Prokaryotic Bio-Inspired Model for Embryonics

2009 NASA/ESA Conference on Adaptive Hardware and Systems Pub Date : 2009-07-29 DOI:10.1109/AHS.2009.45
M. Samie, G. Dragffy, A. Popescu, A. Pipe, C. Melhuish
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引用次数: 37

Abstract

This paper is presented in conjunction with, and forms the first part of, the paper entitled “Prokaryotic Bio-Inspired Systems.” In this part we propose and investigate a novel prokaryotic cell-based bio-inspired model suitable to implement self-healing bio-inspired systems. A key feature of our model is that system reliability can be increased with a minimal amount of hardware overhead. It also offers a bio-inspired compression/decompression technique that exploits the intimate relationship between different genes. Distributed DNA, highly dynamic and flexible routing resources and optimized self-repair characteristics (using Block and cell elimination) are some of the other advantages of the proposed model.
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原核生物启发的胚胎学模型
本文与题为“原核生物启发系统”的论文一起提出,并构成了该论文的第一部分。在这一部分中,我们提出并研究了一种新的基于原核细胞的仿生模型,适合于实现自修复的仿生系统。我们模型的一个关键特征是,系统可靠性可以通过最小的硬件开销来提高。它还提供了一种生物启发的压缩/减压技术,利用不同基因之间的亲密关系。分布式DNA、高度动态和灵活的路由资源以及优化的自我修复特性(使用块和细胞消除)是该模型的其他一些优点。
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2009 NASA/ESA Conference on Adaptive Hardware and Systems
2009 NASA/ESA Conference on Adaptive Hardware and Systems
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