working machine with such a control unit.

State of the art

Methods for executing repetitive instructions are known from the prior art.

Presentation of the invention

The invention relates to a method for carrying out instructions with a work machine. The work machine can be a truck or a construction machine, such as a wheel loader, an excavator, or a bulldozer. An instruction for action, or event, can be an instruction to perform an action. The instruction can consist of commands to carry out the action. The action can be an action to be performed with the work machine. For example, lifting a shovel of the working machine can be carried out as an action. The method can be performed iteratively. The method can be carried out at periodic intervals. The method can be used to carry out repetitive instructions. In particular, the method can be used to carry out location-dependent and repetitive instructions. For example, a first action instruction can always be executed by the method at a first location when the work machine is at the first location. The method allows the first instruction to be carried out automatically at the first location.

The method has a step of reading in information on instructions for action. The information on instructions for action can be read in by a service tool, for example by a central service tool. If the method is executed iteratively, the step of reading in can only take place in the first step of the method. Alternatively or additionally, the step of reading in can always take place when information on instructions for action has been updated, for example by the central service tool. For each instruction, information on one position and one orientation is read. The position of the instruction can describe the place where the instruction is to be carried out. In other words, each instruction can be clearly assigned a position at which it is to be carried out. In addition, information on an orientation of the handling instruction can be read. Information about the orientation of the handling instruction can be used to execute the handling instruction by executing the handling instruction when the work machine moves in the orientation of the handling instruction to the handling instruction. Alternatively, information about a position can be read in for an instruction, but no information about an orientation. In other words, such an instruction can be approached regardless of the direction. The position information may be in two-dimensional coordinate information and the orientation information in degrees in a global and non-moving stationary frame of reference.

Furthermore, the method has a step of detecting a position of the working machine. The step of detecting can occur in each iterative step of executing the method. For example, a first position of the working machine can be detected at a first time and a second position, different from the first position, of the working machine can be detected at a second, later time. The method further includes a step of determining a change in the position of the work machine. The step of determining the change in position of the work machine may be based on the sensed position of the work machine. In particular, the step of determining the change in the position of the working machine can be based on positions of the working machine detected at least at two different points in time.

The method further includes a step of determining a travel direction of the work machine based on the change in the position of the work machine. The step of determining the direction of travel can thus take place as a function of positions of the working machine that change over time.

The method also has a step of determining whether the orientation of the action instruction corresponds to the direction of travel of the work machine within a first tolerance. The orientation can be compared with the direction of travel of the work machine for each individual instruction for which an orientation has been read. The first tolerance can be specified in degrees and specify, for example, that a deviation of up to 10° is permissible for a match between the orientation of a respective instruction and the direction of travel. If the direction of travel of the working machine cannot be determined precisely enough because the speed of the working machine is too slow, the step of determining whether the alignment matches the direction of travel can be skipped or this step can be evaluated positively for each instruction. The step of determining can only take place for the instructions for which an orientation has been read. This determination step can be skipped for instructions without orientation.

The method also has a step of determining an absolute distance between the work machine and the respective instruction. The step of determining the absolute distance takes place for instructions with an alignment to the direction of travel that differs by no more than the first tolerance. In other words, the step of determining the absolute distance for all handling instructions with an orientation that differs from the direction of travel of the work machine by more than the tolerance can be avoided. If the direction of travel of the work machine could not be determined due to the vehicle speed being too slow, the step of determining the absolute distance for all instructions for action can be carried out. The step of determining the absolute distance can take place for an instruction for which no orientation has been read in and is direction-independent. The absolute distance may be the distance, defined in absolute and stationary coordinates, between the 2D coordinates of the position of each action instruction and the sensed position of the work machine. The absolute distance is determined based on the position of the work machine and the respective position of the operating instruction.

The method also has a step of determining a relative distance between the working machine and the respective operating instruction in the direction of travel of the working machine and transversely to the direction of travel of the working machine. The step of determining the relative distance takes place for instructions with an absolute distance that is smaller than a first predefinable value. The first predefined value can represent a passive search window, which can be constant or changeable. Determining the relative distance can be avoided for all instructions for action with an absolute distance that is at least equal to or greater than the first predefinable value. In other words, the relative distance can be determined for all instructions for action that lie in the passive search window. The step of determining the relative distance takes place based on the positions of the respective instruction, the position of the working machine and the direction of travel of the working machine.

