Abstract
Already a 1% improvement to the overall forecast accuracy of mortality rates, may lead to the significant decrease of insurers costs. In practice, Lee-Carter model is widely used for forecasting the mortality rates. Within this study, we combine the traditional Lee-Carter model with the recent advances in the weighted model averaging. For this purpose, first, the training database of template predictive models is constructed for the mortality data and processed with similarity measures, and secondly, competitive predictive models are averaged to produce forecasts. The main innovation of the proposed approach is reflecting the uncertainty related to the shortness (e.g., 14 observations) of available data by the incorporation of multiple predictive models. The performance of the proposed approach is illustrated with experiments for the Human Mortality Database. We analyzed time series datasets for women and men aged 0–100 years from 10 countries in the Central and Eastern Europe. The presented numerical results seem very promising and show that the proposed approach is highly competitive with the state-of-the-art models. It outperforms benchmarks especially when forecasting long periods (6–10 years ahead).
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Notes
- 1.
We can distinguish high mortality countries from low mortality countries with life expectancy at birth [United Nations, Department of Economic and Social Affairs, Population Division (2013). World Mortality Report 2013 (United Nations publication)]. This indicator for Euro Area overtakes 82, while for Central Europe and the Baltics equals 77 [The World Bank 2015].
- 2.
Datasets are available for download from https://www.mortality.org.
- 3.
Some authors calculate prediction errors based on the model’s variable \(\ln (m_ {x, t})\). It is worth pointing out that this approach does not always generate the same conclusions (the results are not equivalent). From a practical point of view we are interested in the central death rate. The LC model is just a estimation tool. Therefore, we compute errors comparing the estimated values to the central death rate.
- 4.
According to MAE relative differences.
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Bartkowiak, M., Kaczmarek-Majer, K., Rutkowska, A., Hryniewicz, O. (2018). Model Averaging Approach to Forecasting the General Level of Mortality. In: Medina, J., et al. Information Processing and Management of Uncertainty in Knowledge-Based Systems. Theory and Foundations. IPMU 2018. Communications in Computer and Information Science, vol 853. Springer, Cham. https://doi.org/10.1007/978-3-319-91473-2_39
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