Hybrid Simulation Framework: Advanced and Secure Training
Resumo
Simulation has been employed as a teaching, training, and procedure validation tool in several fields, such as medicine, education, and the military. Although the use of Simulation presents advantages compared to traditional methodologies, several challenges exist in designing, developing, and implementing these simulation systems. These challenges become even more complex when the project involves the development of hybrid simulators. These simulators integrate physical and virtual systems. This integration makes these simulators more immersive, enhancing the simulation experience. The present work describes a framework for developing hybrid simulator systems. The framework was applied in the “Tupi” Class Submarines retrofit simulator project. The results show that the framework is a feasible solution for hybrid simulation systems, validated through collaboration with the Brazilian Navy’s technical team (CIAMA).
Referências
Ambati, T., Srikanth, K., and Veeraraju, P. (2012). Simulation of vehicular frontal crash-test. International Journal of Applied Research in Mechanical Engineering (IJARME), 2(1):37–42.
Banks, J. (1999). Introduction to simulation. In Proceedings of the 31st conference on Winter simulation: Simulation—a bridge to the future-Volume 1, pages 7–13.
Barros, M. (2022). Marinha/ firjan senai concluem o retrofit do treinador de imersão. Last accessed 03 november 2022.
Belle, A. B., El-Boussaidi, G., Desrosiers, C., and Mili, H. (2013). The layered architecture revisited: Is it an optimization problem? In SEKE, pages 344–349.
Eldabi, T., Brailsford, S., Djanatliev, A., Kunc, M., Mustafee, N., and Osorio, A. F. (2018). Hybrid simulation challenges and opportunities: a life-cycle approach. In 2018 Winter Simulation Conference (WSC), pages 1500–1514. IEEE.
Ha, S., Cha, J.-H., Roh, M.-I., and Lee, K.-Y. (2012). Implementation of the submarine diving simulation in a distributed environment. International Journal of Naval Architecture and Ocean Engineering, 4(3):211–227.
Jr, P. R. B. (2022). Exército e firjan vão desenvolver simulador para o guarani. Last accessed 30 december 2022.
Kamal, M. N. F., Ishak, I. A., Darlis, N., Maji, D. S. B., Sukiman, S. L., Abd Rashid, R., and Azizul, M. A. (2021). A review of aerodynamics influence on various car model geometry through cfd techniques. Journal of Advanced Research in Fluid Mechanics and Thermal Sciences, 88(1):109–125.
Kim, Y.-c. and Ahn, C. (2010). Development of hybrid anti-submarine weapon training simulator using component-based development methodology. SISO.
Lin, Z., Feng, S., and Ying, L. (1998). The design of a submarine voyage training simulator. In SMC’98 Conference Proceedings. 1998 IEEE International Conference on Systems, Man, and Cybernetics (Cat. No. 98CH36218), volume 4, pages 3720–3724. IEEE.
Mentzelopoulos, M., Tanasa, M., Protopsaltis, A., and Economou, D. (2011). Explosive ordinance disposal: motion sensor simulator in nintendo wii. In Proceedings of the 29th ACM international conference on Design of communication, pages 227–234.
Milne-Thomson, L. M. (1973). Theoretical aerodynamics. Courier Corporation.
Mohapatra, S. and Kanungo, P. (2012). Performance analysis of aodv, dsr, olsr and dsdv routing protocols using ns2 simulator. Procedia Engineering, 30:69–76.
Moorthy, K., Vincent, C., and Darzi, A. (2005). Simulation based training.
Nan, Q. and Liang, M. (2018). Subsafe–a game-based training system for submarine safety. In 2018 Joint International Advanced Engineering and Technology Research Conference (JIAET 2018), pages 161–166. Atlantis Press.
Pereira, R., Couto, M., Ribeiro, F., Rua, R., Cunha, J., Fernandes, J. P., and Saraiva, J. (2017). Energy efficiency across programming languages: how do energy, time, and memory relate? In Proceedings of the 10th ACM SIGPLAN International Conference on Software Language Engineering, pages 256–267.
SENAI (2022). Firjan senai vai desenvolver simuladores para o exército, fortalecendo a base industrial de defesa do brasil. Last accessed 30 december 2022.
Shannon, R. E. (1992). Introduction to simulation. In Proceedings of the 24th conference on Winter simulation, pages 65–73.
