Fast Decoupled State Estimation for Distribution Networks Considering Branch Ampere Measurements

Ju, Yuntao; Wu, Wenchuan; Ge, Fuchao; Ma, Kang; Lin, Yi; Yang, Lin

doi:10.1109/tsg.2017.2709463

Cited by 21 publications

(14 citation statements)

References 38 publications

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“…Taking into consideration the narrow voltage regulation range, it is crucial to accurately measure the line voltages for efficient and reliable control. Most WLS-based SE assume that loads are concentered on nodes and the magnitudes of loads are known [9][10][11][12]. However, the actual loads are not concentered on nodes but distributed in sections.…”

Section: Voltage Measurement Methods and The Importance Of Its Accuracymentioning

confidence: 99%

“…where , is the initial section load center between node n and n + 1. is the + of the node n, and ST denotes each section type. In Equation (8), the constant term except on the right side is equal to the initial voltage estimate of the node m. Accordingly, if all the values except are put from the right side to the left side, an estimation error is obtained, as expressed in Equation (9). If Equation 9is arranged with respect to α , the section load center can be expressed by using Equation (10).…”

Section: Step 2: Calculation Of Correction Parameter Of the Section Lmentioning

confidence: 99%

See 1 more Smart Citation

Voltage Estimation Method for Power Distribution Networks Using High-Precision Measurements

Choi

et al. 2020

Energies

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In this study, we propose a voltage estimation method for the radial distribution network with distributed generators (DGs) using high-precision measurements (HPMs). The proposed method uses the section loads center for voltage estimation because individual loads are not measured in the distribution system. The bus voltage was estimated through correction of the section load center by using an HPM at the end of the main feeder. The correction parameter of the section load center was calculated by comparing the initial voltage estimates and the measurements of the HPMs. After that, the voltage of the main feeder was re-estimated. Finally, the bus voltage in the lateral feeder was estimated based on the voltage estimates in the main feeder and the current measurements in the lateral feeder. The accuracy of the proposed algorithm was verified through case studies by using test systems implemented in MATLAB, Simulink, and Python environments. In order to verify the utilization of the proposed method to the practical system, a test with injection of approximately 5% of normally distributed random noise was performed. Through the results of the case studies, when an HPM is installed at the end of the main feeder, it demonstrated that the voltage estimation accuracy can be greatly improved by the proposed method. Compared with the existing methods, the proposed method was less affected by PV and showed robustness to measurement noise.

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Section: Voltage Measurement Methods and The Importance Of Its Accuracymentioning

confidence: 99%

Section: Step 2: Calculation Of Correction Parameter Of the Section Lmentioning

confidence: 99%

Voltage Estimation Method for Power Distribution Networks Using High-Precision Measurements

Choi

et al. 2020

Energies

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“…Accurate state estimation (SE) of interconnected power systems is critical for assessing system security and optimizing performances. [1], [2]. This becomes particularly challenging for continental-scale power systems that rely on the coordination of multiple dispatch centers, while each one of the dispatch centers controls a large-scale region.…”

Section: Introduction a Motivationmentioning

confidence: 99%

A Fully Distributed Coordination Method for Fast Decoupled Multi-Region State Estimation

et al. 2019

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Distributed state estimation (DSE) is effective for the analysis of multi-region state estimation problems, avoiding integrating complicated data sets and models. In this work, the peer-to-peer decomposition of the Karush-Kuhn-Tucker (KKT) condition is applied to formulate the fully distributed fast decoupled state estimation (FD2SE) algorithm. Then, a fixed-matrix form data-exchanging interface incorporating the fast decoupled algorithm is designed, reducing the communication costs and allowing it to be used for various system operating conditions. Further, a convergence detecting method for dispatch centers is proposed in order to infer, locally and asynchronously, about the global convergence. Case studies carried out on IEEE systems and a real power grid of China verify the accuracy and efficiency of the FD2SE algorithm. INDEX TERMS Fully distributed state estimation, data-exchanging interface, asynchronous convergence detecting.

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“…In [26], a new FDSE is presented by the rotation transformation, this method is suitable for networks with a high ratio of R / X , but the rotation transformation will greatly reduce the accuracy and efficiency of calculation, and rotated measurements do not include BCMMs still. Recently, a new FDSE for distribution systems is proposed in [27], the advantage of this method is that BCMMs can be used in FDSE by approximately reformulating BCMMs as active and reactive branch loss measurements; the drawback is that the computational efficiency has been affected by additional state variables, and the applicability of this approach to distribution systems with high ratio of R / X has not been discussed.…”

Section: Introductionmentioning

confidence: 99%

Generalised‐fast decoupled state estimator

Chen

Zhou

Fang³

et al. 2018

IET Generation, Transmission & Distribution

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Fast Decoupled State Estimation for Distribution Networks Considering Branch Ampere Measurements

Cited by 21 publications

References 38 publications

Voltage Estimation Method for Power Distribution Networks Using High-Precision Measurements

Voltage Estimation Method for Power Distribution Networks Using High-Precision Measurements

A Fully Distributed Coordination Method for Fast Decoupled Multi-Region State Estimation

Generalised‐fast decoupled state estimator

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