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A Model-Based Fault Detection, Diagnosis and Repair for Autonomous
Robotics systems
Stefan Loigge1 and Clemens Mu¨hlbacher1 and Gerald Steinbauer1 and Stefan Gspandl2 and Michael Reip2
Abstract—Autonomous robots comprise of several complex
software and hardware components which interact with the en-
vironment to fulfill a certain task. Due to the non-determinism,
inherent of the environment and complexity of the components
one cannot expect that the robot will never show a fault. Instead
one needs to deal with the occurrence of faults in the robotics
system. As we focus on autonomous robots the robot should
deal with faults in an automated fashion.
In this paper, we present a model-based fault detection and
diagnosis method with a simple but powerful method to repair
faults. Using this method, the robot can detect and react to
faults in a timely manner. Furthermore, no human intervention
is necessary thus allowing the robot to be autonomous. As not
every repair can be performed by the robot itself the system
allows the robot also to inform the maintenance staff which
repairs are necessary. Thus, this approach reduces the time for
fault localization of the maintenance staff.
I. INTRODUCTION
Autonomous robots perform tasks in (partly) open envi-
ronments. To perform such a task, the robot uses several
complex software and hardware components which interact
with each other. Due to the (partly) open environment and
the complex components, one cannot assume that no fault
will occur. Instead one needs to design the robotic system
with faults in mind. Thus, one either add fault handling in
each component or one uses a more general approach. One
such general approach is the use of a model-based approach
as outlined in [1]. The model is used to describe the system
behavior and to allow the system to detect a fault.
The use of a model-based approach allows the robot to
determine if a fault has occurred. Furthermore, the robot
can determine which component most likely caused this
fault. Using the information which component is faulty the
robot can determine which action to perform to react to this
fault. Besides the possibility that the robot detects and reacts
to a fault a model-based approach also allows to separate
the current system description from the fault detection and
localization components. As the model is used to describe
the system the fault detection and localization can be done
on the model only. Thus, one can use the software to
perform this reasoning for many different robots without
changes. The only thing which needs to be changed for a
robot is the model of the robot. As many robotic system
1Stefan Loigge, Clemens Mu¨hlbacher and Gerald
Steinbauer are with the Institute for Software Tech-
nology, Graz University of Technology, Graz, Austria.
{sloigge,cmuehlba,steinbauer}@ist.tugraz.at
This work is partly supported by the Austrian Research Promotion Agency
(FFG) under grant 843468.
2Stephan Gspandl and Michael Reip are with incubedIT, Hart bei Graz,
Austria. {gspandl,reip}@incubedit.com reuse components of other robots, or have similar robot
components one can often reuse parts of already existing
models. Thus, further decreasing the effort to perform fault
detection and localization.
In this paper, we present such a model-based diagnosis
approach. The method uses several different observers to ob-
serve properties of the system. These properties are observed
to detect a fault. With the help of the observed properties, the
system can derive a diagnosis which component caused the
fault. This allows pinpointing the fault without extra costs as
the only information necessary for the diagnosis is already
provided through the definition of the observations. To allow
the robot to react to a detected fault a simple rule engine can
be used. The rule engine allows the robot to react fast to a
fault and to trigger more complex repair actions. Through
this fast reaction, one can reduce the chance that a robot
will endanger itself or pose a threat to its surrounding.
The remainder of the paper is organized as follows. In the
next section, we will give an overview of the fault detection,
diagnosis, and repair system. The proceeding section dis-
cusses the different observers which check system properties
in more detail. Afterward, we discuss the diagnosis engine
which is used to identify the faulty component. In Section
V we discuss the rule engine and how it can be used to
react to faults. In Section VI, we show a use case where the
system was used on an industrial robotics system. Before
we conclude the paper, we discuss some related research.
Finally, we conclude the paper and point out some future
work.
II. SYSTEM OVERVIEW
To create a robotic system, the robot operating system
(ROS) [2] is often used as a framework. With the help of
ROS one can use several software components, which are
called nodes, and interact with each other. This interaction
can be performed with the help of publisher-subscriber
principle which allows exchanging message between each
ROS node. To define and identify for such communication
channel ROS uses so-called topics. These are strings defining
an n-to-n communication channel. Furthermore, one can use
service calls to provide a service from one component to
another. In the remainder of the paper, we will focus on
messages exchanged by topics as these are used more often
as services and allow an easy introspection.
Using ROS, a robotic system can be created which uses
several software components interacting with each other. As
we are interested in detecting and identifying faults and react
to these faults we use the system depicted in Figure 1. The
9
Proceedings of the OAGM&ARW Joint Workshop
Vision, Automation and Robotics
- Titel
- Proceedings of the OAGM&ARW Joint Workshop
- Untertitel
- Vision, Automation and Robotics
- Autoren
- Peter M. Roth
- Markus Vincze
- Wilfried Kubinger
- Andreas Müller
- Bernhard Blaschitz
- Svorad Stolc
- Verlag
- Verlag der Technischen Universität Graz
- Ort
- Wien
- Datum
- 2017
- Sprache
- englisch
- Lizenz
- CC BY 4.0
- ISBN
- 978-3-85125-524-9
- Abmessungen
- 21.0 x 29.7 cm
- Seiten
- 188
- Schlagwörter
- Tagungsband
- Kategorien
- International
- Tagungsbände