Coherent Forecasting of the Novel Geometric Autoregressive (NoGeAR(1)) Model

The coherent forecasting methodology established for the NoGeAR(1) model can be extended to higher-order INAR models by leveraging the foundational principles of the NoGeAR(1) process while adapting the transition probabilities and conditional distributions to accommodate the increased complexity of higher-order dependencies. Specifically, the two-step ahead conditional distribution can be generalized by employing recursive relationships that account for the additional lagged terms in the model. This involves deriving the transition probabilities for the higher-order states and utilizing similar Monte Carlo approximation techniques to estimate the h-step ahead forecasts. For other types of integer-valued time series models, such as the New Geometric INAR (NGINAR) or Negative Binomial INAR (NBINAR), the coherent forecasting framework can be adapted by defining the appropriate thinning operators and transition probabilities specific to those models. The key is to maintain the integrity of the coherent forecasting principles—ensuring that the forecasts remain integer-valued and that the chosen point forecasts (median, mode) align with the characteristics of the underlying distribution. Additionally, the methodology can be enhanced by incorporating Bayesian approaches or machine learning techniques to improve forecast accuracy and robustness across various integer-valued time series contexts.

The Monte Carlo approximation approach, while effective for deriving the h-step ahead conditional distribution of the NoGeAR(1) model, has several potential limitations. Firstly, the accuracy of the Monte Carlo estimates is contingent upon the number of simulations performed; insufficient iterations can lead to biased or unstable estimates of the transition probabilities. This is particularly critical in scenarios with high variability or skewness in the distribution, as seen in overdispersed count data. Secondly, the computational intensity of the Monte Carlo method can be a drawback, especially when dealing with higher-order forecasts or large datasets. The time required for simulations can become prohibitive, limiting the practicality of the approach in real-time forecasting applications. Alternative methods that could be explored include analytical approaches that seek to derive closed-form expressions for the conditional distributions, although this may be challenging due to the complexity of the NoGeAR(1) model. Another alternative is the use of numerical methods, such as the Fast Fourier Transform (FFT) or other computational techniques, to approximate the probability generating functions more efficiently. Additionally, Bayesian methods could provide a robust framework for estimating the conditional distributions, allowing for the incorporation of prior information and potentially yielding more accurate forecasts.

The insights gained from the coherent forecasting analysis of the NoGeAR(1) model can significantly inform decision-making in real-world applications like CWß TeXpert downloads and Barbados COVID-19 data. For instance, in the context of CWß TeXpert downloads, understanding the patterns and trends in download counts can help developers and marketers optimize their strategies for user engagement and resource allocation. By utilizing coherent forecasts, stakeholders can anticipate future download volumes, allowing for proactive measures in server capacity planning and marketing campaigns. In the case of Barbados COVID-19 data, coherent forecasting can provide critical insights into the expected number of cases, which is essential for public health planning and resource management. Accurate forecasts can guide policymakers in implementing timely interventions, such as vaccination drives or public health campaigns, to mitigate the spread of the virus. Furthermore, the ability to generate prediction intervals through the highest predictive probability (HPP) method enhances the reliability of forecasts, enabling decision-makers to prepare for various scenarios and allocate resources effectively. Overall, the coherent forecasting methodology not only enhances the accuracy of predictions but also empowers stakeholders in these domains to make informed, data-driven decisions that can lead to improved outcomes and strategic planning.