Zheng, S., Huang, Q., Jin, J., and Han, J. (2009). Flight simulator architecture development and implementation. In 2009 International Conference on Measuring Technology and Mechatronics Automation, volume 2, pages 230–233. IEEE.
Banks, J. (1999). Introduction to simulation. In Proceedings of the 31st conference on Winter simulation: Simulation—a bridge to the future-Volume 1, pages 7–13.
Barros, M. (2022). Marinha/ firjan senai concluem o retrofit do treinador de imersão. Last accessed 03 november 2022.
Belle, A. B., El-Boussaidi, G., Desrosiers, C., and Mili, H. (2013). The layered architecture revisited: Is it an optimization problem? In SEKE, pages 344–349.
Eldabi, T., Brailsford, S., Djanatliev, A., Kunc, M., Mustafee, N., and Osorio, A. F. (2018). Hybrid simulation challenges and opportunities: a life-cycle approach. In 2018 Winter Simulation Conference (WSC), pages 1500–1514. IEEE.
Ha, S., Cha, J.-H., Roh, M.-I., and Lee, K.-Y. (2012). Implementation of the submarine diving simulation in a distributed environment. International Journal of Naval Architecture and Ocean Engineering, 4(3):211–227.
Jr, P. R. B. (2022). Exército e firjan vão desenvolver simulador para o guarani. Last accessed 30 december 2022.
Kamal, M. N. F., Ishak, I. A., Darlis, N., Maji, D. S. B., Sukiman, S. L., Abd Rashid, R., and Azizul, M. A. (2021). A review of aerodynamics influence on various car model geometry through cfd techniques. Journal of Advanced Research in Fluid Mechanics and Thermal Sciences, 88(1):109–125.
Kim, Y.-c. and Ahn, C. (2010). Development of hybrid anti-submarine weapon training simulator using component-based development methodology. SISO.
Lin, Z., Feng, S., and Ying, L. (1998). The design of a submarine voyage training simulator. In SMC’98 Conference Proceedings. 1998 IEEE International Conference on Systems, Man, and Cybernetics (Cat. No. 98CH36218), volume 4, pages 3720–3724. IEEE.
Mentzelopoulos, M., Tanasa, M., Protopsaltis, A., and Economou, D. (2011). Explosive ordinance disposal: motion sensor simulator in nintendo wii. In Proceedings of the 29th ACM international conference on Design of communication, pages 227–234.
Milne-Thomson, L. M. (1973). Theoretical aerodynamics. Courier Corporation.
Mohapatra, S. and Kanungo, P. (2012). Performance analysis of aodv, dsr, olsr and dsdv routing protocols using ns2 simulator. Procedia Engineering, 30:69–76.
Moorthy, K., Vincent, C., and Darzi, A. (2005). Simulation based training.
Nan, Q. and Liang, M. (2018). Subsafe–a game-based training system for submarine safety. In 2018 Joint International Advanced Engineering and Technology Research Conference (JIAET 2018), pages 161–166. Atlantis Press.
Pereira, R., Couto, M., Ribeiro, F., Rua, R., Cunha, J., Fernandes, J. P., and Saraiva, J. (2017). Energy efficiency across programming languages: how do energy, time, and memory relate? In Proceedings of the 10th ACM SIGPLAN International Conference on Software Language Engineering, pages 256–267.
SENAI (2022). Firjan senai vai desenvolver simuladores para o exército, fortalecendo a base industrial de defesa do brasil. Last accessed 30 december 2022.
Shannon, R. E. (1992). Introduction to simulation. In Proceedings of the 24th conference on Winter simulation, pages 65–73.
Zheng, S., Huang, Q., Jin, J., and Han, J. (2009). Flight simulator architecture development and implementation. In 2009 International Conference on Measuring Technology and Mechatronics Automation, volume 2, pages 230–233. IEEE.
Publicado
21/07/2024
Como Citar
SANTOS, Lucas S. dos; MARIA, Luiz C. G.; M. JUNIOR, Erisvaldo F.; MACHADO, Raphael C. S..
Hybrid Simulation Framework: Advanced and Secure Training. In: SEMINÁRIO INTEGRADO DE SOFTWARE E HARDWARE (SEMISH), 51. , 2024, Brasília/DF.
Anais [...].
Porto Alegre: Sociedade Brasileira de Computação,
2024
.
p. 13-24.
ISSN 2595-6205.
DOI: https://doi.org/10.5753/semish.2024.1801.
