METHODS OF DEVELOPING INTEGRATED MODULAR AVIONICS SYSTEMS

Keywords: information systems, decision-making support, project in the aviation industry, automated design system, technological process, integrated modular avionics

Abstract

The development of modern avionics systems makes the design of such systems impossible without the use of automation tools. Currently, the area of such tools is represented by patented tools developed by major aircraft manufacturers such as Boeing and Airbus, as well as a number of open or partially open international projects, differing in terms of validity, availability of source code and documentation. All tools are based on architectural models of the developed system. This article discusses the languages available for describing architectural models of avionics systems and shows which programming language is most appropriate due to its textual notation and embedded concepts that are well suited to represent most of the elements of embedded systems. The article then presents a set of tools for designing modern avionics systems. The toolbox provides both a general platform for designing and analyzing architectural models and a specialized solution for a specific area of avionics systems. It supports creating, editing and manipulating models in both text and graphic formats.

References

1. Hayley J., Reynolds R., Lokhande K., Kuffner M. and Yenson S. (2012) Human-Systems Integration and Air Traffic. Control Lincoln laboratory journal, vol. 19(1), pp. 34-49.
2. Parkinson P. and Kinnan L. (2015) Safety-Critical Software Development for Integrated Modular Avionics. Wind River, vol. 11, no. 2.
3. Tiedeman H. and Parkinson P. (2019) Experiences of Civil Certification of Multi-Core Processing. Systems in Commercial and Military Avionics Integration Activities, vol. 1(2), pp. 419-428. doi: https://doi.org/10.3182/20110828-6- it-1002.01501.
4. Ghannem A., Hamdi M., Kessentini M. and Ammar H. (2017) Search-based requirements traceability recovery: A multi-objective approach. Proc. IEEE Congress on Evolutionary Computation (CEC), pp. 1183-1190. doi: https://ieeexplore.ieee.org/document/7969440.
5. Neretin E. (2019) J. Phys.: Conf. Ser. 1353 012005. doi: https://iopscience.iop.org/article/10.1088/1742-6596/1353/1/012005.
6. Murphy B. and Wakefield A. (2009) Early verification and validation using model-based design The MathWorks.
7. De Niz D. (2007) Diagrams and Languages for Model-Based Software Engineering of Embedded Systems: UML and AADL, SEI.
8. Gilles O. and Hugues J. (2010) Expressing and Enforcing User-Defined Constraints of AADL Models. Engineering of Complex Computer Systems (ICECCS).
9. Martin S. and Minet P. (2006) Schedulability analysis of flows scheduled with FIFO: application to the expedited forwarding class. Parallel and Distributed Processing Symposium.
10. Zelenov S. (2011) Planirovanie strogo periodicheskih zadach v sistemah real'nogo vremeni [Scheduling of Strictly Periodic Tasks in Real-Time Systems]. Trudy ISP RAN [The Proceedings of ISP RAS].
11. Konakhovych H., Kozlyuk I., Kovalenko Y. (2020) Specificity of optimization of performance indicators of technical operation and updating of radio electronic systems of aircraft. System research and information technologies, no. 3, pp. 41-54.
12. Kovalenko Y., Konakhovych H., Kozlyuk I. (2020) Specificity of optimization of performance indicators of technical operation and updating of radio electronic systems of aircraft. International Journal of Engineering Research and Applications (IJERA), vol. 10(09), pp. 48-58.
13. Kozlyuk І., Kovalenko Y. (2020) Functional bases of the software development and operation in avionics. Problems of Informatization and Management, no. 63, pp. 49-63.
14. Kovalenko Y., Kozlyuk І. (2020) Implementation of the integrated modular avionics application development complex according to the ARINC653 standard, The Bulletin of Zaporizhzhіa National University: Physical and mathematical Sciences, no. 2.

Abstract views: 260
PDF Downloads: 226
Published
2021-06-18
How to Cite
Kovalenko, Y. (2021). METHODS OF DEVELOPING INTEGRATED MODULAR AVIONICS SYSTEMS. Scientific Journal of Polonia University, 43(6), 324-334. https://doi.org/10.23856/4341
Section
TECHNOLOGY, CREATIVITY, IMPLEMENTATION