The method also has a step of activating an external control device for executing the respective instruction. The actuation step takes place for instructions for action with a relative distance which is smaller than a second predefinable value. The second predefined value can be an active search window. There can be a predefined value for a distance in the direction of travel and there can be a different, predefined value for a distance transverse to the direction of travel. In other words, the active search window can be circular or rectangular. The position of the respective instruction can be singular, in other words it can only consist of one point in space. Alternatively, the position of the instruction can consist of an area, for example a circular area, around a singular central point of the instruction. Activation can take place when the position and possibly the area around the position of the instruction for action overlaps with the active search window of the work machine. In other words, the actuation can take place for all instructions whose position lies in the active search window or whose area intersects the active search window.

A method is thus advantageously shown with which action instructions can be carried out as a function of the position. The method can advantageously be used to check which instructions are to be carried out in order to carry out the most efficient execution possible. The sequence of the steps of the method can ensure that the necessary steps of determining the absolute distance and the relative distance are only carried out for those instructions that are relevant due to the alignment and the position of the instruction and the direction of travel of the working machine, i.e can be triggered. This can reduce the computational burden of the steps by avoiding unnecessary steps. By using a directional component for the action instruction, the triggering can be designed to be direction-dependent and the computing effort can also be reduced by using this directional component at an early stage.

According to a further embodiment, the action instruction can be one of activating a transmission, activating an implement, activating a drive motor, activating a steering system and activating brakes. The actuation of the transmission can be an actuation of a differential lock and, alternatively or additionally, an engagement of a gear. The actuation of the working device can be, for example, lifting a shovel in an excavator as the working machine. Controlling the drive motor can, for example, include controlling the drive motor with a minimum or maximum torque and alternatively or additionally with a minimum or maximum power. The activation of the drive motor, steering and brakes can describe an instruction for an autonomous driving function, a speed limit, a driving strategy, such as driving uphill or downhill. Alternatively or additionally, the handling instruction can be setting a parameter in a memory. For example, a parameter can be set which is used to compare with sensor measurement data. For example, a distance sensor can be influenced with a comparison parameter that can be parameterized by the action instruction in such a way that the sensor can be set to be more or less sensitive based on the action instruction. A distance sensor can be set to be more sensitive when driving in certain sectors, shown as the position of an instruction.

Advantageously, a method can thus be used to carry out different instructions that are to be carried out at specific positions. When driving uphill, the transmission can always be controlled in the same position, namely at the foot of the hill, so that a lower gear is engaged. A user of the work machine can thus be relieved in that the repetitive action of engaging a low gear at the foot of the mountain can be automatically taken over by the method.

According to a further embodiment, the method can also have a step of determining whether the respective instruction for action is in the direction of travel or against the direction of travel of the working machine. This step of determining can take place based on the direction of travel of the work machine and the respective position of the instruction. In other words, it can be determined individually for each action instruction whether it is in the direction of travel or against the direction of travel of the working machine. This can be done by dividing a work machine coordinate system into two areas. A front area can extend from the working machine in the direction of travel, and a rear area can extend from the working machine in the opposite direction to the working machine. Each instruction that is in the front area can therefore be in the direction of travel, and each other instruction can be opposite to the direction of travel. This step of determining can be carried out qualitatively, and a transformation of the coordinates of the positions of the instructions for action into the work machine coordinate system can be avoided. The step of determining the absolute distance can take place for a respective action instruction in the direction of travel of the working machine. The step of determining the absolute distance can take place for all instructions for action in the front area. The step of determining the absolute distance can be avoided for all instructions for action against the direction of travel. In connection with the step of determining whether the orientation of the instruction for action corresponds to the direction of travel within a first tolerance, the step of determining the absolute distance can only be carried out for those instructions for action which are both in the direction of travel and their respective orientation within of the first tolerance coincides with the direction of travel.

Advantageously, the method can thus ensure that the further steps of determining the absolute and the relative distance are only carried out for the handling instructions, which are in the direction of travel and can therefore be approached and thus executed. This can save computing capacity when executing the method.

