760 results
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2. Eigenvalue Based Stability Analysis for Asymmetric Complex Dynamical Networks
- Author
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Chen, Zengqiang, Xiang, Linying, Liu, Zhongxin, Yuan, Zhuzhi, Chang, Kai, Akan, Ozgur, Series editor, Bellavista, Paolo, Series editor, Cao, Jiannong, Series editor, Dressler, Falko, Series editor, Ferrari, Domenico, Series editor, Gerla, Mario, Series editor, Kobayashi, Hisashi, Series editor, Palazzo, Sergio, Series editor, Sahni, Sartaj, Series editor, Shen, Xuemin (Sherman), Series editor, Stan, Mircea, Series editor, Xiaohua, Jia, Series editor, Zomaya, Albert, Series editor, Coulson, Geoffrey, Series editor, and Zhou, Jie, editor
- Published
- 2009
- Full Text
- View/download PDF
3. Stability of Non-diagonalizable Networks: Eigenvalue Analysis
- Author
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Xiang, Linying, Chen, Zengqiang, Zhu, Jonathan J. H., Akan, Ozgur, Series editor, Bellavista, Paolo, Series editor, Cao, Jiannong, Series editor, Dressler, Falko, Series editor, Ferrari, Domenico, Series editor, Gerla, Mario, Series editor, Kobayashi, Hisashi, Series editor, Palazzo, Sergio, Series editor, Sahni, Sartaj, Series editor, Shen, Xuemin (Sherman), Series editor, Stan, Mircea, Series editor, Xiaohua, Jia, Series editor, Zomaya, Albert, Series editor, Coulson, Geoffrey, Series editor, and Zhou, Jie, editor
- Published
- 2009
- Full Text
- View/download PDF
4. Gaussian quantum particle swarm optimization-based wide-area power system stabilizer for damping inter-area oscillations
- Author
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Kondattu Mony, Sreedivya, Peter, Aruna Jeyanthy, and Durairaj, Devaraj
- Published
- 2023
- Full Text
- View/download PDF
5. A THEORETICAL STUDY OF PAPER FLUTTER
- Author
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Y. Watanabe, M. Sugihara, S. Suzuki, and K. Isogai
- Subjects
Physics::Fluid Dynamics ,Airfoil ,Paper sheet ,Amplitude ,Eigenvalue analysis ,Mechanical Engineering ,Flutter ,Geometry ,Potential flow ,Mechanics ,Stability (probability) ,Mathematics ,Parametric statistics - Abstract
Two different methods of analysis were developed in order to clarify the phenomenon of paper flutter. One of these is a flutter simulation using a Navier–Stokes code (N–S simulation). N–S simulation was used to determine the unsteady lift force, the amplitude of flutter, and the air-flow around a paper sheet, by means of a time-marching scheme. The other form of analysis is based on a potential-flow analysis of an oscillating thin airfoil via an eigenvalue analysis for determining stability. The flutter speeds and flutter modes obtained by each method are consistent. Aspects of the behavior of paper flutter that had not been clarified in the experimental analysis were clarified by potential flow analysis. From the results of this study, it was shown that potential flow analysis is very convenient and adequate for a parametric study of this problem.
- Published
- 2002
6. Wire-Screen Belt Vibrations in a Fourdrinier Paper Machine
- Subjects
Wire-Screen Belt ,Fourdrinier Paper ,Machine ,Eigenvalue Analysis ,Self-Excited Vibration ,Vibration Coupled with Fluid Motion ,Vibration of Moving Body ,Stability - Abstract
In a Fourdrinier paper machine, the fiber and water mixture flows to a wire-screen belt. As the wire-screen belt travels horizontally, water is drained through the screen, leaving the fibers on top. In some operating conditions large vertical vibrations of the wire-screen belt occur. The mechanism of this phenomenon is investigated experimentally. Analytical study is also done, which shows qualitative agreement with the experiment results. Consequently, the screen vibration is self-excited vibration due to the pressure variation of the water on the wire screen belt.
