Hierarchical Approach for Design of Multi-vehicle Multi-modal Embedded Software

Koo, T. John; Liebman, Judith S.; Ma, Cedric; Sastry, S. Shankar

doi:10.1007/3-540-45449-7_24

Cited by 5 publications

(2 citation statements)

References 33 publications

(41 reference statements)

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“…It has been used in the formal design of distributed embedded control systems [85]. Other embedded applications are the design for flying autonomous multivehicle control [86] and high-energy particle physics data acquisition systems [87]. Lastly, it is used in the design of industrial intelligent manufacturing systems of distributed robotic manufacturing [88].…”

Section: Cell Nucleusmentioning

confidence: 99%

Survey of Engineering Models for Systems Biology

Reeves

Hrischuk²

2016

Computational Biology Journal

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In recent years, the field of systems biology has emerged from a confluence of an increase both in molecular biotechnology and in computing storage and power. As a discipline, systems biology shares many characteristics with engineering. However, before the benefits of engineering-based modeling formalisms and analysis tools can be applied to systems biology, the engineering discipline(s) most related to systems biology must be identified. In this paper, we identify the cell as an embedded computing system and, as such, demonstrate that systems biology shares many aspects in common with computer systems engineering, electrical engineering, and chemical engineering. This realization solidifies the grounds for using modeling formalisms from these engineering subdisciplines to be applied to biological systems. While we document several examples where this is already happening, our goal is that identifying the cell as an embedded computing system would motivate and facilitate further discovery through more widespread use of the modeling formalisms described here.

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Section: Cell Nucleusmentioning

confidence: 99%

Survey of Engineering Models for Systems Biology

Reeves

Hrischuk²

2016

Computational Biology Journal

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“…Enabling the design of such systems in easily understandable forms that are amenable to rigorous analysis is a highly desirable goal. [5,6,8,10] The TMO (Time-triggered Message-triggered Object) model formalized earlier by Kim and his collaborators [1,2] has been found to be a sound real-time object model that can be used for various types of hard and soft real-time distributed computing applications. With the TMO model, both functional and timing behaviors of a system can be specified in explicit and natural easy-to-understand forms.…”

Section: Introductionmentioning

confidence: 99%

Design and Experimental Validation of UAV Control System Software Based on the TMO Structuring Scheme

Park

Kim

Chang

et al. 2007

Software Technologies for Embedded and Ubiquitous Systems

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Abstract. The technologies for designing and validating computer-control systems subject to challenging timing and reliability requirements have been advancing slowly. One such type of systems are unmanned aerial vehicle (UAV) control systems. The functional complexity of UAV control systems is steadily increasing. Enabling the design of such complex systems in easily understandable forms that are amenable to rigorous analysis is a highly desirable goal. In this paper, we discuss our experimental application of the Time-triggered Message-triggered Object (TMO) structuring scheme to the design of a UAV control system. The TMO scheme enables high-level structuring together with design-time guaranteeing of accurate timings of various critical control actions with significantly smaller efforts than those required when using lower-level structuring schemes based on direct programming of threads, UDP invocations, etc. An experimental 2-step validation of a UAV control system is also discussed. The first step was to validate the system by use of an environment simulator and then real flight tests were involved only in the second step.

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Multimodal Control of Constrained Nonlinear Systems

Samad

Balas

2003

Software‐Enabled Control

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Hierarchical Approach for Design of Multi-vehicle Multi-modal Embedded Software

Cited by 5 publications

References 33 publications

Survey of Engineering Models for Systems Biology

Survey of Engineering Models for Systems Biology

Design and Experimental Validation of UAV Control System Software Based on the TMO Structuring Scheme

Multimodal Control of Constrained Nonlinear Systems

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