DE102021006476A1 - Method and system for navigating mobile logistics robots - Google Patents

Abstract

The invention relates to a method for navigating mobile logistics robots (1) using a map that is created by detecting a working environment (8) of the mobile logistics robot (1) using sensors. It is proposed that the map is created as an intelligent topological map without using global metric map information, with landmarks (2) in the working environment (8) of the mobile logistic robot (1), which are uniquely designed via an identification system (7), detected by the sensors, recognized as such by evaluating the sensor data in a data processing unit and stored as nodes in the topological map. The invention also relates to a system for carrying out the method.

Description

The invention relates to a method for navigating mobile logistics robots using a map that is created by detecting a working environment of the mobile logistics robot using sensors.

The invention also relates to a system for carrying out the method.

Mobile robots are increasingly being used in industry and in logistics companies to automate processes in industrial production and for logistical tasks, such as order picking. Mobile robots with arm manipulators, in particular robot arms, are usually used in this case. So-called articulated-arm robots are an example of this.

The realization of mobile logistics robots, in particular autonomous industrial trucks with robot arms for load handling, for example mobile picking robots, is particularly demanding because logistics robots are supposed to move freely in a logistics area, for example a warehouse. The mobile logistics robots constantly encounter completely new working environments.

Localization is a basic requirement for navigating automated vehicles in the intralogistics environment. The basis of the localization is the agreement of an expected value with a sensory perception of the vehicle. If the sensory perception is successfully matched with the expected value, a position of the vehicle can be calculated from this. A distinction is made between relative localization and global localization.

In order to implement automatically driving vehicles, in addition to localization, vehicle guidance is also necessary, in which a closed or open control circuit calculates suitable target values for driving vehicles on the basis of a target description and the localization and, if necessary, adjusts them.

For global navigation, ie for a combination of localization and vehicle guidance, a map containing connection information in the form of obstacles, graphs or routes is often used in addition to the localization. Maps are therefore used to calculate a suitable connection based on connection information in order to connect the current position of the vehicle with the target position.

Numerous types of maps exist, including, for example, metric, semantic, or topological maps to depict connection information. The effort involved in creating maps varies greatly and requires procedures of varying complexity.

The creation of metric maps for navigation is now the standard for navigating automatically driving vehicles in the intralogistics environment. The challenge here is that the creation of metric map material either involves high technological risks, such as in the case of self-mapping, or with complex measurements of the movement space, as in particular in the case of third-party mapping.

With self-mapping, the vehicle creates its own map of the environment through exploration drives. In particular, the localization of automatic vehicles indoors is considered to be a challenge, since satellite localization has to be dispensed with for physical reasons. In order for the vehicle to create a metric map of its surroundings, it must specifically drive through and map out the unfamiliar areas, such as a warehouse. Sensor inaccuracies, i.e. random errors, and calibration differences, i.e. systematic errors, result in different metric maps for each vehicle with integral errors. Vehicles that want to use these maps have to deal with these inaccuracies technologically.

Maps created by third-party mapping have no or only very small random and systematic errors. However, these have to be adapted to changes in the environment, are inflexible and usually expensive.

Topological maps are a type of map intended to store connection information of movement space. In contrast to metric maps, topological maps represent a very simple map type in which the movement space is represented by edges and nodes. The disadvantage of these maps is that they are not suitable for navigation without changes.

The use of metric maps is robot-specific due to odometry errors and deviations in hardware components, e.g. from laser scanners. Providing the robot's own metric map to other mobile robots is difficult because of the resulting differences between the recognized environment and the stored metric map.

The present invention is based on the object of designing a method of the type mentioned and a system for carrying out the method in such a way that reliable navigation of the mobile logistics robots is also made possible indoors.

In terms of the method, this object is achieved according to the invention in that the map is created as an intelligent topological map without using global metric map information, with landmarks in the working environment of the mobile logistics robot, which are uniquely designed via an identification system, being detected by the sensors, by evaluating the Sensor data are recognized as such in a data processing unit and stored as nodes in the topological map.

In order to decouple the global navigation of the mobile logistics robots from the metric environment, a smart topological map, ie an intelligent topological map, is introduced according to the invention. This smart topological map consists of nodes that describe unique landmarks.

Really placed markings are preferably used as landmarks, which are attached to prominent positions in the working environment of the mobile logistics robot, in particular at intersections and/or curves and/or stations and/or elevators and/or gates.

The identification system preferably includes numbers and/or letter codes and/or pictograms, which are detected by means of the sensors, which are expediently attached to the mobile logistics robot, and recognized by evaluating the sensor data in the data processing unit, which is expediently also housed on the mobile logistics robot, and for automatic Navigation of the mobile logistics robot can be used in a vehicle control unit.

The mobile logistics robot can therefore detect these unique landmarks using sensors, recognize them as such and save them as nodes in the topological map.

The nodes of the topological map are connected by edges. In particular, these edges can indicate the direction of movement of the connection of the individual nodes by means of a predecessor/successor principle.

