Evolutionary emergence of biological intelligence

arXiv - QuanBio - Populations and Evolution Pub Date : 2024-09-07 DOI:arxiv-2409.04928

Takuya Isomura

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Abstract

Characterising the intelligence of biological organisms is challenging. This work considers intelligent algorithms developed evolutionarily within neural systems. Mathematical analyses unveil a natural equivalence between canonical neural networks, variational Bayesian inference under a class of partially observable Markov decision processes, and differentiable Turing machines, by showing that they minimise the shared Helmholtz energy. Consequently, canonical neural networks can biologically plausibly equip Turing machines and conduct variational Bayesian inferences of external Turing machines in the environment. Applying Helmholtz energy minimisation at the species level facilitates deriving active Bayesian model selection inherent in natural selection, resulting in the emergence of adaptive algorithms. In particular, canonical neural networks with two mental actions can separately learn transition mappings of multiple Turing machines. These propositions were corroborated by numerical simulations of algorithm implementation and neural network evolution. These notions offer a universal characterisation of biological intelligence emerging from evolution in terms of Bayesian model selection and belief updating.

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生物智能的进化

描述生物有机体的智能具有挑战性。本研究考虑了在神经系统内进化发展的智能算法。数学分析揭示了典型神经网络、一类部分可观测的马尔可夫决策过程下的变分贝叶斯推理和可微分图灵机之间的自然等价关系，表明它们能使共享的亥姆霍兹能量最小化。因此，典型神经网络可以在生物学上合理地装备图灵机，并对环境中的外部图灵机进行变量贝叶斯推断。在物种水平上应用亥姆霍兹能量最小化，有助于实现自然选择中固有的主动贝叶斯模型选择，从而产生自适应算法。特别是，具有两种心理行为的典型神经网络可以分别学习多个图灵机的过渡映射。这些概念从贝叶斯模型选择和信念更新的角度为生物智能的进化提供了普遍的特征。

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arXiv - QuanBio - Populations and Evolution

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