Your search keyword '"structural uncertainty"' showing total 2 results

1. Learning stochastic process-based models of dynamical systems from knowledge and data.

Author

Tanevski, Jovan, Todorovski, Ljupčo, and Džeroski, Sašo

Subjects

*LEARNING, *DYNAMICAL systems, *STOCHASTIC analysis, *THEORY of knowledge, *DATA analysis

Abstract

Background: Identifying a proper model structure, using methods that address both structural and parameter uncertainty, is a crucial problem within the systems approach to biology. And yet, it has a marginal presence in the recent literature. While many existing approaches integrate methods for simulation and parameter estimation of a single model to address parameter uncertainty, only few of them address structural uncertainty at the same time. The methods for handling structure uncertainty often oversimplify the problem by allowing the human modeler to explicitly enumerate a relatively small number of alternative model structures. On the other hand, process-based modeling methods provide flexible modular formalisms for specifying large classes of plausible model structures, but their scope is limited to deterministic models. Here, we aim at extending the scope of process-based modeling methods to inductively learn stochastic models from knowledge and data. Results: We combine the flexibility of process-based modeling in terms of addressing structural uncertainty with the benefits of stochastic modeling. The proposed method combines search trough the space of plausible model structures, the parsimony principle and parameter estimation to identify a model with optimal structure and parameters. We illustrate the utility of the proposed method on four stochastic modeling tasks in two domains: gene regulatory networks and epidemiology. Within the first domain, using synthetically generated data, the method successfully recovers the structure and parameters of known regulatory networks from simulations. In the epidemiology domain, the method successfully reconstructs previously established models of epidemic outbreaks from real, sparse and noisy measurement data. Conclusions: The method represents a unified approach to modeling dynamical systems that allows for flexible formalization of the space of candidate model structures, deterministic and stochastic interpretation of model dynamics, and automated induction of model structure and parameters from data. The method is able to reconstruct models of dynamical systems from synthetic and real data. [ABSTRACT FROM AUTHOR]

Published

2016

2. Learning stochastic process-based models of dynamical systems from knowledge and data

Author

Jovan Tanevski, Sašo Džeroski, and Ljupčo Todorovski

Subjects

0301 basic medicine, Compartmental epidemiological models, Process-based modeling, Dynamical systems theory, Process (engineering), Stochastic modelling, Computer science, 0206 medical engineering, Stochastic interpretation, 02 engineering and technology, Machine learning, computer.software_genre, Models, Biological, Structural uncertainty, Disease Outbreaks, 03 medical and health sciences, Structural Biology, Modelling and Simulation, Dynamical systems, Influenza, Human, Humans, Gene Regulatory Networks, Molecular Biology, Flexibility (engineering), Structure (mathematical logic), Plague, Stochastic Processes, business.industry, Stochastic process, Methodology Article, Applied Mathematics, Uncertainty, Computational Biology, Rotation formalisms in three dimensions, Computer Science Applications, Stochastic models, Kinetics, 030104 developmental biology, Modeling and Simulation, Data mining, Artificial intelligence, business, computer, Genetic regulatory networks, 020602 bioinformatics

Abstract

Background Identifying a proper model structure, using methods that address both structural and parameter uncertainty, is a crucial problem within the systems approach to biology. And yet, it has a marginal presence in the recent literature. While many existing approaches integrate methods for simulation and parameter estimation of a single model to address parameter uncertainty, only few of them address structural uncertainty at the same time. The methods for handling structure uncertainty often oversimplify the problem by allowing the human modeler to explicitly enumerate a relatively small number of alternative model structures. On the other hand, process-based modeling methods provide flexible modular formalisms for specifying large classes of plausible model structures, but their scope is limited to deterministic models. Here, we aim at extending the scope of process-based modeling methods to inductively learn stochastic models from knowledge and data. Results We combine the flexibility of process-based modeling in terms of addressing structural uncertainty with the benefits of stochastic modeling. The proposed method combines search trough the space of plausible model structures, the parsimony principle and parameter estimation to identify a model with optimal structure and parameters. We illustrate the utility of the proposed method on four stochastic modeling tasks in two domains: gene regulatory networks and epidemiology. Within the first domain, using synthetically generated data, the method successfully recovers the structure and parameters of known regulatory networks from simulations. In the epidemiology domain, the method successfully reconstructs previously established models of epidemic outbreaks from real, sparse and noisy measurement data. Conclusions The method represents a unified approach to modeling dynamical systems that allows for flexible formalization of the space of candidate model structures, deterministic and stochastic interpretation of model dynamics, and automated induction of model structure and parameters from data. The method is able to reconstruct models of dynamical systems from synthetic and real data.

Published

2016