According to a particularly preferred embodiment of the invention, these edges, which connect the nodes to one another, are stored in the topological map with additional annotations of the edges.

The annotations of the edges advantageously contain information about a preferred path between two nodes and/or about a distance between two nodes and/or about a roadway width and/or about roadway obstructions, for example the number of people, oncoming traffic, blockages, and/or about speed limits and/or or about regions with interaction possibilities.

The mobile logistics robot navigates along the nodes or the recorded or loaded node network. A possible path for the navigation of the mobile logistics robot is then expediently carried out by determining a valid combination of nodes between a starting point and a destination on the intelligent topological map using the data processing unit. The starting point can be found using vehicle behavior heuristics. For example, a request to the mobile logistics robot can consist of following a route in an obstacle-oriented manner to the next junction.

The task of the mobile logistics robot for the movement execution is therefore no longer to navigate a global route, but only to the next junction. All the information required for this is in the annotated edge information of the connection element, i.e. the edge to specific nodes. This information is also subject to systematic random errors, but this information is much more reliable because the range of motion to the nearest node is much smaller and integral errors are therefore less important. Because the topological map according to the invention is completely decoupled from the metric environment after recording, but global references are created at important forks in the road and recognized by the mobile robot, navigation can take place without a global metric map, which is considered a significant innovation.

In this case, the navigation of the mobile logistics robot between the nodes is advantageously carried out reactively, with the mobile logistics robot orienting itself to the existing environment by perceiving the environment using the sensors. The mobile logistics robot can derive its driving behavior from the existing environment, be it obstacles, road markings or other features that provide orientation.

According to a preferred development of the idea of the invention, it is provided that the mobile logistics robot shares the intelligent topological map that has been created with at least one other mobile logistics robot. The other mobile logistics robot can then compare and supplement the topological map it receives with its own map. In this way, an overview of the environment is created in which the connections of the individual landmarks are known. With the smart topological map, paths and tasks can be planned along these connections of the nodes. The planned paths are then processed along the known landmarks and confirmed by recognizing the landmarks along the way. Local navigation, obstacle detection and avoidance, interaction with objects and stations can be taken over by the on-board sensors and systems and only take place locally.

If paths change, for example due to a permanent blockage of a connection between two nodes, the removal or addition of nodes, etc., the topological map can be supplemented in an agile manner. By sharing the smart topological map, other mobile robots are informed directly of the changes and can thus adapt to new situations.

In a further advantageous embodiment of the invention, at least two mobile logistics robots share information about their planned paths in the intelligent topological map, this information being used in at least one traffic management system to control traffic situations. For example, nodes that will be approached in the future can only be released if they are not occupied by vehicles driving in front.

Another development of the invention provides that the mobile logistics robot shares the generated intelligent topological map with at least one manually or partially automatically controlled vehicle in order to enable localization of the manually or partially automatically controlled vehicle. In this way, the smart topological maps can also be used for manual or semi-automated vehicles and their localization.

In a further refinement, it is possible to generate task planning based on the smart topological map, so that the vehicles generate processing hierarchies which can be used for individual transports.

The invention also relates to a system for carrying out the method with at least one mobile logistics robot with a sensor system for detecting a working environment of the mobile logistics robot and a data processing unit for evaluating the sensor data.

The system solves the problem in that landmarks are provided in the working environment of the mobile logistics robot, which are uniquely designed via an identification system and can be detected by the sensors, and the data processing unit is set up to evaluate the sensor data Recognize landmarks as such and save them as nodes in the topological map.

The identification system expediently includes optical markers, while the sensor system includes at least one optical sensor, in particular a camera, which is preferably attached to the mobile logistics robot and is used for the necessary sensory perception.

In principle, radio-based node detection is also conceivable. In this case, the identification system includes radio-based transmitters at the landmarks, while the sensor system includes at least one radio-based receiver.

• Mit der Erfindung wird eine Navigation von automatischen Fahrzeugen ohne globale metrische Karten ermöglicht.

The invention offers a whole range of advantages:

• The invention enables navigation of automated vehicles without global metric charts.

A map of mobile robot workspaces can be shared with other mobile robots. If a mobile robot recognizes changes in the area, other mobile robots learn from it.

Multi-storey work areas can be handled easily and without additions using the smart topological map. Automated vehicles are enabled to orient themselves and localize themselves, for example, with elevators in multi-storey warehouses.

The localization of mobile robots is no longer dependent on a global or local positioning system such as GPS, Galileo or WLAN.

Heuristic algorithms can use the smart topological map to plan paths and tasks. For this purpose, the smart topological map can provide heuristic weighting parameters, such as distance, lane width, frequency of bends, number of people and speed limits. Because the intelligent topological map compactly bundles the nodes and edges, no global, metric occupancy grid maps are processed. This leads to a saving in computing time.

Through an extended exchange of their planned paths, mobile robots can recognize whether other participants also have a planned path on the edges used and thus recognize upcoming traffic situations and react to them through traffic management.

