Deep Learning Based Muti-Objective Reactive Power Optimization of Distribution Network with PV and EVs

Wu, Renbo; Li, Shuqin

doi:10.3390/s22124321

Cited by 7 publications

(5 citation statements)

References 35 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In [77], the authors used both computational intelligence methods and analytical methods. In [55], five multi-objective evolution algorithms (MOEAs), named promising-region-based evolutionary many-objective algorithm (PREA), strength Pareto evolutionary algorithm 2 (SPEA 2), nondominated sorting genetic algorithm II (NSGA-II), nondominated sorting genetic algorithm III (NSGA-III), and two-phase framework (ToP), are used to determine the reactive power capacity of PVs and EVs. The results obtained by MOEAs are used to train a deep deconvolution neural network (DDNN) to solve the problem of voltage deviation and loss minimization.…”

Section: Computational Intelligence Methodsmentioning

confidence: 99%

“…In addition to voltage optimization, the following objectives also appear: (i) power loss minimization [53][54][55], (ii) on load tap changer (OLTC) switching operation minimization [56], (iii) PV cost minimization [38], (iv) reactive power injection/absorption minimization [57], (v) active power curtailment (APC) minimization [58], (vi) cost of purchased energy minimization [59], (vii) peak shaving minimization [59], and (viii) security margin index (SMI) minimization [59]. The mathematical expressions of the commonly used objectives are given in Table 2.…”

Section: General Formulation-objectives and Variablesmentioning

confidence: 99%

“…Objectives Variables [65] single-objective min VD PV inverter reactive power, OLTC [38] multi-objective min losses, min VD, min VUF, min PV generation cost, min PV APC cost PV inverter reactive power [66] multi-objective min losses, min VD, improvement VSI PV inverter reactive power and static compensator [53,54,[67][68][69] multi-objective min losses, min VD PV inverter reactive power [70] multi-objective min VD, min losses PV inverter reactive power, CBs, and OLTC [71] single-objective min VUF PV inverter active and reactive power, power injected by TS [72] single-objective min VD PV inverter reactive power [73] multi-objective min losses, min cost of APC and generated/consumed reactive power, min VD PV inverter reactive power [74] multi-objective min VD, min voltage unbalance PV inverter reactive power, OLTC, VR, and CB [75] multi-objective min losses, min VD, min VUF PV inverter reactive power [32] single-objective min VUF PV inverter reactive power [76] single-objective min VD PV inverter reactive power, OLTC [77] multi-objective min losses, min VD, min control action of OLTC and SC PV inverter reactive power, OLTC, SC [78] single-objective min VD PV inverter reactive power, OLTC [79] multi-objective min VD, min losses PV inverter reactive power, OLTC, and SC [57] multi-objective min VD, min losses, min reactive power injection, and absorption PV inverter reactive power [80] multi-objective min VD, min losses PV inverter reactive power, OLTC [81] single-objective min VD PV inverter reactive power, OLTC, and VR [58] multi-objective min VD, min losses, min APC PV inverter reactive power, OLTC and CB [55] multi-objective min VD, min losses PV and EV inverter reactive power, the compensation device [56] multi-objective min VD, min OLTC tap operation PV inverter reactive power, OLTC [82] single-objective min VD PV inverter reactive power, charge/discharge rate of ESS [83] multi-objective min losses, min VUF PV inverter reactive power [34] multi-objective min cost, min losses, min cost associated with active power s...…”

Section: Reference Single/ Multi-objectivementioning

confidence: 99%

See 2 more Smart Citations

Voltage Optimization in PV-Rich Distribution Networks—A Review

et al. 2022

View full text Add to dashboard Cite

There is a rising trend to integrate different types of distributed generation (DG), especially photovoltaic (PV) systems, on the roofs of existing consumers, who then become prosumers. One of the prosumer impacts is voltage violations, which conventional strategies find hard to solve. However, some prosumers, such as those with PV with inverters in their configurations, can actively participate in voltage optimization. To help find the optimal PV inverter setting with the objective of voltage optimization, an optimal power flow (OPF) can be a promising and reliable tool. This paper tries to shed light on the complex problem of voltage optimization in distribution networks (DNs) with PV prosumers. Relevant scientific papers are analyzed and optimization characteristics such as objective functions, variables, and constraints are summarized. Special attention is given to the systematization and classification of papers according to the mathematical formulation of the optimization problem (linear, nonlinear, integer, etc.) and the applied solving methods. Both analytical and computational intelligence optimization methods as well as their advantages and limitations are considered. Papers are also categorized according to the distribution network model used for testing the developed solutions.

