聚集 Boid 行为,帮助人工自生组织。

IF 2 4区 生物学 Q2 BIOLOGY
Steven Lawrence, Chrystopher L. Nehaniv
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引用次数: 0

摘要

对地球上的碳基生命进行分析,可能会导致对宇宙其他地方可能存在的其他形式的生命本质做出有失偏颇的推断,因此,科学家们要么将生命抽象为由其组成的系统,要么将其抽象为生命逻辑,要么将其抽象为基本标准清单,要么将其抽象为描述生命特征的基本动态模式。自生(autopoiesis)(瓦雷拉等人,1974 年)是一个系统层面的特征,也被称为最小生命的一般模式,包括生产、维护和替换所需的成分,以建立和维持一个自我/他体分离的内部环境,该环境调节并构成生产环境的过程,以及构成这一持续的自我生产活动的过程的成分,即以一种允许组织模式不断重组自身永续所需的条件、成分和过程的方式。这一开创性的 "自生 "概念在我们所知的生命中得到了体现,但也可能以不同的媒介和不可预见的方式得到体现。其他研究人员则认为,生命不仅仅是自生过程,它是自生过程和认知的共同生成属性。生命产生了许多新出现的特性,例如同步和模式,这在不同动物物种的成群结队中可以看到。克雷格-雷诺兹(Craig Reynolds)将成群结队的动物所表现出的这种同步性的机理提取为一个生成模型,称为 "Boids"。基于这些概念,我们提出了以下研究问题:Boids 的同步操作和聚合行为如何为实现自造血系统的构成子系统做出贡献?这样的系统能否表现出最低限度的认知?这项研究试图用一种自下而上的方法来构建人工生命系统,从而回答这些问题。我们展示了一个自生的计算模型,以及 M. Bitbol 和 P. Luigi Luisi 意义上的最低认知水平,即自生实体在自我生产活动中主动吸收外部成分。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Aggregate Boid behavior to aid in artificial autopoietic organization

Analyzing carbon-based life on earth can lead to biased inferences on the nature of life as might exist in elsewhere in the universe in alternative forms, therefore, scientists have looked into either abstracting life into constituent systems it is comprised of, or logics of life, or lists of essential criteria, or essential dynamic patterning that characterizes the living. A system-level characterization that is and referred to as a general pattern of minimal life is autopoiesis (Varela et al., 1974) including production, maintenance and replacement of required constituents for setting up and maintaining an internal environment with self/other separation that regulates and is constitutive of processes that produce the environment and components for processes that comprise this ongoing activity of self-production in ‘recursively’, i.e., in a manner that allows the organizational pattern to continually reconstitute the conditions, components and processes required for its own perpetuation. This seminal concept of an autopoiesis is instantiated in life as we know it, but might also be instantiated in different media and in unforeseen ways. Other researchers have argued life is more than autopoiesis and that it is a co-emergent property of autopoiesis and cognition. Life produces many emergent properties such as synchronization and patterns as seen in flocks and herds of different animal species. The mechanics of this synchrony displayed in flocks and herd animals has been extracted by Craig Reynolds into a generative model referred to as “Boids”. With these concepts in mind, we address the following research question: How can the synchronous maneuvers and aggregate behavior of Boids contribute to constitutive subsystems in realizing an autopoietic system? Can such a system exhibit minimal cognition? This work attempts to answer these questions with a bottom-up approach to constructing an artificial life system. We exhibit a computational model of autopoiesis and a minimal level of cognition in the sense of M. Bitbol and P. Luigi Luisi, whereby an autopoietic entity engages in active assimilation of external components as part of its activity of self-production.

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来源期刊
Biosystems
Biosystems 生物-生物学
CiteScore
3.70
自引率
18.80%
发文量
129
审稿时长
34 days
期刊介绍: BioSystems encourages experimental, computational, and theoretical articles that link biology, evolutionary thinking, and the information processing sciences. The link areas form a circle that encompasses the fundamental nature of biological information processing, computational modeling of complex biological systems, evolutionary models of computation, the application of biological principles to the design of novel computing systems, and the use of biomolecular materials to synthesize artificial systems that capture essential principles of natural biological information processing.
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