当前共找到 1 篇文献分享。
1.
张德祥 (2022-06-22 19:35):
#paper https://doi.org/10.1016/j.pbiomolbio.2022.05.006 A free energy principle for generic quantum systems 自由能作为一个无尺度的概念框架,这篇论文讲FEP的适用范围扩展到了一般的量子系统,论文表明量子生物的领域比现在了解的要大的多。预测分子级别的动力学实现了量子信息处理。技术细节没有基础,个人感觉难度比较大,欢迎朋友一起研读。
Abstract:
The Free Energy Principle (FEP) states that under suitable conditions of weak coupling, random dynamical systems with sufficient degrees of freedom will behave so as to minimize an upper bound, … >>>
The Free Energy Principle (FEP) states that under suitable conditions of weak coupling, random dynamical systems with sufficient degrees of freedom will behave so as to minimize an upper bound, formalized as a variational free energy, on surprisal (a.k.a., self-information). This upper bound can be read as a Bayesian prediction error. Equivalently, its negative is a lower bound on Bayesian model evidence (a.k.a., marginal likelihood). In short, certain random dynamical systems evince a kind of self-evidencing. Here, we reformulate the FEP in the formal setting of spacetime-background free, scale-free quantum information theory. We show how generic quantum systems can be regarded as observers, which with the standard freedom of choice assumption become agents capable of assigning semantics to observational outcomes. We show how such agents minimize Bayesian prediction error in environments characterized by uncertainty, insufficient learning, and quantum contextuality. We show that in its quantum-theoretic formulation, the FEP is asymptotically equivalent to the Principle of Unitarity. Based on these results, we suggest that biological systems employ quantum coherence as a computational resource and - implicitly - as a communication resource. We summarize a number of problems for future research, particularly involving the resources required for classical communication and for detecting and responding to quantum context switches. <<<
翻译
回到顶部