Emergence and Criticality in Spatiotemporal Synchronization: The Complementarity Model.

IF 1.6 4区 计算机科学 Q4 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Alessandro Scirè
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引用次数: 0

Abstract

This work concerns the long-term collective excitability properties and the statistical analysis of the critical events displayed by a recently introduced spatiotemporal many-body model, proposed as a new paradigm for Artificial Life. Numerical simulations show that excitable collective structures emerge in the form of dynamic networks, created by bursts of spatiotemporal activity (avalanches) at the edge of a synchronization phase transition. The spatiotemporal dynamics is portraited by a movie and quantified by time varying collective parameters, showing that the dynamic networks undergo a "life cycle," made of self-creation, homeostasis, and self-destruction. The power spectra of the collective parameters show 1/f power law tails. The statistical properties of the avalanches, evaluated in terms of size and duration, show power laws with characteristic exponents in agreement with those values experimentally found in the neural networks literature. The mechanism underlying avalanches is argued in terms of local-to-collective excitability. The connections that link the present work to self-organized criticality, neural networks, and Artificial Life are discussed.

时空同步中的新兴性和临界性:互补模型。
这项工作涉及长期集体兴奋特性以及对最近引入的时空多体模型所显示的临界事件的统计分析,该模型被提出作为人工生命的新范例。数值模拟显示,可兴奋的集体结构以动态网络的形式出现,由同步相变边缘的时空活动爆发(雪崩)产生。影片描绘了时空动态,并通过时变集体参数进行量化,显示动态网络经历了自我创建、平衡和自我毁灭的 "生命周期"。集合参数的功率谱显示出 1/f 的幂律尾巴。根据规模和持续时间评估的雪崩统计特性显示,幂律的特征指数与神经网络文献中的实验值一致。从局部到集体的兴奋性角度论证了雪崩的内在机制。讨论了本研究与自组织临界、神经网络和人工生命之间的联系。
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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来源期刊
Artificial Life
Artificial Life 工程技术-计算机:理论方法
CiteScore
4.70
自引率
7.70%
发文量
38
审稿时长
>12 weeks
期刊介绍: Artificial Life, launched in the fall of 1993, has become the unifying forum for the exchange of scientific information on the study of artificial systems that exhibit the behavioral characteristics of natural living systems, through the synthesis or simulation using computational (software), robotic (hardware), and/or physicochemical (wetware) means. Each issue features cutting-edge research on artificial life that advances the state-of-the-art of our knowledge about various aspects of living systems such as: Artificial chemistry and the origins of life Self-assembly, growth, and development Self-replication and self-repair Systems and synthetic biology Perception, cognition, and behavior Embodiment and enactivism Collective behaviors of swarms Evolutionary and ecological dynamics Open-endedness and creativity Social organization and cultural evolution Societal and technological implications Philosophy and aesthetics Applications to biology, medicine, business, education, or entertainment.
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