- Published
- 1998
7. Analysis of Low-Frequency Oscillations in the Bosnia and Herzegovina Power System.
- Author
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Dedović, Maja Muftić, Avdaković, Samir, Alihodžić, Ajdin, and Memić, Adin
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WIND power plants ,ELECTRIC power systems ,WIND power ,OSCILLATIONS ,RENEWABLE energy sources ,DYNAMICAL systems - Abstract
This paper presents a detailed model of low-frequency oscillations and their damping within the Electric Power System (EPS) of Bosnia and Herzegovina (B&H). The system is modeled using MATLAB software, analysing the steady state and dynamic responses. This research highlights the challenges and impacts of integrating renewable energy sources, such as wind farms, on grid stability and oscillation damping. The paper utilizes eigenvalue analysis to investigate the dynamic characteristics of the system, emphasizing the need for efficient damping strategies to maintain system stability. The methodology includes a comprehensive review of existing literature, the creation of a detailed EPS model of B&H, and the application of eigenvalue and oscillation amplitude analysis to determine damping ratios. The dynamic responses of hydro power plants, HPP Mostar and HPP Jablanica, to transient disturbances are analysed to validate the model and refine damping strategies. The results indicate that the B&H EPS is well-damped, with all eigenvalues possessing negative real parts, and demonstrate the system's resilience to small disturbances. The results are compared with the technical report on the integration of the wind power plant WPP Podveležje. This comparative analysis shows consistent patterns between the modeled calculations and empirical data, confirming the robustness of the EPS model. This alignment underscores the effectiveness of current damping mechanisms and provides a foundational strategy for enhancing system stability with increasing renewable energy penetration. The findings highlight the importance of developing advanced control strategies to sustain system stability as the integration of variable renewable energy sources continues to grow. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
8. Eigenvalue Analysis of Oscillatory Variable State Paper Winder
- Author
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Erno Keskinen and Sirpa Launis
- Subjects
Physics ,Stress (mechanics) ,Eigenvalue analysis ,Mathematical analysis ,medicine ,Stiffness ,State (functional analysis) ,medicine.symptom ,Resonance (particle physics) ,Eigenvalues and eigenvectors ,Variable (mathematics) - Abstract
Winding is a paper finishing process, in which the full paper web is longitudinally cut and wound in narrower paper rolls to fit later to printing machines. The quality of the paper roll is measured in terms of uniform roundness and axially symmetric internal stress and stiffness distribution. Unfortunately dynamic effects disturb winding process so that out-of-roundness shape error profiles may accumulate to the rolls. The reason for this phenomenon is mechanical oscillation, in which the set of rolls and the three winding drums are in relative motion in normal direction of their rolling contact plane. The time evolution of this process is extremely complicated since the roll size as well as contact conditions and running frequencies are changing during the complete process. To avoid unwanted resonance crossings the system eigenstates have to be as first step analyzed and compared with the roll speed harmonics at each roll diameter. This analysis is carried out using linearized spring-mass model, whose parameters are updated according to the roll growth. The spring elements represent the local stiffnesses of roll-drum contacts in both normal and tangential directions, the effect of latter ones being actually a novel element introduced in this analysis.
- Published
- 2001
9. Methodology for predicting brake squeal propensity using complex eigenvalue analysis, including thermo-mechanical effects
- Author
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M Tirovic, Paul Bannister, and Michele Vianello
- Subjects
0209 industrial biotechnology ,Digital image correlation ,eigenvalue analysis ,business.industry ,Computer science ,Mechanical Engineering ,Aerospace Engineering ,Noise, vibration, and harshness ,02 engineering and technology ,Structural engineering ,020303 mechanical engineering & transports ,020901 industrial engineering & automation ,0203 mechanical engineering ,Eigenvalue analysis ,Brake ,Brake squeal ,digital image correlation ,natural frequencies ,thermal effects ,business ,Thermo mechanical ,pressure sensitive paper - Abstract
With brake squeal being the most prevalent noise vibration and harshness issue in modern vehicles, this paper presents an improved methodology for brake squeal propensity prediction at the design stage. The research established four clearly defined ‘Stages’ in conducting finite element squeal analyses, describing crucial input data, modelling procedures, output and validation results. Stage 1 deals with free-free modal characteristics of individual brake components and their material characteristics. Stage 2 combines individual parts, conducting brake assembly mechanical finite element analyses. Stage 3 concentrates on fully coupled thermo-mechanical finite element analyses, and the concluding stage, Stage 4, focuses on brake assembly stability analyses. Validations proved that very accurate predictions are possible, but the geometries, material characteristics and established modelling procedures must be strictly followed. Material characteristics were most prone to introduce discrepancies with measured values. ‘Generic’ values are found to be unacceptable and conducting own measurements was necessary, in particular for the friction material, whose anisotropic properties have been measured in detail, leading to high accuracy in predicting pad natural modes and frequencies. In Stage 4, the stability analyses of the full brake assembly were based on the complex eigenvalue analysis (which included thermal aspects), with the sign of the real part giving an indication of stability and the imaginary part defining the frequency of the unstable mode. Instabilities and frequencies predicted match well with the values measured in dynamometer tests, clearly demonstrating the influence of thermal effects. The final output of the procedures described in this paper is a validated three dimensional thermo-mechanical finite element noise vibration and harshness brake assembly model in which natural frequencies and modes, instabilities and contributing factors can be predicted at any time during a brake application.
