Abstract
This study considers the forecasting of mortality rates in multiple populations. We propose a model that combines mortality forecasting and functional data analysis (FDA). Under the FDA framework, the mortality curve of each year is assumed to be a smooth function of age. As with most of the functional time series forecasting models, we rely on functional principal component analysis (FPCA) for dimension reduction and further choose a vector error correction model (VECM) to jointly forecast mortality rates in multiple populations. This model incorporates the merits of existing models in that it excludes some of the inherent randomness with the nonparametric smoothing from FDA, and also utilizes the correlation structures between the populations with the use of VECM in mortality models. A nonparametric bootstrap method is also introduced to construct interval forecasts. The usefulness of this model is demonstrated through a series of simulation studies and applications to the age-and sex-specific mortality rates in Switzerland and the Czech Republic. The point forecast errors of several forecasting methods are compared and interval scores are used to evaluate and compare the interval forecasts. Our model provides improved forecast accuracy in most cases.
Highlights
Most countries around the world have seen steady decreases in mortality rates in recent years, which come with aging populations
We propose a model under the functional data analysis (FDA) framework
We have extended the existing models and introduced a functional vector error correction model (VECM) for the prediction of multivariate functional time series
Summary
Most countries around the world have seen steady decreases in mortality rates in recent years, which come with aging populations. Carter and Lee [7] examine how mortality rates of female and male populations can be forecast together using only one time-varying component. Danesi et al [11] compare several multi-population forecasting models and show that the preferred models are those providing a balance between model parsimony and flexibility These mentioned approaches model mortality rates using raw data without smoothing techniques. We are not the first to use the functional data approach to model mortality rates. Smooth the observed data in each population; reduce the dimension of the functions in each population using functional principal component analysis (FPCA) separately; fit the first set of principal component scores from all populations with VECM. Yang and Wang [9] and Zhou et al [10] use VECM to model the time-varying factor, namely, the first set of principal component scores.
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