Power Grid Line Breaking Identification Method Based on Parallel Power Flow Figure Using Deep Learning

The electricity tariffs available to customers in Poland depend on the connection voltage level and contracted capacity, which reflect the customer demand profile. Therefore, before connecting to the power grid, each consumer declares the demand for maximum power. This amount, referred to as the contracted capacity, is used by the electricity provider to assign the proper connection type to the power grid, including the size of the security breaker. Maximum power is also the basis for calculating fixed charges for electricity consumption, which is controlled and metered through peak meters. If the peak demand exceeds the contracted capacity, a penalty charge is applied to the exceeded amount, which is up to ten times the basic rate. In this article, we present several solutions for entrepreneurs based on the implementation of two-stage and deep learning approaches to predict maximal load values and the moments of exceeding the contracted capacity in the short term, i.e., up to one month ahead. The forecast is further used to optimize the capacity volume to be contracted in the following month to minimize network charge for exceeding the contracted level. As confirmed experimentally with two datasets, the application of a multiple output forecast artificial neural network model and a genetic algorithm (two-stage approach) for load optimization delivers significant benefits to customers. As an alternative, the same benefit is delivered with a deep learning architecture (hybrid approach) to predict the maximal capacity demands and, simultaneously, to determine the optimal capacity contract.

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A Tale of Two Entities

ACM Transactions on Internet of Things ◽

10.1145/3437258 ◽

2021 ◽

Vol 2 (2) ◽

pp. 1-21

Author(s):

Hossam ElHussini ◽

Chadi Assi ◽

Bassam Moussa ◽

Ribal Atallah ◽

Ali Ghrayeb

Keyword(s):

Power Flow ◽

Power Grid ◽

Communication Protocols ◽

Charging Infrastructure ◽

Electric Vehicle Charging ◽

Public Data ◽

Simulation Based ◽

Charging Stations ◽

The Impact ◽

Ev Charging

With the growing market of Electric Vehicles (EV), the procurement of their charging infrastructure plays a crucial role in their adoption. Within the revolution of Internet of Things, the EV charging infrastructure is getting on board with the introduction of smart Electric Vehicle Charging Stations (EVCS), a myriad set of communication protocols, and different entities. We provide in this article an overview of this infrastructure detailing the participating entities and the communication protocols. Further, we contextualize the current deployment of EVCSs through the use of available public data. In the light of such a survey, we identify two key concerns, the lack of standardization and multiple points of failures, which renders the current deployment of EV charging infrastructure vulnerable to an array of different attacks. Moreover, we propose a novel attack scenario that exploits the unique characteristics of the EVCSs and their protocol (such as high power wattage and support for reverse power flow) to cause disturbances to the power grid. We investigate three different attack variations; sudden surge in power demand, sudden surge in power supply, and a switching attack. To support our claims, we showcase using a real-world example how an adversary can compromise an EVCS and create a traffic bottleneck by tampering with the charging schedules of EVs. Further, we perform a simulation-based study of the impact of our proposed attack variations on the WSCC 9 bus system. Our simulations show that an adversary can cause devastating effects on the power grid, which might result in blackout and cascading failure by comprising a small number of EVCSs.

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Research on Breaking Power Flow Algorithm of Offshore Platform Power Grid Based on Parameter Sensitivity

2020 IEEE 4th Conference on Energy Internet and Energy System Integration (EI2) ◽

10.1109/ei250167.2020.9346626 ◽

2020 ◽

Author(s):

Yansong Wang ◽

Dezhi Xuan ◽

Qiang Li

Keyword(s):

Power Flow ◽

Power Grid ◽

Parameter Sensitivity ◽

Offshore Platform ◽

Flow Algorithm ◽

Grid Based

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Predicting AC Optimal Power Flows: Combining Deep Learning and Lagrangian Dual Methods

Proceedings of the AAAI Conference on Artificial Intelligence ◽

10.1609/aaai.v34i01.5403 ◽

2020 ◽

Vol 34 (01) ◽

pp. 630-637 ◽

Cited By ~ 2

Author(s):

Ferdinando Fioretto ◽

Terrence W.K. Mak ◽

Pascal Van Hentenryck

Keyword(s):

Deep Learning ◽

Power Systems ◽

Power Flow ◽

Optimal Power Flow ◽

Large Scale ◽

Renewable Energy Sources ◽

Electrical Power ◽

Practical Applications ◽

Fundamental Building Block ◽

Optimal Power

The Optimal Power Flow (OPF) problem is a fundamental building block for the optimization of electrical power systems. It is nonlinear and nonconvex and computes the generator setpoints for power and voltage, given a set of load demands. It is often solved repeatedly under various conditions, either in real-time or in large-scale studies. This need is further exacerbated by the increasing stochasticity of power systems due to renewable energy sources in front and behind the meter. To address these challenges, this paper presents a deep learning approach to the OPF. The learning model exploits the information available in the similar states of the system (which is commonly available in practical applications), as well as a dual Lagrangian method to satisfy the physical and engineering constraints present in the OPF. The proposed model is evaluated on a large collection of realistic medium-sized power systems. The experimental results show that its predictions are highly accurate with average errors as low as 0.2%. Additionally, the proposed approach is shown to improve the accuracy of the widely adopted linear DC approximation by at least two orders of magnitude.

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