• 1 eine Landmarke in einem Lagerhaus aus Sicht eines mobilen Logistik-Roboters und
• 2 die Situation aus 1 mit dem mobilen Logistik-Roboter aus einer perspektivischen Sicht von oben.

Further advantages and details of the invention are explained in more detail with reference to the exemplary embodiments illustrated in the schematic figures. show here

• 1 a landmark in a warehouse from the perspective of a mobile logistics robot and
• 2 the situation out 1 with the mobile logistics robot from a perspective view from above.

In 1 an example of a landmark 2 in a warehouse 5 is shown. In the 1 only one landmark 2 is shown, but as a rule there are several landmarks 2 in the warehouse 5. The landmarks 2 can vary by an arbitrarily represented unique identifier.

The landmarks 2 are real placed markings that are uniquely designed via an identification system 7, for example numbers, letter codes or pictograms and sensory from the mobile logistics robot 1, which is shown in the 2 can be seen, can be perceived. In the case shown, the landmark 2 is a sign 6 with unique ArUco markers 3 as machine-readable characters. The landmark 2 also contains a representation 4 for human interaction as a translation of the machine-readable characters.

The landmarks 2 are placed in the robot area that can be driven on, ie in the working environment 8 of the mobile logistics robot 1, at prominent positions, for example intersections, curves, stations, elevators, gates. The mobile logistics robot can detect these unique landmarks 2 using its on-board sensors, recognize them as such and save them as nodes in a topological map.

A smart topological map, ie an intelligent topological map, is used to decouple the global navigation of the mobile logistics robot 1 from the metric environment. This smart topological map consists of nodes formed by the unique landmarks 2 .

The 2 shows the situation 1 with the mobile logistics robot from a perspective view from above. The mobile logistics robot 1 can also be seen in this representation. Furthermore, several unique landmarks 2 can be seen in the form of signs 6, which are attached to distinctive positions in the warehouse 5. The mobile logistics robot 1 can detect these unique landmarks 2 by sensors, recognize them as such and save them as nodes in the topological map. The navigation of the mobile logistics robot 1 takes place along the nodes that describe the landmarks 2 in the topological map, or the recorded or loaded node network.

Claims (13)

Method for navigating mobile logistics robots (1) using a map that is created by detecting a working environment (8) of the mobile logistics robot (1) using sensors, characterized in that the map is an intelligent topological map without using global metric map information is created, with landmarks (2) in the working environment (8) of the mobile logistics robot (1), which are uniquely designed via an identification system (7), being detected by means of the sensors by evaluating the sensor data in a data processing unit as such recognized and stored as nodes in the topological map. procedure after claim 1 , characterized in that as landmarks (2) real placed markings are used at prominent positions in the working environment (8) of the mobile logistics robot (1), in particular at intersections and / or curves and / or stations and / or elevators and/or gates. procedure after claim 1 or 2 , characterized in that the identification system (7) comprises numbers and/or letter codes and/or pictograms. Procedure according to one of Claims 1 until 3 , characterized in that edges that connect the nodes to one another are stored in the topological map with additional annotations of the edges. procedure after claim 4 , characterized in that the annotations of the edges information about a preferred path between two nodes and / or a distance between two nodes and / or a lane width and / or lane obstructions and / or speed limits and / or about regions with interaction possibilities included. Procedure according to one of Claims 1 until 5 , characterized in that the navigation of the mobile logistics robot (1) is carried out by determining a valid node combination between a starting point and a destination on the intelligent topological map using the data processing unit. Procedure according to one of Claims 1 until 6 , characterized in that the navigation of the mobile logistics robot (1) between the nodes is carried out reactively, with the mobile logistics robot (1) being oriented by the perception of the environment using the sensors. Procedure according to one of Claims 1 until 7 , characterized in that the mobile logistics robot (1) shares the intelligent topological map created with at least one other mobile logistics robot (1). Procedure according to one of Claims 1 until 8th , characterized in that at least two mobile logistics robots (1) share information about their planned paths in the intelligent topological map, this information being used in at least one traffic management system for controlling traffic situations. Procedure according to one of Claims 1 until 9 , characterized in that the mobile logistics robot (1) shares the generated intelligent topological map with at least one manually or partially automatically controlled vehicle in order to enable localization of the manually or partially automatically controlled vehicle. System for carrying out the method according to one of Claims 1 until 10 with at least one mobile logistics robot (1) with a sensor system for detecting a working environment of the mobile logistics robot (1) and a data processing unit for evaluating the sensor data, characterized in that landmarks (2) in the working environment (8) of the mobile logistics -Robots (1) are provided, which are uniquely designed via an identification system (7) and can be detected by means of the sensors, and the data processing unit is set up to recognize the landmarks (2) as such by evaluating the sensor data and as nodes in of the topological map. system after claim 11 , characterized in that the identification system (7) comprises optical markers and the sensor system comprises at least one optical sensor, in particular a camera. system after claim 11 or 12 , characterized in that the identification system (7) comprises radio-based transmitters and the sensor system comprises at least one radio-based receiver.

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