- Published
- 2018
10. A new transmission‐line model for time‐domain implementation
- Author
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Wilcox, D.J. and Condon, M.
- Published
- 1997
- Full Text
- View/download PDF
11. Stability Analysis in Multi-VSC (Voltage Source Converter) Systems of Wind Turbines.
- Author
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Dimitropoulos, Dimitrios, Wang, Xiongfei, and Blaabjerg, Frede
- Subjects
WIND turbines ,IDEAL sources (Electric circuits) ,TIME delay systems ,WIND energy conversion systems ,WIND power plants ,NUMBER systems - Abstract
In this paper, a holistic nonlinear state-space model of a system with multiple converters is developed, where the converters correspond to the wind turbines in a wind farm and are equipped with grid-following control. A novel generalized methodology is developed, based on the number of the system's converters, to compute the equilibrium points around which the model is linearized. This is a more solid approach compared with selecting operating points for linearizing the model or utilizing EMT simulation tools to estimate the system's steady state. The dynamics of both the inner and outer control loops of the power converters are included, as well as the dynamics of the electrical elements of the system and the digital time delay, in order to study the dynamic issues in both high- and low-frequency ranges. The system's stability is assessed through an eigenvalue-based stability analysis. A participation factor analysis is also used to give an insight into the interactions caused by the control topology of the converters. Time domain simulations and the corresponding frequency analysis are performed in order to validate the model for all the control interactions under study. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
12. Analysis of Grid-Connected Stability of VSG-Controlled PV Plant Integrated with Energy Storage System and Optimization of Control Parameters.
- Author
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Chen, Qian, Zhu, Bing, Liu, Muyang, and Mao, Shanxiang
- Subjects
ENERGY storage ,MATHEMATICAL optimization ,BATTERY storage plants ,SYNCHRONOUS generators ,PARTICLE swarm optimization ,PARTICLE tracks (Nuclear physics) - Abstract
In the static stability analysis of the grid-connected photovoltaic (PV) generation and energy storage (ES) system, the grid-side is often simplified using an infinite busbar equivalent, which streamlines the analysis but neglects the dynamic characteristics of the grid, leading to certain inaccuracies in the results. Furthermore, the control parameter design does not consider the coupling relationships among parameters, resulting in arbitrary values and the inability to achieve overall optimality. To address these issues, this paper presents a comprehensive parameter optimization method for the oscillation characteristics of grid-connected PV generation and ES systems in various frequency ranges. Firstly, a detailed modeling of the grid-connected PV generation and ES system is conducted, resulting in the derivation of the system's small-signal model. This study investigates the impact of parameters related to PV arrays, ES units, and the virtual synchronous generator (VSG) on the system's characteristic roots using participation factors, sensitivity analysis, and eigenvalue root trajectories. Subsequently, based on the analysis of system root trajectories and the Particle Swarm Optimization (PSO) algorithm, a holistic parameter optimization design method for the system's oscillation modes is proposed, and the parameter optimization results are obtained. Finally, the accuracy of the theoretical analysis is validated through perturbation testing using both Matlab/Simulink models and the small-signal model. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
13. Stability Analysis of Inverse Lax-Wendroff Procedure for a High order Compact Finite Difference Schemes
- Author
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Li, Tingting, Lu, Jianfang, and Wang, Pengde
- Published
- 2024
- Full Text
- View/download PDF
14. Generalized eigenvalue formulation of the helmholtz equation by the trefftz method
- Author
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Kamiya, N. and Wu, S.T.
