The electricity industry is heavily implementing smart grid technologies to improve reliability, availability, security, and efficiency. This implementation needs technological advancements, the development of standards and regulations, as well as testing and planning. Smart grid load forecasting and management are critical for reducing demand volatility and improving the market mechanism that connects generators, distributors, and retailers. During policy implementations or external interventions, it is necessary to analyse the uncertainty of their impact on the electricity demand to enable a more accurate response of the system to fluctuating demand. This paper analyses the uncertainties of external intervention impacts on electricity demand. It implements a framework that combines probabilistic and global forecasting models using a deep learning approach to estimate the causal impact distribution of an intervention. The causal effect is assessed by predicting the counterfactual distribution outcome for the affected instances and then contrasting it to the real outcomes. We consider the impact of Covid-19 lockdowns on energy usage as a case study to evaluate the non-uniform effect of this intervention on the electricity demand distribution. We could show that during the initial lockdowns in Australia and some European countries, there was often a more significant decrease in the troughs than in the peaks, while the mean remained almost unaffected.
翻译:电力工业正在大力应用智能电网技术,以提高可靠性、可用性、安全性和效率。这一实施需要技术进步,制定标准和条例,以及测试和规划。智能电网负荷预测和管理对于减少需求波动和改善连接发电机、分销商和零售商的市场机制至关重要。在政策实施或外部干预期间,有必要分析其对电力需求影响的不确定性,以便能够更准确地应对电力需求波动。本文分析了外部干预对电力需求影响的不确定性。它采用了一种框架,将概率和全球预测模型结合起来,采用深层次的学习方法来估计干预措施的因果影响分布。通过预测受影响案例的反实际分配结果来评估因果关系,然后将其与实际结果进行对比。我们考虑Covid-19锁定对能源使用的影响,以此作为一项案例研究,评估这一干预对电力需求分配的不统一影响。我们可以表明,在澳大利亚和一些欧洲国家的初始封闭期间,在最高峰期间,风险程度往往比最低时要低得多。