ROSMonitoring: A Runtime Verification Framework for ROS

A. Ferrando; R.C. Cardoso; M. Fisher; D. Ancona; L. Franceschini; V. Mascardi

doi:10.1007/978-3-030-63486-5_40

ROSMonitoring: A Runtime Verification Framework for ROS

A. Ferrando, R.C. Cardoso, M. Fisher, D. Ancona, L. Franceschini, V. Mascardi

Formal Methods

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

Abstract

Recently, robotic applications have been seeing widespread use across industry, often tackling safety-critical scenarios where software reliability is paramount. These scenarios often have unpredictable environments and, therefore, it is crucial to be able to provide assurances about the system at runtime. In this paper, we introduce ROSMonitoring, a framework to support Runtime Verification (RV) of robotic applications developed using the Robot Operating System (ROS). The main advantages of ROSMonitoring compared to the state of the art are its portability across multiple ROS distributions and its agnosticism w.r.t. the specification formalism. We describe the architecture behind ROSMonitoring and show how it can be used in a traditional ROS example. To better evaluate our approach, we apply it to a practical example using a simulation of the Mars curiosity rover. Finally, we report the results of some experiments to check how well our framework scales.

Original language	English
Title of host publication	Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)
Pages	387-399
Number of pages	13
DOIs	https://doi.org/10.1007/978-3-030-63486-5_40
Publication status	Published - 3 Dec 2020

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10.1007/978-3-030-63486-5_40

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title = "ROSMonitoring: A Runtime Verification Framework for ROS",

abstract = "Recently, robotic applications have been seeing widespread use across industry, often tackling safety-critical scenarios where software reliability is paramount. These scenarios often have unpredictable environments and, therefore, it is crucial to be able to provide assurances about the system at runtime. In this paper, we introduce ROSMonitoring, a framework to support Runtime Verification (RV) of robotic applications developed using the Robot Operating System (ROS). The main advantages of ROSMonitoring compared to the state of the art are its portability across multiple ROS distributions and its agnosticism w.r.t. the specification formalism. We describe the architecture behind ROSMonitoring and show how it can be used in a traditional ROS example. To better evaluate our approach, we apply it to a practical example using a simulation of the Mars curiosity rover. Finally, we report the results of some experiments to check how well our framework scales.",

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AU - Ferrando, A.

AU - Cardoso, R.C.

AU - Fisher, M.

AU - Ancona, D.

AU - Franceschini, L.

AU - Mascardi, V.

PY - 2020/12/3

Y1 - 2020/12/3

N2 - Recently, robotic applications have been seeing widespread use across industry, often tackling safety-critical scenarios where software reliability is paramount. These scenarios often have unpredictable environments and, therefore, it is crucial to be able to provide assurances about the system at runtime. In this paper, we introduce ROSMonitoring, a framework to support Runtime Verification (RV) of robotic applications developed using the Robot Operating System (ROS). The main advantages of ROSMonitoring compared to the state of the art are its portability across multiple ROS distributions and its agnosticism w.r.t. the specification formalism. We describe the architecture behind ROSMonitoring and show how it can be used in a traditional ROS example. To better evaluate our approach, we apply it to a practical example using a simulation of the Mars curiosity rover. Finally, we report the results of some experiments to check how well our framework scales.

AB - Recently, robotic applications have been seeing widespread use across industry, often tackling safety-critical scenarios where software reliability is paramount. These scenarios often have unpredictable environments and, therefore, it is crucial to be able to provide assurances about the system at runtime. In this paper, we introduce ROSMonitoring, a framework to support Runtime Verification (RV) of robotic applications developed using the Robot Operating System (ROS). The main advantages of ROSMonitoring compared to the state of the art are its portability across multiple ROS distributions and its agnosticism w.r.t. the specification formalism. We describe the architecture behind ROSMonitoring and show how it can be used in a traditional ROS example. To better evaluate our approach, we apply it to a practical example using a simulation of the Mars curiosity rover. Finally, we report the results of some experiments to check how well our framework scales.

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M3 - Conference contribution

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EP - 399

BT - Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)

ER -

ROSMonitoring: A Runtime Verification Framework for ROS

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Robotics and Artificial Intelligence for Nuclear (RAIN)

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ROSMonitoring: A Runtime Verification Framework for ROS

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Robotics and Artificial Intelligence for Nuclear (RAIN)

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