According to a further embodiment, the method can also have a step of determining a respective direction vector in relation to the working machine for a respective instruction. The step of determining a direction vector in each case can take place for all instructions whose orientation corresponds to the direction of travel within the first tolerance. As an alternative or in addition, the step of determining a respective direction vector for all instructions that lie in the direction of travel of the work machine can take place. The step of determining the direction vector can be based on the position of the working machine and the position of the respective instruction. The step of determining the absolute distance for a respective instruction can take place if the direction vector of the respective instruction for action matches the direction of travel of the work machine within a second tolerance. The step of determining the absolute distance can take place for all instructions for action whose respective direction vector corresponds to the direction of travel within the second tolerance. A direction vector of an instruction can be the relative direction from the position of the work machine to the position of the respective instruction. In other words, a direction vector for an instruction can be obtained by subtracting the position of the work machine from the position of the respective instruction in stationary coordinates.

Advantageously, the step of determining the absolute distance can only be carried out for those handling instructions whose directional vectors match the direction of travel within the second tolerance. In other words, the step of determining the absolute distance can only take place for those instructions for action in the direction of which the working machine is moving. In this way, the calculation-intensive determination of the absolute and, in particular, the relative distance for all other instructions whose direction vector does not match the direction of travel within the second tolerance can be avoided. The working machine does not move toward these instructions either, and as a result unnecessary computing effort for further steps of the determination can be avoided. It cannot be expected that these instructions will be carried out.

According to a further embodiment, the method can also have a step of storing information about an instruction. The information on an instruction can be stored in a storage medium. The information can be one of the respective directional vector of the handling instruction, the absolute distance between the working machine and the handling instruction, the relative distance between the working machine and the handling instruction, whether the handling instruction is in the direction of travel of the working machine and whether the orientation of the handling instruction is no more than that first tolerance is different from the direction of travel of the working machine. In other words, the step of storing can include the steps of determining direction vectors, determining the absolute distances and determining the relative distances, and determining whether the instruction for action is in the direction of travel and whether the orientation of the instruction for action corresponds to the direction of travel, store specific values. In this way, all existing and specific information can be stored for all instructions. Thus, only this information can be stored for a first instruction for action, for which it has only been determined that its orientation differs from the direction of travel of the working machine by more than the first tolerance. The direction vector and the absolute distance can also be stored for a second instruction for action, for which the direction vector and the absolute distance have also been determined. This specific relative distance can also be stored for a third instruction for action, for which the relative distance has also been determined.

Advantageously, within the framework of the method to be carried out iteratively, all of the specific information relating to all instructions for action can be stored for each iteration step. This information can then be accessed in a later iteration step. As a result, the method can be used iteratively for executing the instructions, as a result of which the individual computing steps can access previously determined values and the computing effort in each iteration step can thus be minimized and the accuracy of the method can be increased.

According to a further embodiment, information on instructions for action can be in the form of a list. For example, a first entry in the list can describe a first instruction and a second entry in the list can describe a second instruction. The list may have been stored in the step of storing information of the action instruction. The method can also include a step of sorting the list of information on instructions for action. In other words, the sorting step can take place in an iteratively next step of the method as a function of the step of storing information of the instruction from a previous step of the method. Entries in the action instruction list may be sorted depending on information from the step of determining the directional vector, absolute distance, relative distance, whether the orientation matches the direction of travel, and whether the action instruction is in the direction of the direction of travel. In the sorting step, the order of the entries in the instructions can be changed, specifically as a function of the information on instructions. In this way, a first instruction can be sorted at the chronological start of the list, for which all steps of the determination have been carried out, for which a relative distance has therefore also been determined. A second instruction can then be sorted chronologically, to which an absolute but no relative distance has been determined. The step of determining whether each alignment is no more than the first tolerance of the direction of travel is different can be based on the list sorted in the sorting step. As an alternative or in addition, the step of determining whether the action instruction is in the direction of travel can take place based on the list sorted in the sorting step. In other words, it is possible to react to values determined in a first iterative run of the method, such as the relative and absolute distances, by sorting the list of instructions. This sorted list can then be used in a next, second iterative run of the method. The steps of determining can thus take place in a sorted order according to the sorted instructions for action.

