Multi-Objective Optimal Control Approach for Static Voltage Stability of Power System Considering Interval Uncertainty of the Wind Farm Output

Yang, Yuerong; Lin, Shian-Ru; Wang, Qiong; Xie, Yuquan; Liu, Mingbo

doi:10.1109/access.2020.3002931

Cited by 8 publications

(4 citation statements)

References 27 publications

(59 reference statements)

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“…A voltage stability index is presented in [35] based on the P-V curve, where the voltage stability index is computed in terms of the distance between the operating point and saddle point on the P-V curve. A control model for static voltage stability considering the interval uncertainty of wind power output is suggested by [36], where the objective functions are to increase the central value and decrease the fluctuation range. Based on the models presented in the literature, the VSM in scenario 𝑠 for a given investment plan can be computed as follows:…”

Section: A Voltage Stability Margin Evaluationmentioning

confidence: 99%

A Joint Optimization Model for Transmission Capacity and Wind Power Investment Considering System Security

et al. 2023

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Due to continuous growth in electric demand and increasing connection of renewable energy, the power systems are being operated with smaller stability margins. Therefore, a sufficient loading margin is essential to maintain the system secure and ensure voltage stability. To this end, this paper studies the joint optimization of transmission capacity and wind power investment problem, the unique feature of which is incorporating voltage stability margin (VSM) in the planning model. A bi-level model has been formulated whose upper level minimizes the total investment and operation cost minus the weighted VSM. The lower level evaluates the VSM given the optimal expansion plan from the upper level. In addition, the stochastic nature of wind power and load can impact voltage stability. Thus, uncertainties related to intermittent wind generation and demand must be modeled. We use an approximated linear representation to model the AC power system at both levels of the problem. The duality theory (primal-dual formulation) is utilized to transform bi-level programming into single-level mathematical programming. The validity of the constructed methodology is demonstrated on the IEEE 24-bus RTS, which indicates the efficacy and feasibility of the presented model. INDEX TERMSBi-level programming, Primal-dual formulation, Transmission and wind investment, Voltage stability. NOMENCLATURE A. Indices and sets: Ω Set of buses indexed by 𝑖, 𝑗. Ω Set of scenarios indexed by s. B. Parameters: 𝑔 , 𝑏 Conductance and susceptance of a transmission line. 𝐴 , 𝐵 , 𝐶 Constant parameters used to approximate a circle by a regular polygon. 𝑎 , 𝑏 , 𝑐 Production cost coefficients of a thermal unit. 𝐼 ,𝐼 Annualized investment cost of a wind farm and a transmission line. 𝑀 , 𝑀 , 𝑀 , 𝑀 Big-M parameters. 𝑃 Active power demand. 𝑄 , 𝑄 , 𝑄 Reactive power generation of thermal units in the main problem, VSM assessment problem and OPF problem. 𝑃 , 𝑃 , 𝑃 Active power generation of wind farms in the main problem, VSM assessment problem and OPF problem. 𝑄 , 𝑄 𝑄 Reactive power generation of wind farms in the main problem, VSM assessment problem and OPF problem. 𝑃 Capacity of a wind farm. 𝑢 Binary variable indicating the installation status of a transmission line. ∆𝑣 , ∆𝑣 , ∆𝑣 Voltage deviation in the main problem, VSM assessment problem and OPF problem. 𝛿 ,𝛿 𝛿 Voltage angle in the main problem, VSM assessment problem and OPF problem. 𝛿 , Voltage angle at the reference bus.

