Active Learning to Understand Infectious Disease Models and Improve Policy Making
Authored by Lander Willem, Sean Stijven, Philippe Beutels, Niel Hens, Jan Broeckhove, Ekaterina Vladislavleva
Date Published: 2014
DOI: 10.1371/journal.pcbi.1003563
Sponsors:
No sponsors listed
Platforms:
C++
Model Documentation:
Other Narrative
Model Code URLs:
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Abstract
Modeling plays a major role in policy making, especially for infectious
disease interventions but such models can be complex and computationally
intensive. A more systematic exploration is needed to gain a thorough
systems understanding. We present an active learning approach based on
machine learning techniques as iterative surrogate modeling and
model-guided experimentation to systematically analyze both common and
edge manifestations of complex model runs. Symbolic regression is used
for nonlinear response surface modeling with automatic feature
selection. First, we illustrate our approach using an individual-based
model for influenza vaccination. After optimizing the parameter space, we observe an inverse relationship between vaccination coverage and
cumulative attack rate reinforced by herd immunity. Second, we
demonstrate the use of surrogate modeling techniques on input-response
data from a deterministic dynamic model, which was designed to explore
the cost-effectiveness of varicella-zoster virus vaccination. We use
symbolic regression to handle high dimensionality and correlated inputs
and to identify the most influential variables. Provided insight is used
to focus research, reduce dimensionality and decrease decision
uncertainty. We conclude that active learning is needed to fully
understand complex systems behavior. Surrogate models can be readily
explored at no computational expense, and can also be used as emulator
to improve rapid policy making in various settings.
Tags
Design
cost-effectiveness
symbolic regression
Outbreaks
Pandemic influenza
Strategies
United-states
Impact
Sensitivity-analysis
Varicella vaccination programs