Abstract
Building energy management systems (BEMS) have been intensively used to manage the electricity consumption of residential buildings more efficiently. However, the dynamic behavior of the occupants introduces uncertainty problems that affect the performance of the BEMS. To address this uncertainty problem, the BEMS may implement load forecasting as one of the BEMS modules. Load forecasting utilizes historical load data to compute model predictions for a specific time in the future. Recently, smart meters have been introduced to collect electricity consumption data. Smart meters not only capture aggregation data, but also individual data that is more frequently close to real-time. The processing of both smart meter data types for load forecasting can enhance the performance of the BEMS when confronted with uncertainty problems. The collection of smart meter data can be processed using a batch approach for short-term load forecasting, while the real-time smart meter data can be processed for very short-term load forecasting, which adjusts the short-term load forecasting to adapt to the dynamic behavior of the occupants. This approach requires different data processing techniques for aggregation and individual of smart meter data. In this paper, we propose Lambda-based data processing architecture to process the different types of smart meter data and implement the two-level load forecasting approach, which combines short-term and very short-term load forecasting techniques on top of our proposed data processing architecture. The proposed approach is expected to enhance the BEMS to address the uncertainty problem in order to process data in less time. Our experiment showed that the proposed approaches improved the accuracy by 7% compared to a typical BEMS with only one load forecasting technique, and had the lowest computation time when processing the smart meter data.
Highlights
Buildings have been identified as entities that consume a significant portion of electricity [1,2,3].The residential building, as one building type, consumed 38% of total U.S electricity in 2014 [4], which makes it a significant prominent electricity consumer in the building sector
Our experiment showed that the proposed approaches improved the accuracy by 7% compared to a typical Building energy management systems (BEMS) with only one load forecasting technique, and had the lowest computation time when processing the smart meter data
Our contributions in this paper are as follows: (1) We introduce two-level load forecasting to enable the system to adapt to the dynamic behavior of the occupants; (2) We propose a Lambda-like architecture to process the smart meter data following the different time processing requirements; (3) We evaluate our system using a real dataset by comparing the cost reduction and time processing to show the advantages of our proposed architecture
Summary
Buildings have been identified as entities that consume a significant portion of electricity [1,2,3].The residential building, as one building type, consumed 38% of total U.S electricity in 2014 [4], which makes it a significant prominent electricity consumer in the building sector. A significant portion of the energy consumption in residential buildings is used for the services that maintain the occupants’ comfort, such as heat, ventilation, and air conditioning (HVAC) and lighting systems [5,6]. Energies 2018, 11, 772 consists of oil-fuel-based electricity, and the rise of renewable energy sources with unstable electricity provision has become a limitation to providing the electricity demands of residential buildings. This situation increases the need to manage the electricity consumption of residential buildings more efficiently. This dynamic behavior introduces an uncertainty problem that may reduce the performance of the BEMS
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