Advantageously, when the method is carried out iteratively, information that has already been determined and stored for instructions on how to act can be accessed. As a result of the sorting, the further determination in the next iterative step of the method can thus initially take place in the chronological order of the list and thus for the more relevant instructions for action. The method for the instructions for action sorted chronologically further up in the list can thus preferably be used in order to carry out these instructions for action.

According to a further embodiment, the method can also have a step of reading in information about a new instruction. A new action instruction can be a new event, for example a new action at a new position. The step of reading in can be confirmed by a user in a step of confirmation. The user can confirm the instruction via a user interface of the work machine, for example a touch display. For example, it can be suggested to the user to save the new instruction to engage a lower gear when driving uphill. The user can confirm this in the confirming step via the user interface. As an alternative or in addition, the user can enter new instructions for action himself via the user interface and confirm them at the same time. The step of determining whether the respective orientation differs from the direction of travel of the work machine by no more than the first tolerance can be carried out based on the new instruction for action confirmed in the step of confirming. Alternatively or additionally, the step of determining whether the action instruction is in the direction of travel can take place based on the new action instruction confirmed in the confirmation step. Alternatively or additionally, the step of determining the direction vector of the new instruction, of determining the absolute distance and the relative distance can be based on the confirmed new instruction.

Thus, the method can also be used for newly appearing instructions.

According to a further embodiment, the method can also have a step of driving the user interface with information on instructions for action. In this way, information on instructions for action can be displayed to the user via the touch display of the working machine. The step of controlling the user interface can be carried out based on the information on instructions for action stored in the step of storing. In other words, the specific directional vectors, the specific absolute distances and the specific relative distances, whether the action instruction is in the direction of travel and whether its alignment is not different from the direction of travel can be displayed. Furthermore, information on the actual action of the action instruction can be displayed, for example the action lifting a shovel or the action engaging a gear.

The method can thus be used to display all available information on instructions for action to the user of the working machine.

According to a further embodiment, the method can also have a step of detecting a user input via the user interface. The user input can include confirmation via the touch display. The control step can be based on the user input detected in the detection step. In other words, only the instructions for action that have been confirmed and approved by the user can be executed. As an alternative or in addition to executing the instruction as a function of the detection step, stored information relating to at least one instruction can be deleted by user input and alternatively or additionally manipulated. If the user believes that an obsolete instruction has been saved, the user can delete it.

The method can thus advantageously also be used for safety-critical instructions, in that all safety-critical instructions can only be executed when they have been released by the user. Furthermore, the user can manipulate the list in such a way that only instructions relevant to him are found in the list.

According to a further embodiment, the step of determining the relative distance in the direction of travel and transverse to the direction of travel can only be carried out for the instructions for which the absolute distance does not increase over time in the step of determining the absolute distance between the working machine and the respective instruction has. In other words, when the method is executed iteratively, it can be determined that the absolute distance between the working machine and the first instruction for action increases between two consecutive execution steps of the method. For such a first instruction for action, the step of determining the relative distance can be avoided since the work machine effectively moves away from the instruction for action and determining the relative distance can therefore be obsolete.

Advantageously, a computationally intensive step of determining the relative distance can thus be avoided for all the instructions for which the absolute distance increases when the method is executed iteratively and the instructions are therefore not relevant.

According to a further specific embodiment, the second predefinable value can be dependent on a driving state of the working machine. The driving state can describe, for example, a speed and, alternatively or additionally, an acceleration of the working machine. The second predefinable value, or the active search window, can thus be greater when the working machine is moving at a high speed than when it is moving at a slower speed. In the case of a transverse acceleration of the work machine, for example when cornering, the second predefinable value can be greater, in particular in the transverse direction, than in the case of a lower transverse acceleration, for example when the work machine is driving straight ahead.

It is thus advantageously possible to react to different driving states by adapting the second predefinable value, ie the active search window. The method can thus be used for different driving states of the working machine to carry out instructions. If the work machine drives faster, an instruction can be executed at a relative distance, for example, which would not yet be executable at a lower speed.

In a further aspect, the invention relates to a control device which is set up to carry out the method according to an embodiment according to the preceding aspect of the invention.

