1. Modeling seasonality and serial dependence of electricity price curves with warping functional autoregressive dynamics
- Author
-
James Stephen Marron, Jiejie Zhang, and Ying Chen
- Subjects
0301 basic medicine ,Statistics and Probability ,Electricity price ,Seasonal functional time series ,01 natural sciences ,warping function ,010104 statistics & probability ,03 medical and health sciences ,Econometrics ,medicine ,0101 mathematics ,Image warping ,Karcher mean ,Mathematics ,business.industry ,Seasonality ,medicine.disease ,030104 developmental biology ,Amplitude ,Autoregressive model ,Modeling and Simulation ,Electricity ,Statistics, Probability and Uncertainty ,business ,Smoothing ,Serial dependence - Abstract
Electricity prices are high dimensional, serially dependent and have seasonal variations. We propose a Warping Functional AutoRegressive (WFAR) model that simultaneously accounts for the cross time-dependence and seasonal variations of the large dimensional data. In particular, electricity price curves are obtained by smoothing over the $24$ discrete hourly prices on each day. In the functional domain, seasonal phase variations are separated from level amplitude changes in a warping process with the Fisher–Rao distance metric, and the aligned (season-adjusted) electricity price curves are modeled in the functional autoregression framework. In a real application, the WFAR model provides superior out-of-sample forecast accuracy in both a normal functioning market, Nord Pool, and an extreme situation, the California market. The forecast performance as well as the relative accuracy improvement are stable for different markets and different time periods.
- Published
- 2019
- Full Text
- View/download PDF