Co-design of control and platform with dropped signals

Author(s)

Soudbakhsh, Damoon; Phan, Linh T. X.; Sokolsky, Oleg; Lee, Insup; Annaswamy, Anuradha M.

Abstract

This paper examines a co-design of control and platform in the presence of dropped signals. In a cyber-physical system, due to increasing complexities such as the simultaneous control of several applications, limited resources, and complex platform architectures, some of the signals transmitted may often be dropped. In this paper, we address the challenges that arise both from the control design and the platform design point of view. A dynamic model is proposed that accommodates these drops, and a suitable switching control design is proposed. A Multiple Lyapunov functions based approach is used to guarantee the stability of the system with the switching controller. We then present a method for optimizing the amount of platform resource required to ensure stability of the control systems via a buffer control mechanism that exploits the ability to drop signals of the control system and an associated analysis of the drop bound. The results are demonstrated using a case study of a co-designed lane keeping control system in the presence of dropped signals.

Date issued

2013

URI

http://hdl.handle.net/1721.1/86938

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

Proceedings of the ACM/IEEE 4th International Conference on Cyber-Physical Systems - ICCPS '13

Publisher

Association for Computing Machinery

Citation

Soudbakhsh, Damoon, Linh T. X. Phan, Oleg Sokolsky, Insup Lee, and Anuradha Annaswamy. “Co-Design of Control and Platform with Dropped Signals.” Proceedings of the ACM/IEEE 4th International Conference on Cyber-Physical Systems - ICCPS’13 (2013), April 8-11, 2013, Philadelphia, PA, USA.

Version: Author's final manuscript

ISBN

9781450319966