A Methodology for the Use of the Teleo-Reactive Programming Technique in Autonomic Computing

The materials on the development of asynchronous electric drive with scalar control are given. The technical solutions associated with the design of software and hardware parts of the microprocessor control system are described. When developed, tools of model-based programming technique are used.

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The Effect of Using Linear Programming Technique of Programmed Instruction in Learning and Improving the Performance of some Sprints (running) of the Deaf and Dumb

10.36295/asro.2020.231344 ◽

2020 ◽

Vol 23 (13) ◽

Author(s):

Dr. Sanaa Jawad Kadhim Almayah

Keyword(s):

Linear Programming ◽

Programmed Instruction ◽

Programming Technique ◽

Linear Programming Technique

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Application of Stochastic Programming Technique to Solve Interval Quadratic Programming Problem

International Journal of Applied and Computational Mathematics ◽

10.1007/s40819-020-00947-7 ◽

2021 ◽

Vol 7 (1) ◽

Author(s):

Shaveta Kumari ◽

Saurabh Srivastava

Keyword(s):

Stochastic Programming ◽

Quadratic Programming ◽

Programming Problem ◽

Quadratic Programming Problem ◽

Programming Technique ◽

Interval Quadratic Programming

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A Programming Approach to Collective Autonomy

Journal of Sensor and Actuator Networks ◽

10.3390/jsan10020027 ◽

2021 ◽

Vol 10 (2) ◽

pp. 27

Author(s):

Roberto Casadei ◽

Gianluca Aguzzi ◽

Mirko Viroli

Keyword(s):

Autonomous Vehicles ◽

Autonomic Computing ◽

Autonomous Agents ◽

Programming Approach ◽

Multi Agent Systems ◽

Agent Systems ◽

Multi Agent ◽

Simulated Case ◽

Complex Settings

Research and technology developments on autonomous agents and autonomic computing promote a vision of artificial systems that are able to resiliently manage themselves and autonomously deal with issues at runtime in dynamic environments. Indeed, autonomy can be leveraged to unburden humans from mundane tasks (cf. driving and autonomous vehicles), from the risk of operating in unknown or perilous environments (cf. rescue scenarios), or to support timely decision-making in complex settings (cf. data-centre operations). Beyond the results that individual autonomous agents can carry out, a further opportunity lies in the collaboration of multiple agents or robots. Emerging macro-paradigms provide an approach to programming whole collectives towards global goals. Aggregate computing is one such paradigm, formally grounded in a calculus of computational fields enabling functional composition of collective behaviours that could be proved, under certain technical conditions, to be self-stabilising. In this work, we address the concept of collective autonomy, i.e., the form of autonomy that applies at the level of a group of individuals. As a contribution, we define an agent control architecture for aggregate multi-agent systems, discuss how the aggregate computing framework relates to both individual and collective autonomy, and show how it can be used to program collective autonomous behaviour. We exemplify the concepts through a simulated case study, and outline a research roadmap towards reliable aggregate autonomy.

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