Supporting Robotic Software Migration Using Static Analysis and Model-Driven Engineering
August 05, 2020 Β· Declared Dead Β· π ACM/IEEE International Conference on Model Driven Engineering Languages and Systems
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Authors
Sophie Wood, Nicholas Matragkas, Dimitris Kolovos, Richard Paige, Simos Gerasimou
arXiv ID
2008.02164
Category
cs.SE: Software Engineering
Cross-listed
cs.RO
Citations
3
Venue
ACM/IEEE International Conference on Model Driven Engineering Languages and Systems
Last Checked
4 months ago
Abstract
The wide use of robotic systems contributed to developing robotic software highly coupled to the hardware platform running the robotic system. Due to increased maintenance cost or changing business priorities, the robotic hardware is infrequently upgraded, thus increasing the risk for technology stagnation. Reducing this risk entails migrating the system and its software to a new hardware platform. Conventional software engineering practices such as complete re-development and code-based migration, albeit useful in mitigating these obsolescence issues, they are time-consuming and overly expensive. Our RoboSMi model-driven approach supports the migration of the software controlling a robotic system between hardware platforms. First, RoboSMi executes static analysis on the robotic software of the source hardware platform to identify platform-dependent and platform-agnostic software constructs. By analysing a model that expresses the architecture of robotic components on the target platform, RoboSMi establishes the hardware configuration of those components and suggests software libraries for each component whose execution will enable the robotic software to control the components. Finally, RoboSMi through code-generation produces software for the target platform and indicates areas that require manual intervention by robotic engineers to complete the migration. We evaluate the applicability of RoboSMi and analyse the level of automation and performance provided from its use by migrating two robotic systems deployed for an environmental monitoring and a line following mission from a Propeller Activity Board to an Arduino Uno.
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