The V2G Process With the Predictive Model

Mroczek, Bartłomiej; Kolodynska, Amanda

doi:10.1109/access.2020.2991329

Cited by 14 publications

(9 citation statements)

References 24 publications

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“…As investigated and demonstrated in several published studies, as in [17], [18], [19], [19], [20], [21], [22], and [23], this option of bidirectional power interface has an extremely vital impact, permitting, for example, to control the EV to overcome issues of efficiency and power quality in the power grid. In this standpoint, with the consent of the EV driver (e.g., guaranteeing advantageous tariffs for programs of power management sustained by the G2V/V2G modes, and knowing that the EV battery can be degraded when subjected to additional charge/discharge cycles), the EV can be controlled by an algorithm of power management of the smart home or smart grid, which outlines the programming modes for charging (G2V) and discharging (V2G) processes [24].…”

Section: Ev In Smart Homes and Smart Grids: Overview Of Operation Modesmentioning

confidence: 99%

The Role of the Electric Vehicle in Smart Homes: Assessment and Future Perspectives

Monteiro¹,

Afonso²,

Ferreira³

et al. 2021

EAI Endorsed Transactions on Energy Web

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The wide spreading of electric mobility is imposing the application of new technologies of hardware and software for supporting new operation paradigms, not only in the perspective of improving smart grids, but also each time more in the perspective of boosting the preponderance of smart homes. Concretely, nowadays it is clear that the emergent technologies for smart homes, targeting power quality and a more efficient power management, are also altering the conventional electrical power grids toward smart grids. In this panorama, by relating the strategic pillars of electric mobility and smart homes, this paper has as main objective the characterization of the role of the electric vehicle (EV) in smart homes, presenting a broad assessment based on the state of the art, as well as creating a link with upcoming advanced operations. From the smart home point of view, since it should be equipped to deal with the requirements of the EV, the assessment of both on-board and off-board EV battery charging systems are considered along the paper. Furthermore, the presence of technologies such as energy storage systems, renewable energy sources and dc electrical appliances in smart homes towards sustainability is also reflected in this paper, but framed from the point of view of an off-board EV battery charging system, since it is more convenient for enabling the interface of these mentioned technologies. Looking the paper as a whole, a relevant contribution is the discussion of future operations for the EV in smart homes, also envisioning the opportunity for ac, dc, or hybrid power grids. Illustrative and strategic results are shown, covering all these features with specific details, not only based on numerical simulations, but also based on experimental results, which were obtained with a proof-of-concept laboratory prototype.

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Section: Ev In Smart Homes and Smart Grids: Overview Of Operation Modesmentioning

confidence: 99%

The Role of the Electric Vehicle in Smart Homes: Assessment and Future Perspectives

Monteiro¹,

Afonso²,

Ferreira³

et al. 2021

EAI Endorsed Transactions on Energy Web

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“…Electric vehicles (EVs) have become popular due to several environmental and economical advantages compared to fossil fuel cars such as reducing pollution, greenhouse gas emission, and operation cost [1]. In modern transportation systems, EVs are the preferred choice due to their energy and environmental sustainability, although they often fail to find proper charging stations due to the limited infrastructure of Smart Grid (SG) and unbalance demand of charging.…”

Section: Introductionmentioning

confidence: 99%

“…erefore, the efficient management of the EVs charging/discharging to reduce cost has become challenging due to random EV's arrival and departure times, randomness of the EVs' utility, and dynamic price of energy. In V2G, EVs can be used for excess energy storage from the SG to balance energy demand, smooth demand peak, and eliminate distribution losses [1].…”

Section: Introductionmentioning

confidence: 99%

“…; at the same time, there are disadvantages like adverse battery effects, new infrastructure, new trading mechanism, and security from cyberattacks, replay attacks, data manipulation attacks, etc. For example, Bartłomiej et al [1] presented the effectiveness of the V2G process using predictive model [9,10]. Moreover, the various ML-and DL-based approaches exist, but they have various challenges; for example, ML/DL models are trained on the training data and then tested over the test dataset.…”

Section: Introductionmentioning

confidence: 99%

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SV2G-ET: A Secure Vehicle-to-Grid Energy Trading Scheme Using Deep Reinforcement Learning

Kumari

Trivedi

Tanwar

et al. 2022

International Transactions on Electrical Energy Systems

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In recent years, advancements in electric vehicle (EV) technology and rising petrol prices have increased the demand for EVs and also made them important for the Smart Grid (SG) economy. During the high energy demand, Vehicle to Grid (V2G) comprises a notable feature that returns the stored energy back to the grid. However, due to dynamic nature of energy prices and EVs availability, determining the best charging and discharging strategy is quite difficult. The existing approaches need a model to predict the uncertainty and optimize the scheduling problem. Further, other issues like security, scalability, and real-time data accessibility of EVs energy trading (ET) data at low cost also exist. Though many solutions exist, they are not adequate to handle the aforementioned issues. This paper proposes a Secure V2G-Energy Trading (SV2G-ET) scheme using deep Reinforcement Learning (RL) and Ethereum Blockchain Technology (EBT). The proposed SV2G-ET scheme employs a deep Q-network for EVs scheduling for charging/discharging. SV2G-ET scheme uses InterPlanetary File System (IPFS) and smart contract (SC) for secure access of EV’s ET data in real time. The experimental results prove the efficacy of the proposed SV2G-ET scheme that leads to improved scalability, saving the EVs charging cost, low ET data storage cost, and increased EV owner’s profit.

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“…The authors in [ 18 ] propose using the BLDC motor thermal model to optimize the trajectory of the industrial robot movements, taking into account thermal constraints. Moreover, based on the research conducted by the authors in [ 19 ], it can be concluded that thermal modeling of a traction motor with permanent magnets will have a significant impact on the optimization of V2G (vehicle to grid) systems, because the amount of energy consumed by an electric vehicle is dependent on thermal losses of its motor.…”

Section: Introductionmentioning

confidence: 99%

Machine Learning for Sensorless Temperature Estimation of a BLDC Motor

Czerwiński

Gęca

Kolano

2021

Sensors

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In this article, the authors propose two models for BLDC motor winding temperature estimation using machine learning methods. For the purposes of the research, measurements were made for over 160 h of motor operation, and then, they were preprocessed. The algorithms of linear regression, ElasticNet, stochastic gradient descent regressor, support vector machines, decision trees, and AdaBoost were used for predictive modeling. The ability of the models to generalize was achieved by hyperparameter tuning with the use of cross-validation. The conducted research led to promising results of the winding temperature estimation accuracy. In the case of sensorless temperature prediction (model 1), the mean absolute percentage error MAPE was below 4.5% and the coefficient of determination R2 was above 0.909. In addition, the extension of the model with the temperature measurement on the casing (model 2) allowed reducing the error value to about 1% and increasing R2 to 0.990. The results obtained for the first proposed model show that the overheating protection of the motor can be ensured without direct temperature measurement. In addition, the introduction of a simple casing temperature measurement system allows for an estimation with accuracy suitable for compensating the motor output torque changes related to temperature.

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The V2G Process With the Predictive Model

Cited by 14 publications

References 24 publications

The Role of the Electric Vehicle in Smart Homes: Assessment and Future Perspectives

The Role of the Electric Vehicle in Smart Homes: Assessment and Future Perspectives

SV2G-ET: A Secure Vehicle-to-Grid Energy Trading Scheme Using Deep Reinforcement Learning

Machine Learning for Sensorless Temperature Estimation of a BLDC Motor

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