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Section: A Voltage Stability Margin Evaluationmentioning

confidence: 99%

A Joint Optimization Model for Transmission Capacity and Wind Power Investment Considering System Security

et al. 2023

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“…where L mi , 𝜇 mi and 𝜎 2 mi need to be obtained by continuous power flow calculation (CPF) as the limit operating values of the system, and the details can be found in literature [44].…”

Section: (7) System Voltage Collapse Riskmentioning

confidence: 99%

“…The probability of collapse is calculated by the load margin

M_{i}=L_{\mathrm{m}i}-L_i

. With the consideration of the fluctuations of load and wind power,

M_i

also satisfies the normal distribution as:

\begin{equation} M_i \sim N{\big(\mu _{\mathrm{m} i}, \sigma _{\mathrm{m} i}^2\big)}, \end{equation}

where

L_{\mathrm{m}i}

\mu _{\mathrm{m} i}

and

\sigma _{\mathrm{m} i}^2

need to be obtained by continuous power flow calculation (CPF) as the limit operating values of the system, and the details can be found in literature [44].…”

Section: The Model Of Power System Optimizationmentioning

confidence: 99%

Probability confidence correlation analysis for many‐objective optimal operation considering a set of conflict interests

Zheng,

Guo,

et al. 2023

IET Renewable Power Gen

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As the proportion of renewable energy penetrated in power systems further increases, the optimal operation faces a large obstacle to satisfying various conflict interests simultaneously. This paper first formulates a many‐objective optimal operation problem of the new power system considering a comprehensive set of economic, environmental, and reliable objectives. To figure out this problem efficiently, this paper proposes a probability confidence correlation analysis method (PCCA) utilizing a t‐distributed stochastic neighbor embedding (T‐SNE) standard to greatly preserve the distribution information and separability of the objectives. Consequently, the objectives can be aggregated and the objective dimension is reduced based on the important sorting and correlation of the objectives. Based on the outcome of the T‐SNE, the adopted optimal operation problem with low dimensional objectives is solved by a multiple producer group search optimizer (GSOMP) with less computation burden, to obtain the Pareto‐optimal solution set. Simulation studies are conducted on IEEE 30‐bus, 39‐bus and 57‐bus systems to investigate the performance of the proposed PCCA in terms of efficiency and accuracy, making comparisons of the existing many‐objective optimization algorithms.

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“…To mitigate this deficiency, coordinated secondary voltage control (CSVC) has been applied in power systems [21]. The CSVC, which has been introduced by J.P. Paul et al [22], aims to increase voltage stability in highly constrained areas [23]. Consequently, the CSVC can regulate the free variables of the reactive power flow [24].…”

Section: Introductionmentioning

confidence: 99%

Coordinated Complex-Valued Encoding Dragonfly Algorithm and Artificial Emotional Reinforcement Learning for Coordinated Secondary Voltage Control and Automatic Voltage Regulation in Multi-Generator Power Systems

et al. 2020

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This paper proposes a coordinated optimization and control algorithm for coordinated secondary voltage control (CSVC) in multi-generator power systems. Firstly, to obtain a smaller voltage deviation and avoid the curse of dimensionality simultaneously, an artificial emotional reinforcement learning (AERL) is applied to automatic voltage regulation (AVR). Secondly, to obtain a smaller fitness value with lesser random for the decentralized independent variables optimization problem of the CSVC, a complex-valued encoding dragonfly algorithm (CDA) is proposed. Thirdly, the CDA and the AERL are coordinated for the CSVC and the AVR in multi-generator power systems. To verify the control performance of the AERL and the convergence of the proposed CDA, three simulation cases, i.e., IEEE 57-bus, 118-bus and 300-bus systems, are considered. The simulation results show that the CDA-AERL effectively obtains the smallest control objectives and the convergence for the CSVC in multi-generator power systems.INDEX TERMS Coordinated secondary voltage control; artificial emotional reinforcement learning; complex-valued encoding dragonfly algorithm; automatic voltage regulation; multi-generator power systems.

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Multi-Objective Optimal Control Approach for Static Voltage Stability of Power System Considering Interval Uncertainty of the Wind Farm Output

Cited by 8 publications

References 27 publications

A Joint Optimization Model for Transmission Capacity and Wind Power Investment Considering System Security

A Joint Optimization Model for Transmission Capacity and Wind Power Investment Considering System Security

Probability confidence correlation analysis for many‐objective optimal operation considering a set of conflict interests

Coordinated Complex-Valued Encoding Dragonfly Algorithm and Artificial Emotional Reinforcement Learning for Coordinated Secondary Voltage Control and Automatic Voltage Regulation in Multi-Generator Power Systems

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