Optimal Forecast Reconciliation with Uncertainty Quantification
Abstract
We propose to estimate the weight matrix used for forecast reconciliation as parameters in a general linear model in order to quantify its uncertainty. This implies that forecast reconciliation can be formulated as an orthogonal projection from the space of base-forecast errors into a coherent linear subspace. We use variance decomposition together with the Wishart distribution to derive the central estimator for the forecast-error covariance matrix. In addition, we prove that distance-reducing properties apply to the reconciled forecasts at all levels of the hierarchy as well as to the forecast-error covariance. A covariance matrix for the reconciliation weight matrix is derived, which leads to improved estimates of the forecast-error covariance matrix. We show how shrinkage can be introduced in the formulated model by imposing specific priors on the weight matrix and the forecast-error covariance matrix. The method is illustrated in a simulation study that shows consistent improvements in the log-score. Finally, standard errors for the weight matrix and the variance-separation formula are illustrated using a case study of forecasting electricity load in Sweden.
Cite
@article{arxiv.2402.06480,
title = {Optimal Forecast Reconciliation with Uncertainty Quantification},
author = {Jan Kloppenborg Møller and Peter Nystrup and Poul G. Hjorth and Henrik Madsen},
journal= {arXiv preprint arXiv:2402.06480},
year = {2024}
}
Comments
51 pages