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  1. Strong Emergence in Biological Systems: Is It Open to Mathematical Reasoning?Lars H. Wegner, Min Yu, Biao Wu, Jiayou Liu & Zhifeng Hao - 2021 - Acta Biotheoretica 69 (4):841-856.
    Complex, multigenic biological traits are shaped by the emergent interaction of proteins being the main functional units at the molecular scale. Based on a phenomenological approach, algorithms for quantifying two different aspects of emergence were introduced (Wegner and Hao in Progr Biophys Mol Biol 161:54–61, 2021) describing: (i) pairwise reciprocal interactions of proteins mutually modifying their contribution to a complex trait (denoted as weak emergence), and (ii) formation of a new, complex trait by a set of n ‘constitutive’ proteins at (...)
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  • Self-Organization, Emergence, and Constraint in Complex Natural Systems.Jon Lawhead - manuscript
    Contemporary complexity theory has been instrumental in providing novel rigorous definitions for some classic philosophical concepts, including emergence. In an attempt to provide an account of emergence that is consistent with complexity and dynamical systems theory, several authors have turned to the notion of constraints on state transitions. Drawing on complexity theory directly, this paper builds on those accounts, further developing the constraint-based interpretation of emergence and arguing that such accounts recover many of the features of more traditional accounts. We (...)
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  • Lightning in a Bottle: Complexity, Chaos, and Computation in Climate Science.Jon Lawhead - 2014 - Dissertation, Columbia University
    Climatology is a paradigmatic complex systems science. Understanding the global climate involves tackling problems in physics, chemistry, economics, and many other disciplines. I argue that complex systems like the global climate are characterized by certain dynamical features that explain how those systems change over time. A complex system's dynamics are shaped by the interaction of many different components operating at many different temporal and spatial scales. Examining the multidisciplinary and holistic methods of climatology can help us better understand the nature (...)
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  • Complexity and information: Measuring emergence, self‐organization, and homeostasis at multiple scales.Carlos Gershenson & Nelson Fernández - 2013 - Complexity 18 (2):29-44.
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  • From big data to important information.Yaneer Bar-Yam - 2016 - Complexity 21 (S2):73-98.
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  • The sigma profile: A formal tool to study organization and its evolution at multiple scales.Carlos Gershenson - 2011 - Complexity 16 (5):37-44.
    The σ profile is presented as a tool to analyze the organization of systems at different scales, and how this organization changes in time. Describing structures at different scales as goal‐oriented agents, one can define σ ∈ [0,1] (satisfaction) as the degree to which the goals of each agent at each scale have been met. σ reflects the organization degree at that scale. The σ profile of a system shows the satisfaction at different scales, with the possibility to study their (...)
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  • On optimal modularity for system construction.Mahmoud Efatmaneshnik & Michael J. Ryan - 2016 - Complexity 21 (5):176-189.
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  • A mathematical theory of strong emergence using multiscale variety.Yaneer Bar-Yam - 2004 - Complexity 9 (6):15-24.
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  • Modeling Urban Growth and Form with Spatial Entropy.Yanguang Chen - 2020 - Complexity 2020:1-14.
    Entropy is one of the physical bases for the fractal dimension definition, and the generalized fractal dimension was defined by Renyi entropy. Using the fractal dimension, we can describe urban growth and form and characterize spatial complexity. A number of fractal models and measurements have been proposed for urban studies. However, the precondition for fractal dimension application is to find scaling relations in cities. In the absence of the scaling property, we can make use of the entropy function and measurements. (...)
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  • Harnessing the complexity of education with information technology.Carlos Gershenson - 2015 - Complexity 20 (5):13-16.
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  • Computationally tractable pairwise complexity profile.Yaneer Bar‐Yam & Dion Harmon - 2013 - Complexity 18 (5):20-27.
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