自然界中的软件:复杂多级系统中出现的计算方法

Fernando E. Rosas, Bernhard C. Geiger, Andrea I Luppi, Anil K. Seth, Daniel Polani, Michael Gastpar, Pedro A. M. Mediano
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引用次数: 0

摘要

了解复杂系统的功能结构,对于揭示其内部运作,并为其预测和控制提供有效方法至关重要。最近的研究进展引入了一些工具来描述宏观层面的涌现;然而,虽然这些方法成功地识别了涌现发生的时间,但它们在决定涌现如何发生的程度上是有限的。在这里,我们通过开发一种计算方法来解决这一局限性,这种方法从计算能力的角度来描述宏观过程。具体来说,我们根据软件的工作原理阐述了一种关于涌现的观点,这种观点植根于数学形式主义,阐明了宏观过程如何能够表达自足的信息、干预和计算特性。这一框架建立了嵌套自足过程的层次结构,它决定了在哪个层次上进行哪些计算,进而勾勒出复杂系统的功能架构。统计物理学和计算神经科学文献中的范例模型对这种方法进行了说明,这些模型展示了类似于人类工程系统软件的宏观过程。总之,这个框架能让我们更深入地理解复杂系统的多层次结构,揭示出高效模拟、预测和控制复杂系统的具体方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Software in the natural world: A computational approach to emergence in complex multi-level systems
Understanding the functional architecture of complex systems is crucial to illuminate their inner workings and enable effective methods for their prediction and control. Recent advances have introduced tools to characterise emergent macroscopic levels; however, while these approaches are successful in identifying when emergence takes place, they are limited in the extent they can determine how it does. Here we address this limitation by developing a computational approach to emergence, which characterises macroscopic processes in terms of their computational capabilities. Concretely, we articulate a view on emergence based on how software works, which is rooted on a mathematical formalism that articulates how macroscopic processes can express self-contained informational, interventional, and computational properties. This framework establishes a hierarchy of nested self-contained processes that determines what computations take place at what level, which in turn delineates the functional architecture of a complex system. This approach is illustrated on paradigmatic models from the statistical physics and computational neuroscience literature, which are shown to exhibit macroscopic processes that are akin to software in human-engineered systems. Overall, this framework enables a deeper understanding of the multi-level structure of complex systems, revealing specific ways in which they can be efficiently simulated, predicted, and controlled.
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