确保微分和平均随机动力学相等的图形条件

Hugo BuscemiENS Paris Saclay, Lifeware, François FagesLifeware
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引用次数: 0

摘要

用形式化反应系统(RS)(又称化学反应网络)对复杂系统进行建模具有优势。根据问题的不同,基于反应的模型可以用不同层次的语义进行解释,其中最主要的是常微分方程(ODE)、连续时间马尔可夫链(CTMC)、离散 Petri 网和异步布尔转换系统。后三种语义可以很容易地在抽象解释框架中联系起来。库尔兹极限定理(Kurtz's limittheorem)指出,如果反应是密度依赖族,那么随着体积变为无穷大,CTMC 的平均反应物浓度就会趋向于 ODE 的解。在更现实的有界体积背景下,很容易通过矩闭合证明,对最多只有一种反应物的反应的限制同样确保了 CTMC 轨迹的平均值等于所有时间点的 ODE 解。在本文中,我们将这一结果推广到多反应物反应中,引入了反应物的化学影响和修饰图(SIMG),并证明对于属于多反应物反应的不同 SIMG 祖先的变量来说,两种解释之间的相等性是成立的。在生物模型上进行的评估表明,所有变量的条件仅在具有单分子反应的模型上得到满足。然而,我们的定理可以有选择地应用于模型中的某些变量,以便深入了解它们在更复杂系统中的行为。有趣的是,我们还证明了在实现时间的正弦和余弦函数的非平稳振荡 RS 中,该等式也是成立的。
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Graphical Conditions ensuring Equality between Differential and Mean Stochastic Dynamics
Complex systems can be advantageously modeled by formal reaction systems (RS), a.k.a. chemical reaction networks in chemistry. Reaction-based models can indeed be interpreted in a hierarchy of semantics, depending on the question at hand, most notably by Ordinary Differential Equations (ODEs), Continuous Time Markov Chains (CTMCs), discrete Petri nets and asynchronous Boolean transition systems. The last three semantics can be easily related in the framework of abstract interpretation. The first two are classically related by Kurtz's limit theorem which states that if reactions are density-dependent families, then, as the volume goes to infinity, the mean reactant concentrations of the CTMC tends towards the solution of the ODE. In the more realistic context of bounded volumes, it is easy to show, by moment closure, that the restriction to reactions with at most one reactant ensures similarly that the mean of the CTMC trajectories is equal to the solution of the ODE at all time points. In this paper, we generalize that result in presence of polyreactant reactions, by introducing the Stoichiometric Influence and Modification Graph (SIMG) of an RS, and by showing that the equality between the two interpretations holds for the variables that belong to distinct SIMG ancestors of polyreactant reactions. We illustrate this approach with several examples. Evaluation on BioModels reveals that the condition for all variables is satisfied on models with no polymolecular reaction only. However, our theorem can be applied selectively to certain variables of the model to provide insights into their behaviour within more complex systems. Interestingly, we also show that the equality holds for a basic oscillatory RS implementing the sine and cosine functions of time.
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