Research on Optimal Electrical Energy Management Method of Smart Grid Based on Value Iteration

The chapter describes a dynamic smart grid concept that enables electricity end-users to be acting on controlling, shifting, or curtailing own demand to avoid peak-demand conditions according to information received about electricity market conditions over the Internet. Computer-controlled switches are used to give users the ability to control and curtail demand on a user’s premises as necessary, following a preset user’s preferences. The computerized switching provides the ability to accommodate local renewable energy sources as available. The concept offers further the ability to integrate charging electrical vehicles during off-peak periods, helping thus substantially improving the utilization of the whole electricity system. The approach is pursuing improved use of electrical energy associated with improved energy management, reduced electricity prices and reduced pollution caused by excessive use of combustion engine in transport. The technique is inherently restricted to take effect in frame of energy tariff regimes based on real-time price made to encourage and reward conscious users being proactively participating in holistic energy management strategies.

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A Smart Autonomous Time- and Frequency-Domain Analysis Current Sensor-Based Power Meter Prototype Developed over Fog-Cloud Analytics for Demand-Side Management

Sensors ◽

10.3390/s19204443 ◽

2019 ◽

Vol 19 (20) ◽

pp. 4443 ◽

Cited By ~ 2

Author(s):

Yung-Yao Chen ◽

Yu-Hsiu Lin

Keyword(s):

Smart Grid ◽

Energy Management ◽

Electrical Energy ◽

Demand Side Management ◽

Current Sensor ◽

The Internet ◽

Load Identification ◽

Demand Side ◽

Power Meter ◽

Iot Devices

Electrical energy management, or demand-side management (DSM), in a smart grid is very important for electrical energy savings. With the high penetration rate of the Internet of Things (IoT) paradigm in modern society, IoT-oriented electrical energy management systems (EMSs) in DSM are capable of skillfully monitoring the energy consumption of electrical appliances. While many of today’s IoT devices used in EMSs take advantage of cloud analytics, IoT manufacturers and application developers are devoting themselves to novel IoT devices developed at the edge of the Internet. In this study, a smart autonomous time and frequency analysis current sensor-based power meter prototype, a novel IoT end device, in an edge analytics-based artificial intelligence (AI) across IoT (AIoT) architecture launched with cloud analytics is developed. The prototype has assembled hardware and software to be developed over fog-cloud analytics for DSM in a smart grid. Advanced AI well trained offline in cloud analytics is autonomously and automatically deployed onsite on the prototype as edge analytics at the edge of the Internet for online load identification in DSM. In this study, auto-labeling, or online load identification, of electrical appliances monitored by the developed prototype in the launched edge analytics-based AIoT architecture is experimentally demonstrated. As the proof-of-concept demonstration of the prototype shows, the methodology in this study is feasible and workable.

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Demand-Side Response Smart Grid Technique for Optimized Energy Use

Sustainable Practices ◽

10.4018/978-1-4666-4852-4.ch090 ◽

2013 ◽

pp. 1614-1639

Author(s):

Fouad Kamel ◽

Marwan Marwan

Keyword(s):

Smart Grid ◽

Energy Management ◽

Electricity Market ◽

Energy Use ◽

Combustion Engine ◽

Renewable Energy Sources ◽

Management Strategies ◽

Electrical Energy ◽

Electricity System ◽

Time Price

The chapter describes a dynamic smart grid concept that enables electricity end-users to be acting on controlling, shifting, or curtailing own demand to avoid peak-demand conditions according to information received about electricity market conditions over the Internet. Computer-controlled switches are used to give users the ability to control and curtail demand on a user’s premises as necessary, following a preset user's preferences. The computerized switching provides the ability to accommodate local renewable energy sources as available. The concept offers further the ability to integrate charging electrical vehicles during off-peak periods, helping thus substantially improving the utilization of the whole electricity system. The approach is pursuing improved use of electrical energy associated with improved energy management, reduced electricity prices and reduced pollution caused by excessive use of combustion engine in transport. The technique is inherently restricted to take effect in frame of energy tariff regimes based on real-time price made to encourage and reward conscious users being proactively participating in holistic energy management strategies.