A further aspect relates to the work machine with such a control device according to the previous aspect. The work machine can have a GPS receiver for determining the position of the work machine. Furthermore, the work machine can have an interface for reading in information on instructions for action and on new instructions for action. Furthermore, the work machine can have the user interface, such as the touch display, for displaying information about the instructions for action by driving. The user interface can also be used to capture the user input and to confirm the new instruction for action. Furthermore, the work machine can have the transmission for executing the instructions for action by activation. For example, the transmission can have a differential lock.

character list

• 1 shows schematically steps of a method for carrying out instructions according to an embodiment.
• 2 schematically shows components of a work machine and instructions for use around the work machine.

Detailed Description of Embodiments

1 shows schematically steps of a method for carrying out instructions 4, 6, 8, 9 according to an embodiment. Instructions 4, 6, 8, 9 are in 2 shown, which schematically shows components of a working machine 2 and instructions 4, 6, 8, 9 around the working machine 2.

The work machine 2 has a control unit 10 which is set up to carry out the method. The work machine 2 has an interface 3 which is set up to read in information on the instructions for action 4, 6, 8 in a reading step S0. The work machine 2 has a GPS receiver 14 for detecting a position of the work machine 2 S3 . Control unit 10 is set up to determine a change in the position of working machine 2 at at least two different points in time in a determining step S3.1 as a function of step S3 of detecting the position of working machine 2 . In a determination step S4, control unit 10 is set up to determine a direction of travel 2a of working machine 2 based on the change in the position of working machine 2 determined in step S3.1. The one in the 2 shown direction of travel 2a points to the right.

The control unit 10 is set up to carry out a step of determining S5.1 whether an orientation 4a, 6a of the action instruction 4, 6 corresponds to the direction of travel 2a within a first tolerance. The alignments 4a, 6a were read in the reading step S0. As in 2 shown, some instructions 4, 6 each have an orientation 4a, 6a. The orientations 4a, 6a shown point to the right. Some instructions 8, 9 are direction-independent and have no orientation. No alignment for the instructions 8 was read in the reading step S0. The alignments 4a, 6a match the direction of travel 2a of the working machine 2 within the first tolerance.

The control device 10 is also set up to carry out a step of determining S5.2 whether the action instruction 4, 6, 8 is in the direction of travel 2a. in the in 2 shown embodiment are instructions 4, 6 in the direction of travel 2a, and instruction 8 against the direction of travel 2a.

Control unit 10 is also set up to determine a step of determining S6 one direction vector for each instruction 4, 6. The respective direction vector is determined relative to the position of the working machine 2 based on the position of the working machine 2 and the respective position of the instruction 4, 6. The step of determining S6 takes place for all instructions 4, 6 whose orientation 4a, 6a matches the direction of travel 2a within the first tolerance and which lie in the direction of travel 2a.

The control unit 10 is set up to carry out a step of determining S7 an absolute distance between the work machine 2 and an instruction 4, 6 in each case. The step of determining S7 takes place for all instructions 4, 6 with a directional vector which corresponds to the direction of travel of the working machine 2 within a second tolerance. Thus, the instructions for action 4 lie within the second tolerance of the direction of travel 2a of the working machine 2 , whereas the instruction for action 6 lies outside of this second tolerance of the direction of travel 2a of the working machine 2 . In other words, the action instruction 6 is too transverse to the direction of travel 2a of the work machine 2. The step of determining S7 is therefore not carried out for the action instruction 6, and incidentally also not for the action instruction 8. This saves computing capacity.

The control unit 10 is set up to carry out a step of determining S8 a relative distance between the work machine 2 and the respective action instruction 4 . The step of determining S8 takes place for the action instruction 4 since the absolute distance between the position of the action instruction 4 and the position of the working machine 2 is smaller than a first predefinable value. The first predefined value is represented by a passive search window 16, shown in 2 , described. In other words, the instruction 4 is in the passive search window 16. This saves computing power, since the relative distance does not have to be determined for instructions 6, 8.

The control unit 10 is also set up to carry out a step of activating S9 an external control unit (not shown) for executing the instruction 4 . Activation S9 takes place for action instruction 4 since the relative distance is smaller than a second predefinable value. The second predefinable value is described by an active search window 18 . In other words, the action instruction 4 is in the active search window 18. The action instruction 4 includes engaging a gear of a transmission of the working machine 2.

