The limits of falsifiability: Dimensionality, measurement thresholds, and the sub-Landauer domain in biological systems

IF 1.9 4区生物学 Q2 BIOLOGY

Biosystems Pub Date : 2025-10-11 DOI:10.1016/j.biosystems.2025.105608

Ian Todd

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引用次数: 0

Abstract

Karl Popper’s falsifiability criterion assumes that scientific hypotheses can be reduced to binary tests. We show this assumption is scale-dependent and can saturate in high-dimensional biological systems operating near physical measurement limits, especially near criticality. In neural networks, much relevant information exists as patterns below the Landauer threshold for irreversible bit recording—signals too weak for individual neurons to detect but detectable when pooled across populations. These sub-threshold patterns cannot be projected into binary outcomes without destroying their causal structure. We develop a framework connecting dimensionality, thermodynamic measurement limits, and biological epistemology, showing that Popperian logic represents a special case applicable only to low-dimensional systems with strong signals. Our analysis has implications for neuroscience, where aspects of conscious processing may in part depend on sub-threshold coherence patterns that resist binary measurement, motivating a shift from single-case hypothesis tests to multi-scale, ensemble-based inference. The framework extends to other complex biological systems including ecological networks, protein folding dynamics, and evolutionary processes where causal relationships exist as irreducible multi-dimensional structures operating below classical measurement thresholds.

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可证伪性的极限：维度、测量阈值和生物系统中的亚朗道尔域。

卡尔·波普尔的可证伪性准则假定科学假设可以简化为二元检验。我们表明这种假设是尺度相关的，并且可以在接近物理测量极限的高维生物系统中饱和，特别是接近临界。在神经网络中，许多相关信息以低于不可逆比特记录的兰道尔阈值的模式存在，这些信号对于单个神经元来说太弱而无法检测到，但当它们汇集在一起时却可以检测到。这些亚阈值模式不能在不破坏其因果结构的情况下投射到二元结果中。我们开发了一个连接维度、热力学测量极限和生物认识论的框架，表明波普尔逻辑代表一种特殊情况，仅适用于具有强信号的低维系统。我们的分析对神经科学具有启示意义，在神经科学中，意识处理的各个方面可能部分依赖于抵制二元测量的亚阈值相干模式，从而促使从单例假设检验转向多尺度、基于集合的推理。该框架扩展到其他复杂的生物系统，包括生态网络、蛋白质折叠动力学和进化过程，其中因果关系作为不可约的多维结构存在，运行在经典的测量阈值以下。

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

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.