We apply a new method for learning equations from data -- Exhaustive Symbolic Regression (ESR) -- to late-type galaxy dynamics as encapsulated in the radial acceleration relation (RAR). Relating the centripetal acceleration due to baryons, $g_\text{bar}$, to the total dynamical acceleration, $g_\text{obs}$, the RAR has been claimed to manifest a new law of nature due to its regularity and tightness, in agreement with Modified Newtonian Dynamics (MOND). Fits to this relation have been restricted by prior expectations to particular functional forms, while ESR affords an exhaustive and nearly prior-free search through functional parameter space to identify the equations optimally trading accuracy with simplicity. Working with the SPARC data, we find the best functions typically satisfy $g_\text{obs} \propto g_\text{bar}$ at high $g_\text{bar}$, although the coefficient of proportionality is not clearly unity and the deep-MOND limit $g_\text{obs} \propto \sqrt{g_\text{bar}}$ as $g_\text{bar} \to 0$ is little evident at all. By generating mock data according to MOND with or without the external field effect, we find that symbolic regression would not be expected to identify the generating function or reconstruct successfully the asymptotic slopes. We conclude that the limited dynamical range and significant uncertainties of the SPARC RAR preclude a definitive statement of its functional form, and hence that this data alone can neither demonstrate nor rule out law-like gravitational behaviour.
翻译:我们用一种新的方法从数据中学习方程式 -- -- Exhaustive Regrestic Regrestition(ESR) -- -- 以学习在辐射加速关系(RAR)中包含的数据 -- -- Exhaustive Regrestical Regrestition(ESR) -- -- 来学习较晚类型的星系动态。将巴伦、$g<unk> text{bar}$g<unk> text{bar}美元等值的子宫加速度与总动态加速度($g<unk> text{bus}美元,RAR声称由于它的规律性和紧凑性,因此它适合这一关系的情况受到特定功能形式的期望限制,而ESRRSR则通过功能参数空间提供详尽和近乎于以往的免费搜索空间,以最优化地交易精确度。与STARC数据一起,我们发现最佳的功能一般满足${text{g}g>text{text{bar}$,尽管相称性系数并不明显,而深度的MONDread destrution $bar{blate rudeal rudeal rude rude rude</s>