show abstract

Section: Computational Intelligence Methodsmentioning

confidence: 99%

Section: General Formulation-objectives and Variablesmentioning

confidence: 99%

Section: Reference Single/ Multi-objectivementioning

confidence: 99%

See 1 more Smart Citation

Voltage Optimization in PV-Rich Distribution Networks—A Review

et al. 2022

View full text Add to dashboard Cite

show abstract

“…The algorithm's effectiveness is demonstrated through a case study on the South Korean distribution system, confirming significant improvement in system performance through optimized smart inverter settings. The author in [81] addresses the challenges of increased line losses and voltage deviations in distribution networks due to high PV and EV penetration. The study proposes new reactive power regulation methods, utilizing the potential of PVs and EVs, to alleviate these challenges.…”

Section: Control and Optimization Integrationmentioning

confidence: 99%

Voltage Optimization in Active Distribution Networks—Utilizing Analytical and Computational Approaches in High Renewable Energy Penetration Environments

Alshehri,

Yang

2024

Energies

View full text Add to dashboard Cite

This review paper synthesizes the recent advancements in voltage regulation techniques for active distribution networks (ADNs), particularly in contexts with high renewable energy source (RES) penetration, using photovoltaics (PVs) as a highlighted example. It covers a comprehensive analysis of various innovative strategies and optimization algorithms aimed at mitigating voltage fluctuations, optimizing network performance, and integrating smart technologies like smart inverters and energy storage systems (ESSs). The review highlights key developments in decentralized control algorithms, multi-objective optimization techniques, and the integration of advanced technologies such as soft open points (SOPs) to enhance grid stability and efficiency. The paper categorizes these strategies into two main types: analytical methods and computational methods. In conclusion, this review underscores the critical need for advanced analytical and computational methods in the voltage regulation of ADNs with high renewable energy penetration levels, highlighting the potential for significant improvements in grid stability and efficiency.

show abstract

“…Among the suggested solutions, some are based on the usage of electrical storage [ 1 , 2 , 3 , 4 ], and some of them apply power flow dispatch at generating facilities [ 5 , 6 ]. Other solutions are based on the utilization of reactive power equipment [ 7 , 8 , 9 , 10 , 11 , 12 , 13 , 14 ]. Considering the influence of the high costs of high-voltage storage, reactive power usage as the voltage regulation model may be preferable among other methods.…”

Section: Introductionmentioning

confidence: 99%

The Actual Exactness of a Fast RMS Correction during Abrupt Voltage Change

Danin

Amiel

Miteva

et al. 2023

Sensors

View full text Add to dashboard Cite

The requirement of RMS (voltage and current) measurements under a fraction of the AC period has become increasingly attractive in power systems. Some of these power applications are responsible for voltage stabilization in distribution lines when the voltage correction should be made in a short time, no more than one or two periods of the AC signal. Previously developed RMS correction applications must be validated in real-world situations characterized by an abrupt change (discontinuity) in voltage magnitude occurring even during a single AC period. Such circumstances can substantially influence the RMS estimation and, therefore, should be considered. This article suggests a mathematically based approach, validated in the laboratory, that improves the accuracy of a voltage RMS estimation for the appropriate measurement devices. It produces better results in cases where the RMS assessment should be done in a fraction of the AC period.

show abstract

Deep Learning Based Muti-Objective Reactive Power Optimization of Distribution Network with PV and EVs

Cited by 7 publications

References 35 publications

Voltage Optimization in PV-Rich Distribution Networks—A Review

Voltage Optimization in PV-Rich Distribution Networks—A Review

Voltage Optimization in Active Distribution Networks—Utilizing Analytical and Computational Approaches in High Renewable Energy Penetration Environments

The Actual Exactness of a Fast RMS Correction during Abrupt Voltage Change

Contact Info

Product

Resources

About