Towards Large-Scale Simulations of Open-Ended Evolution in Continuous Cellular Automata

arXiv - PHYS - Cellular Automata and Lattice Gases Pub Date : 2023-04-12 DOI:arxiv-2304.05639

Bert Wang-Chak Chan

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Abstract

Inspired by biological and cultural evolution, there have been many attempts to explore and elucidate the necessary conditions for open-endedness in artificial intelligence and artificial life. Using a continuous cellular automata called Lenia as the base system, we built large-scale evolutionary simulations using parallel computing framework JAX, in order to achieve the goal of never-ending evolution of self-organizing patterns. We report a number of system design choices, including (1) implicit implementation of genetic operators, such as reproduction by pattern self-replication, and selection by differential existential success; (2) localization of genetic information; and (3) algorithms for dynamically maintenance of the localized genotypes and translation to phenotypes. Simulation results tend to go through a phase of diversity and creativity, gradually converge to domination by fast expanding patterns, presumably a optimal solution under the current design. Based on our experimentation, we propose several factors that may further facilitate open-ended evolution, such as virtual environment design, mass conservation, and energy constraints.

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面向连续元胞自动机开放式进化的大规模模拟

受生物和文化进化的启发，已经有许多尝试去探索和阐明开放性人工智能和人工生命的必要条件。以连续元胞自动机Lenia为基础系统，利用并行计算框架JAX构建大规模进化模拟，以实现自组织模式永无止境进化的目标。我们报告了一些系统设计选择，包括:(1)遗传算子的隐式实现，例如通过模式自我复制进行繁殖，以及通过差异存在成功进行选择;(2)遗传信息的定位;(3)定位基因型的动态维护和向表型的翻译算法。仿真结果往往会经历一个多样性和创造性的阶段，逐渐收敛到被快速扩展的模式所支配，可能是当前设计下的最优解。基于我们的实验，我们提出了几个可能进一步促进开放式进化的因素，如虚拟环境设计、质量守恒和能量约束。

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arXiv - PHYS - Cellular Automata and Lattice Gases

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