- Published
- 1994
- Full Text
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15. An approach on nonlinear integration of MMC to linear model of ROPS in transient analysis.
- Author
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Shivashanker, K. and Janaki, M.
- Subjects
- *
TRANSIENT analysis , *TURBINE generators , *PULSE width modulation , *EIGENVALUES , *COINTEGRATION , *MATHEMATICAL models - Abstract
Summary: The modular multilevel converter (MMC) is a novel prospective multilevel converter topology for high‐voltage or high‐power applications. This paper presents the 3‐ Φ model integrated into a linear model in transient analysis and the design of current controller for MMC. This paper analyzes the control interactions of MMC on nearby turbine generator. The eigenvalue analysis is used to evaluate the impact of different controller modes of MMC. The impact of converter control with nonlinear switches is analyzed through the transient simulation. The eigenvalue analysis and controller design are carried out on a linear model, and the transient simulation analysis is performed on both the D‐Q model and a three‐phase model of MMC using MATLAB‐Simulink. The results show that the transient simulation of three‐phase model on the proposed approach is consistent with the transient simulation of D‐Q model. Also, the transient simulation results show a satisfactory response with the current controller parameters of the MMC at various operating cases. To validate the results of MATLAB‐Simulink model, the proposed system is implemented in hardware‐in‐the‐loop (HIL) simulation with an integrated subsystem built in two real‐time simulators. The subsystem of mathematical model is implemented in dSPACE, and the subsystem of 3‐ Φ MMC with controller is implemented in Typhoon. The HIL simulation results show a satisfactory response and consistent with MATLAB‐Simulink model results. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
16. Constructive eigenvalue analysis based velocity observer design for mechanical systems
- Author
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Wen, Haowei, Liu, Li, Shi, Peng, Yue, Xiaokui, and Gong, Shengping
- Published
- 2024
- Full Text
- View/download PDF
17. Eigenvalue-Based Stability Analysis for Droop-Free Controlled Islanded Microgrid With Symmetric/Asymmetric Communication Network.
- Author
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Zuo, Kunyu and Wu, Lei
- Abstract
Applying droop-based hierarchical control for islanded microgrids would face several unavoidable operation issues, such as large frequency deviation, high dynamic fluctuation, and inefficient coordination between different control layers. To this end, droop-free control has been explored to achieve the power sharing goal through neighboring communication, while maintaining system frequency levels (i.e., keeping the average nodal frequency constant). Although droop-free control shows potential in mitigating the defects of droop-based control, current research on the theoretical understanding of its stability performance remains limited. Hereby, this paper discusses the stability performance of droop-free controlled islanded microgrid via eigenvalue-based analysis. Specifically, a modified eigenvalue analysis method is first proposed to prove that all effective system eigenvalues under the symmetric communication network are located in the left half-plane, indicating that the symmetric droop-free controlled microgrid is asymptotically stable. Then, the asymmetric communication network is discussed, and the analytical eigenvalues with symmetric/asymmetric communication network designs are deduced under the homogenized electrical network. With the deduced analytical eigenvalues, stability performances of the symmetric/asymmetric designs are assessed via stability margin analysis and vulnerability analysis. Numerical case studies illustrate stability performance of the proposed designs, demonstrating that the asymmetric cycle design outperforms symmetric cycle and symmetric/asymmetric chain designs in overall convergence speed and stability against communication errors between droop-free controllers. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
18. Research on SSO Caused by HVDC Based on Eigenvalue Analysis
- Author
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Lin Yang, Ben Feng Gao, Dan Zhang, and Xiang Ning Xiao
- Subjects
Engineering ,Eigenvalue analysis ,Control theory ,Oscillation ,business.industry ,General Engineering ,Paper based ,Transient (oscillation) ,business ,Signal - Abstract
Subsynchronous Oscillation problems caused by HVDC system are studied and analyzed intensively in this paper based on eigenvalue analysis method. By establishing the small signal linearized model of a typical HVDC system, subsynchronous oscillation characteristics of the system with or without SSDC are obtained. Further more, the influence of SSDC parameters to the system subsynchronous oscillation characteristic can be illustrated clearly. This is significant for SSDC design in order to achieve a satisfied restraining effect. Comparing with more accurate electromagnetic transient simulation results, the consistency of the two methods is verified and it can be demonstrated that eigenvalue analysis method is adequate for studying subsynchronous oscillations.