Control unit 10 is set up to carry out a storage step S10. The storage S10 takes place depending on the steps of determining S5.1, S5.2, S6, S7 and S8. All determined directional vectors, absolute distances and relative distances, and whether the alignment 4a, 6a is in the direction of travel 2a and whether the instructions for action 4, 6, 8 are in the direction of travel 2a, are stored in a storage medium that is not shown further.

The control unit 10 is set up to control a user interface 12, for example a touchscreen in the exemplary embodiment shown, in a control step S11. Activation S11 takes place with information on instructions 4, 6, 8. All specific values, such as directional vectors, absolute distances and relative distances, are displayed. The driver can thus find out all the information about all instructions for action 4 , 6 , 8 via the user interface 12 .

The method also has a step of detecting S12 a user input via the user interface 12 . The detection step S12 takes place as a function of the actuation step S11. In other words, information is displayed to the user in step S11 and is confirmed by the user in step S12. Thus, for a safety-critical instruction 4, the user can enable activation S9 in step S12.

The method also has a step of sorting S2 a list of information on instructions for action 4, 6, 8. The step of sorting S2 takes place as a function of the step of storing S10 information on instructions for action in an iteratively preceding execution step of the method. Furthermore, the step of sorting S2 takes place as a function of the step of detecting S12 the user input. For example, the user can delete an instruction 4, 6, 8, and the sorting step S2 then takes place without this deleted instruction 4, 6, 8. Depending on the determined and stored information on the instructions 4, 6, 8 Entries for the instructions 4, 6, 8 sorted according to their relevance, depending on the directional vectors and distances. The step of determining S5.1 and the step of determining S5.2 in the next iterative step of the method depends on the step of sorting S2. Furthermore, steps S6-S9 depend on the sorted list.

The method also has a step of reading in S1 a new action instruction 9 . The reading in S1 takes place via the interface 3. In a step of a confirmation S1.1, the new handling instruction 9 is confirmed by the user via the user interface 12 via the touch display. The new instruction 9 is thus added to the existing list of instructions 4, 6, 8 by the user confirming S1.1. An iterative next step of determining S5.1 and determining S5.2 then takes place for all instructions 4, 6, 8, 9. Steps S6-S9 are also dependent on the sorted list.

Reference List

2

working machine

2a

direction of travel of the working machine

3

interface

4, 6, 8, 9

instruction

4a, 6a

Direction of action

10

control unit

12

user interface

14

GPS receiver

16

passive search window

18

active search window

50

Reading in information on instructions for action

S1

Reading in a new instruction

S1.1

Confirm the new instruction

S2

Sorting a list of instruction information

S3

detecting a position of the working machine

S3.1

determining a change in position of the work machine

S4

Determining a direction of travel of the working machine

S5.1

Determining whether each orientation of the instruction corresponds to the direction of travel of the working machine

S5.2

Determine whether the instructions for action are in the direction of travel

S6

Determination of a direction vector of an instruction for action

S7

Determination of an absolute distance between the working machine and an instruction for action in each case

S8

Determining a relative distance between the work machine and an instruction for action in each case

S9

Activation of an external control device to carry out the handling instruction

S10

Storage of information on instructions for action

S11

Control of the user interface with information on instructions for action

S12

Capturing user input via the user interface

Claims (13)

