Hierarchical learning, forecasting coherent spatio-temporal individual and aggregated building loads

TL;DR

This paper introduces a novel multi-dimensional hierarchical forecasting method that ensures coherent predictions across spatial, temporal, and combined hierarchies, specifically applied to building load forecasting in smart grids.

Contribution

It develops a unified framework for multi-dimensional hierarchies and a coherency-informed learning approach using custom loss functions and reconciliation techniques.

Findings

Coherent forecasts achieved across multiple hierarchy levels.

Performance varies depending on the case study and setup.

Identifies challenges and future directions for hierarchical forecasting.

Abstract

Optimal decision-making compels us to anticipate the future at different horizons. However, in many domains connecting together predictions from multiple time horizons and abstractions levels across their organization becomes all the more important, else decision-makers would be planning using separate and possibly conflicting views of the future. This notably applies to smart grid operation. To optimally manage energy flows in such systems, accurate and coherent predictions must be made across varying aggregation levels and horizons. With this work, we propose a novel multi-dimensional hierarchical forecasting method built upon structurally-informed machine-learning regressors and established hierarchical reconciliation taxonomy. A generic formulation of multi-dimensional hierarchies, reconciling spatial and temporal hierarchies under a common frame is initially defined. Next, a coherency-informed hierarchical learner is developed built upon a custom loss function leveraging optimal reconciliation methods. Coherency of the produced hierarchical forecasts is then secured using similar reconciliation technics. The outcome is a unified and coherent forecast across all examined dimensions. The method is evaluated on two different case studies to predict building electrical loads across spatial, temporal, and spatio-temporal hierarchies. Although the regressor natively profits from computationally efficient learning, results displayed disparate performances, demonstrating the value of hierarchical-coherent learning in only one setting. Yet, supported by a comprehensive result analysis, existing obstacles were clearly delineated, presenting distinct pathways for future work. Overall, the paper expands and unites traditionally disjointed hierarchical forecasting methods providing a fertile route toward a novel generation of forecasting regressors.