Abstract
In this study, experiments are conducted to gauge the relative importance of model, initial condition, and driving climate uncertainty for simulations of malaria transmission at a highland plantation in Kericho, Kenya. A genetic algorithm calibrates each of these three factors within their assessed prior uncertainty in turn to see which allows the best fit to a timeseries of confirmed cases. It is shown that for high altitude locations close to the threshold for transmission, the spatial representativeness uncertainty for climate, in particular temperature, dominates the uncertainty due to model parameter settings. Initial condition uncertainty plays little role after the first two years, and is thus important in the early warning system context, but negligible for decadal and climate change investigations. Thus, while reducing uncertainty in the model parameters would improve the quality of the simulations, the uncertainty in the temperature driving data is critical. It is emphasized that this result is a function of the mean climate of the location itself, and it is shown that model uncertainty would be relatively more important at warmer, lower altitude locations.
Highlights
Any prediction for the future, whether for days, years or centuries, should be accompanied with an estimate of its uncertainty or confidence [1]
The convergence of the algorithm is first examined for the case where all climate, model parameters and initial conditions are calibrated, in order to confirm that the Parameter K Infiltration and evaporation loss
The approach was to use a genetic algorithm to calibrate the driving climate data and the malaria model parameters, each constrained by an estimate of parameter uncertainty
Summary
Any prediction for the future, whether for days, years or centuries, should be accompanied with an estimate of its uncertainty or confidence [1]. This is valid for short range and seasonal forecasts and long-term projections of climate-sensitive health outcomes. Understanding this uncertainty is critical if forecast information is to contribute to health decision making effectively. Incorporating uncertainty into the decision-making process should help to ensure forecasts are primarily used when confidence is high, minimizing potential losses from poor forecasts. The necessity to understand the decision context adds an additional layer of complexity [2, 3]
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