Fundamentals of Holonic Systems and Their Implications for Self-Adaptive and Self-Organizing Systems

2008 Second IEEE International Conference on Self-Adaptive and Self-Organizing Systems Workshops Pub Date : 2008-10-20 DOI:10.1109/SASOW.2008.29

P. Valckenaers, H. Brussel, T. Holvoet

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引用次数: 21

Abstract

Holonic systems originate from Simon's research on the Sciences of the Artificial [4]. In a demanding and dynamic environment, all non-trivial systems must posses a holonic (pyramidal) structure to adapt swiftly while the information processing capacity is bounded. This paper discusses the implications of the manner in which holonic systems emerge, adapt and survive on the design of self-adaptive and self-organizing systems. First, self-adaptive and self-organizing holons must be resilient against the dynamics of their surroundings, deliver services within the setting of their surrounding super-holon(s), and shield neighboring holons from dynamics that those neighbors cannot digest. This paper discusses a holonic design illustrating this. Second, a holonic system design must balance self-*elements with more conventional elements. Indeed, the more efficient conventional elements increase the adaptation speed. This paper discusses how self adaptive and self-organizing holons can be combined with other holons without forfeiting the qualities of these self-* elements (operating range, low-and-late commitment).

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全息系统的基本原理及其对自适应和自组织系统的影响

全息系统起源于西蒙对人工真空科学的研究。在苛刻的动态环境中，所有非平凡系统都必须具有整体(金字塔)结构，以便在信息处理能力有限的情况下快速适应。本文讨论了整体系统的产生、适应和生存方式对自适应和自组织系统设计的影响。首先，自适应和自组织的黑洞必须对周围环境的动态具有弹性，在周围超级黑洞的设置内提供服务，并保护相邻的黑洞免受无法消化的动态的影响。本文讨论了一个全息设计来说明这一点。第二，一个全息系统的设计必须平衡自我元素和更多的传统元素。事实上，效率更高的常规元素提高了适应速度。本文讨论了如何在不丧失这些自要素(工作范围、低承诺和晚承诺)的情况下，将自适应和自组织的全息与其他全息组合在一起。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2008 Second IEEE International Conference on Self-Adaptive and Self-Organizing Systems Workshops

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