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A low-rank complexity reduction algorithm for the high-dimensional kinetic chemical master equation

Lukas Einkemmer, Julian Mangott, Martina Prugger

2024Journal of Computational Physics9 citationsDOIOpen Access PDF

Abstract

It is increasingly realized that taking stochastic effects into account is important in order to study biological cells. However, the corresponding mathematical formulation, the chemical master equation (CME), suffers from the curse of dimensionality and thus solving it directly is not feasible for most realistic problems. In this paper we propose a dynamical low-rank algorithm for the CME that reduces the dimensionality of the problem by dividing the reaction network into partitions. Only reactions that cross partitions are subject to an approximation error (everything else is computed exactly). This approach, compared to the commonly used stochastic simulation algorithm (SSA, a Monte Carlo method), has the advantage that it is completely noise-free. This is particularly important if one is interested in resolving the tails of the probability distribution. We show that in some cases (e.g. for the lambda phage) the proposed method can drastically reduce memory consumption and run time and provide better accuracy than SSA.

Topics & Concepts

Curse of dimensionalityMaster equationDimensionality reductionAlgorithmMonte Carlo methodComputer scienceRank (graph theory)Reduction (mathematics)Noise (video)Applied mathematicsMathematical optimizationMathematicsStatistical physicsArtificial intelligencePhysicsStatisticsCombinatoricsQuantum mechanicsImage (mathematics)GeometryQuantumGene Regulatory Network AnalysisAdvanced Fluorescence Microscopy TechniquesSingle-cell and spatial transcriptomics
A low-rank complexity reduction algorithm for the high-dimensional kinetic chemical master equation | Litcius