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A Smart Grid Energy Management Problem for Data-driven Design with Probabilistic Reachability Guarantees

10.29007/5qvt ◽

2018 ◽

Author(s):

Daniele Ioli ◽

Alessandro Falsone ◽

Marianne Hartung ◽

Axel Busboom ◽

Maria Prandini

Keyword(s):

Smart Grid ◽

Energy Management ◽

Energy Production ◽

Electrical Energy ◽

Environmental Data ◽

Data Driven ◽

Management Problem ◽

Local Power ◽

Energy Management Strategy ◽

Battery Energy

In this paper we describe an energy management benchmark problem for a smart grid where electrical energy is supplied to a load via local power production from a solar PhotoVoltaic (PV) installation. The smart grid is connected with the main grid, which can eventually provide the energy needed for balancing demand and generation. The goal is to set the battery energy flow so as to keep the energy exchange with the main grid as close as possible to a nominal profile, within certified bounds, avoiding the fluctuations caused by the local PV energy production. Some energy production profiles of the PV installation and environmental data on irradiation and temperature are available for the design of the energy management strategy, together with a hybrid model for the battery and the electrical load profile. We describe a data-driven solution, pointing out its limits and providing some hint on possible direction for improvement.

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Validation of a Distributed Energy Management Approach for Smart Grid Based on a Generic Colored Petri Nets Model

Journal of Clean Energy Technologies ◽

10.18178/jocet.2018.6.1.430 ◽

2018 ◽

Vol 6 (1) ◽

pp. 20-25 ◽

Cited By ~ 3

Author(s):

Zeineb Mhadhbi ◽

◽

Sajeh Zairi ◽

Cedric Gueguen ◽

Belhassen Zouari ◽

...

Keyword(s):

Smart Grid ◽

Petri Nets ◽

Energy Management ◽

Colored Petri Nets ◽

Management Approach ◽

Distributed Energy ◽

Distributed Energy Management ◽

Grid Based

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A Novel Accurate and Fast Converging Deep Learning-Based Model for Electrical Energy Consumption Forecasting in a Smart Grid

Energies ◽

10.3390/en13092244 ◽

2020 ◽

Vol 13 (9) ◽

pp. 2244 ◽

Cited By ~ 2

Author(s):

Ghulam Hafeez ◽

Khurram Saleem Alimgeer ◽

Zahid Wadud ◽

Zeeshan Shafiq ◽

Mohammad Usman Ali Khan ◽

...

Keyword(s):

Deep Learning ◽

Energy Consumption ◽

Convergence Rate ◽

Smart Grid ◽

Energy Management ◽

Electrical Energy ◽

Features Selection ◽

Electrical Energy Consumption ◽

Efficient Energy ◽

Proposed Model

Energy consumption forecasting is of prime importance for the restructured environment of energy management in the electricity market. Accurate energy consumption forecasting is essential for efficient energy management in the smart grid (SG); however, the energy consumption pattern is non-linear with a high level of uncertainty and volatility. Forecasting such complex patterns requires accurate and fast forecasting models. In this paper, a novel hybrid electrical energy consumption forecasting model is proposed based on a deep learning model known as factored conditional restricted Boltzmann machine (FCRBM). The deep learning-based FCRBM model uses a rectified linear unit (ReLU) activation function and a multivariate autoregressive technique for the network training. The proposed model predicts future electrical energy consumption for efficient energy management in the SG. The proposed model is a novel hybrid model comprising four modules: (i) data processing and features selection module, (ii) deep learning-based FCRBM forecasting module, (iii) genetic wind driven optimization (GWDO) algorithm-based optimization module, and (iv) utilization module. The proposed hybrid model, called FS-FCRBM-GWDO, is tested and evaluated on real power grid data of USA in terms of four performance metrics: mean absolute percentage deviation (MAPD), variance, correlation coefficient, and convergence rate. Simulation results validate that the proposed hybrid FS-FCRBM-GWDO model has superior performance than existing models such as accurate fast converging short-term load forecasting (AFC-STLF) model, mutual information-modified enhanced differential evolution algorithm-artificial neural network (MI-mEDE-ANN)-based model, features selection-ANN (FS-ANN)-based model, and Bi-level model, in terms of forecast accuracy and convergence rate.

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