Proceedings of ICIUS

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Development of autonomous system like unmanned vehicle is easy to be costly because of its difficulty during the test process. To reduce that inefficiency, it is common to use the Hardware-In-the-Loop Simulation (HILS). The HILS is simulation environment that consist of the control system running actually and the simulator. Further, there are not only many researches of the the the single vehicle system but also multi vehicle system interacting with other systems. Verifying and testing those highly sophisticated systems is harder and cost higher than single system. Thus the need of the HILS is required. However, there are many issues about real time guarantee in the HILS system and these issues should be properly satisfied. Unfortunately, designing real time system is hard and requires high cost, and this makes the development of the system harder. To improve this low productivity, an architecture of TMO based HILS system was previously presented. TMO (time-triggered message-triggered object) model is a real-time object model for distributed and timeliness-guaranteed computing. The previous model addressed the problems about the real time issues gracefully using real time middleware named TMOSM. In this paper, improving previous architecture, we present architecture of the multi HILS system to provide multi simulation environment. In the multi HILS, it is not only important to guarantee the real time of each HILS system but also synchronize data between multi HILS systems in time. The presented multi HILS based on the TMO has hardware platform and software design for simulation engine, collision detection and virtual environment. The multi HILS system is structurally more complex than single HILS system. Nevertheless, applying the TMO scheme to design of the multi HILS, both of real time guaranteeing and expandability can gracefully satisfied.

Marco A. A. Sanvido and Walter Schaufelberger. Design of a framework for Hardware-In-The-Loop Simulations

Dongwan Jung and Panagiotis Tsiotras. Modeling and Hardware-In-The-Loop Simulation for a Small Unmanned Aerial Vehicle

Dongwon Jung, Jayant Ratti and Panagiotis Tsiotras. Real-time Implementation and Validation of a New Hierarchical Path Planning Scheme of UAVs via Hardware-in-the-loop Simulation.

Shixianjun, Song jiakun and Liu hongxing. Hardware-in-the-loop Simulation Framework Design for a UAV Embedded Control System.

Stefan E. Slagowski and Justin E. Vican. A Hardware-In-The-Loop Simulator for Software Development for a Mars Airplane.

Peter M. Visser, Marcel A. Groothuis and Jan F. Broenink. Multi-Disciplinary Design Support using Hardware-In-The-Loop Simulation.

kresimir Cosic, Ivica Kopriva, Todor Kostic, Miroslav Slamic and Marijo Volarevic. A Multi-Level Hardware-In-The-Loop Simulation.

Ali Haydar Goktogan and Salah Sukkarieh. Simulation of Multi-UAV Missions in a Real-Time Distributed Hardware-In-The-Loop Simulator.

Wook Hyun Kown and Seong-Gyu Coi. Real-Time Distributed Software-In-The-Loop Simulation for Distributed Control System.

Ali Haydar Goktogan and Salah Sukkarieh. Distributed Simulation and Middleware for Networked UAS.

T. Jogn Koo, Judith Liebman, Cedric Ma, Benjamin Horowitz, Alberto Sangiovanni-Vincentelli and Shankar Sastry. Platform-Based Embedded Software Design for Multi-Vehicle Multi-Modal Systems

K.H. Kim. Real-Time Object-Oriented Distributed Software Engineering and The TMO Scheme

K.H. Kim. Object-Oriented Real-Time Distributed Programming and Support Middleware

K.H. Kim, Yuqing Li, Sheng Liu, Moon H. Kim and Doo-Hyun Kim. RMMC Programming Model and Support Execution Engine in the TMO Programming Scheme.

Jingyu Xu, Hansol Park, Karpjoo Jeong and Chun-Hyon Chang. TMO-HILS Architecture for Real-Time Control System

K.H. Kim. Real-Time Simulation Techniques Based on the RTO.k object Modeling

K.H. Kim. Object Structures for Real-Time Systems and Simulators.

Jan O. Biermeyer, Vason P. Srini and Bernd Kleinjohann. Distributed Real-time Computing in Autonomous Robots using TMOs.

Doo-Hyun Kim and K.H. Kim. A TMO-Based Software Architecture for Distributed Real-Time Multimedia Processing.

Doo-Hyun Kim, Moon-Hae Kim and Seok-Phil Lee. Distributed Computing Based Streaming and Play of Music Ensemble Realized Through TMO Programming.