Inferring interaction potentials from stochastic particle trajectories

arXiv - PHYS - Data Analysis, Statistics and Probability Pub Date : 2024-06-03 DOI:arxiv-2406.01522

Ella M. King, Megan C. Engel, Caroline Martin, Alp M. Sunol, Qian-Ze Zhu, Sam S. Schoenholz, Vinothan N. Manoharan, Michael P. Brenner

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引用次数: 0

Abstract

Accurate interaction potentials between microscopic components such as colloidal particles or cells are crucial to understanding a range of processes, including colloidal crystallization, bacterial colony formation, and cancer metastasis. Even in systems where the precise interaction mechanisms are unknown, effective interactions can be measured to inform simulation and design. However, these measurements are difficult and time-intensive, and often require conditions that are drastically different from in situ conditions of the system of interest. Moreover, existing methods of measuring interparticle potentials rely on constraining a small number of particles at equilibrium, placing limits on which interactions can be measured. We introduce a method for inferring interaction potentials directly from trajectory data of interacting particles. We explicitly solve the equations of motion to find a form of the potential that maximizes the probability of observing a known trajectory. Our method is valid for systems both in and out of equilibrium, is well-suited to large numbers of particles interacting in typical system conditions, and does not assume a functional form of the interaction potential. We apply our method to infer the interactions of colloidal spheres from experimental data, successfully extracting the range and strength of a depletion interaction from the motion of the particles.

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从随机粒子轨迹推断相互作用势

微观成分（如胶体粒子或细胞）之间精确的相互作用势对于理解一系列过程至关重要，这些过程包括胶体结晶、细菌菌落形成和癌症转移。即使在精确的相互作用机制未知的系统中，也可以测量有效的相互作用，为模拟和设计提供信息。然而，这些测量既困难又耗时，而且所需的条件往往与相关系统的原位条件大相径庭。此外，现有的粒子间势能测量方法依赖于对少量处于平衡状态的粒子进行约束，这就对可以测量的相互作用施加了限制。我们介绍了一种直接从相互作用粒子的轨迹数据推断相互作用势的方法。我们明确地求解运动方程，以找到一种最大化观测已知轨迹概率的相互作用势形式。我们的方法对处于平衡和非平衡状态的系统都有效，非常适合在典型系统条件下相互作用的大量粒子，而且不假定相互作用势的函数形式。我们应用我们的方法从实验数据中推断胶体球的相互作用，成功地从粒子的运动中提取了耗竭相互作用的范围和强度。

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arXiv - PHYS - Data Analysis, Statistics and Probability

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