Method for executing instructions (4, 6, 8) with a work machine (2), the method having the steps: reading in (S0) information on instructions (4, 6, 8), with each instruction (4; 6 ; 8) information is read in each case for one position and for each up to an alignment (4a; 6a), Detecting (S3) a position of the working machine (2) and determining (S3.1) a change in the position of the working machine (2), determining (S4) a travel direction (2a) of the working machine (2) based on the change in the position of the working machine (2), determining (S5.1) whether the orientation (4a; 6a) of the instruction (4; 6) corresponds to the direction of travel (2a) of the work machine (2) within a first tolerance, determining (S7) for Instructions (4; 6; 8) with an orientation (4a; 6a) to the direction of travel (2a) that does not differ by more than the first tolerance, in each case an absolute distance between the working machine (2) and the respective instruction (4; 6; 8) based on the position of the work machine (2) and the respective position of the instruction (4; 6; 8), determining (S8) for instructions (4; 6; 8) with an absolute distance which is smaller than a first predefinable value , in each case a relative distance between the work machine (2) and the respective instruction (4; 6; 8) in the direction of travel (2a) of the working machine (2) and transversely to the direction of travel (2a) of the working machine (2) based on the position of the respective instruction (4; 6; 8), the position of the working machine (2) and the direction of travel ( 2a) the work machine (2), and control (S9), for instructions (4; 6; 8) with a relative distance which is smaller than a second predefinable value, an external control device for executing the respective instruction (4; 6; 8th). procedure after claim 1 , wherein the action instruction (4; 6; 8) is one of activating a transmission, activating an implement, activating a drive motor, activating a steering system and activating brakes. Procedure according to one of Claims 1 or 2 , further with a step of determining (S5.2) whether the respective instruction (4; 6; 8) is in the direction of travel (2a) or opposite to the direction of travel (2a) of the working machine (2), based on the direction of travel ( 2a) of the working machine (2) and the respective position of the instruction (4; 6; 8), and wherein the step of determining (S7) the absolute distance for a respective instruction (4; 6; 8) in the direction of travel (2a) of the Working machine (2) takes place. Method according to one of the preceding claims, further comprising a step of determining (S6) a respective direction vector for a respective instruction (4; 6; 8) based on the position of the working machine (2) and the position of the respective instruction (4; 6 ; 8), the step of determining (S7) the absolute distance for a respective instruction (4; 6; 8) taking place if the directional vector of the respective instruction for action matches the direction of travel (2a) of the work machine (2) within a second tolerance . Method according to one of the preceding claims, further comprising a step of storing (S10) information on an action instruction (4; 6; 8), the information being one of the respective direction vector of the action instruction (4; 6; 8), the absolute Distance between the working machine (2) and the handling instruction (4; 6; 8), the relative distance between the working machine (2) and the handling instruction (4; 6; 8), whether the handling instruction (4; 6; 8) in the direction of travel (2a) of the working machine (2) and whether the alignment (4a; 6a) of the instruction (4; 6) is no more than the first tolerance of the direction of travel (2a) of the working machine (2) different. procedure after claim 5 , wherein information on instructions for action (4, 6, 8) is in the form of a list, the list being stored in the step of storing (S10) information on the instruction for action (4; 6; 8), the method further comprising a step sorting (S2) the list of information on instructions for action (4, 6, 8), and wherein the step of determining (S5.1) whether the respective orientation (4a; 6a) is no more than the first tolerance of the direction of travel (2a) of the working machine (2) is different, based on the list sorted in the sorting step (S2). Method according to one of the preceding claims, further comprising a step of reading in (S1) information on a new instruction (9), the step of reading in (S1) being confirmed by a user in a step of confirmation (S1.1) and wherein the step of determining (S5.1) whether the respective orientation (4a; 6a) differs from the direction of travel (2a) of the work machine (2) by no more than the first tolerance, based on the step of confirming (S1. 1) confirmed new instructions for action (9). Method according to one of the preceding claims, further comprising a step of driving (S11) a user interface (12) with information on instructions for action (4, 6, 8) based on the information on instructions for action (4, 6 , 8th). procedure after claim 8 , further comprising a step of detecting (S12) a user input via the user interface (12), wherein the step of driving (S9) based on the im Step of detecting (S12) detected user input takes place. Method according to one of the preceding claims, in which the step of determining (S8) the relative distance is only carried out for the instructions (4, 6, 8) for which the step of determining (S7) the absolute distance between the working machine (2nd ) and the respective instructions (4; 6; 8) the absolute distance has not increased over time. Method according to one of the preceding claims, in which the second predefinable value is dependent on a driving state of the working machine (2). Control unit (10) which is set up to carry out the method according to any one of the preceding claims. Working machine (2) with a control unit (10). claim 12 , a GPS receiver (14) for determining (S3.1) a position of the work machine (2), an interface (3) for reading in (S0) information on instructions for action (4, 6, 8), a user interface (12) for displaying information about the handling instructions (4, 6, 8) by driving (S11), for detecting (S12) a user input and for confirming (S1.1) a new handling instruction (9), and also with a transmission for executing the Action instructions (4, 6, 8) by activation (S9).

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