- Published
- 2011
19. Discrete-Time State-Space Construction Method for SSO Analysis of Renewable Power Generation Integrated AC/DC Hybrid System.
- Author
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Han, Yingsheng, Sun, Haishun, Huang, Biyue, Qin, Shiyao, Mu, Qing, and Yu, Yongjun
- Subjects
STATE-space methods ,HYBRID power systems ,NODAL analysis ,HYBRID systems ,PARALLEL electric circuits ,EIGENVALUES - Abstract
Construction of the linearized state-space model is the key step of eigenvalue analysis for SSO study of power systems with large-scale renewable power generation (RPG) integrated. This paper proposes a novel method to construct the state matrix of the AC/DC hybrid power system with RPG within the discrete-time domain. The continuous-time state-space model of each AC/DC component as well as RPG units in the power system, is discretized together with their corresponding control. The discretized equation of each component is then represented by an equivalent circuit consisting of parallel historical current and conductance. According to the power system configuration, the discrete-time equivalent circuit of the whole AC/DC hybrid system is established, and the nodal analysis method is applied for the construction of the discrete-time state-space model of the power system. In this way, the state matrix can be acquired much more conveniently than that of continuous-time state-space method, which needs topology analysis to find independent state variables of the network from the proper tree. The proposed method has been applied in the eigenvalue analysis for the SSO study of a case system adapted from the AC/DC hybrid transmission system in northwest China. Eigenvalue results are in high accordance with time-domain simulation results in PSCAD/EMTDC. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
20. Research on Variable Droop Control Method for Improving Stability of Low-Voltage DC Distribution System
- Author
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Liu, Yantao, Deng, Wei, Mao, Xuekui, Zhang, Shiyi, Pei, Wei, Angrisani, Leopoldo, Series Editor, Arteaga, Marco, Series Editor, Chakraborty, Samarjit, Series Editor, Chen, Jiming, Series Editor, Chen, Shanben, Series Editor, Chen, Tan Kay, Series Editor, Dillmann, Rüdiger, Series Editor, Duan, Haibin, Series Editor, Ferrari, Gianluigi, Series Editor, Ferre, Manuel, Series Editor, Jabbari, Faryar, Series Editor, Jia, Limin, Series Editor, Kacprzyk, Janusz, Series Editor, Khamis, Alaa, Series Editor, Kroeger, Torsten, Series Editor, Li, Yong, Series Editor, Liang, Qilian, Series Editor, Martín, Ferran, Series Editor, Ming, Tan Cher, Series Editor, Minker, Wolfgang, Series Editor, Misra, Pradeep, Series Editor, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Oneto, Luca, Series Editor, Panigrahi, Bijaya Ketan, Series Editor, Pascucci, Federica, Series Editor, Qin, Yong, Series Editor, Seng, Gan Woon, Series Editor, Speidel, Joachim, Series Editor, Veiga, Germano, Series Editor, Wu, Haitao, Series Editor, Zamboni, Walter, Series Editor, Tan, Kay Chen, Series Editor, Yang, Qingxin, editor, Li, Zewen, editor, and Luo, An, editor
- Published
- 2024
- Full Text
- View/download PDF
21. A Frequency Domain Approach to Eigenvalue-Based Detection With Diversity Reception and Spectrum Estimation.
- Author
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Yousif, Ebtihal H. G., Ratnarajah, Tharmalingam, and Sellathurai, Mathini
- Subjects
EIGENVALUES ,EIGENANALYSIS ,EXPONENTIAL stability ,MELLIN transform ,INTEGRAL transforms - Abstract
In this paper, we investigate a frequency domain approach for eigenvalue-based detection of a primary user, based on equal gain combining (EGC) and spectrum estimation with Bartlett’s method. This paper considers two techniques for eigenvalue detection which are Maximum Eigenvalue Detection (MED) and the Maximum-Minimum Eigenvalue (MME) detector. We exploit the eigenvalues that are associated with the Hermitian form representation of Bartlett’s estimate to assess the performance of the aforementioned eigenvalue techniques in the frequency domain. For each case, we quantify the performance based on the probabilities of false alarm and missed detection over Rayleigh and Rician fading. A bivariate Mellin transform approach is employed to obtain the probability distribution function for the ratio of the extreme eigenvalues under each hypothesis. All obtained formulas are validated via Monte-Carlo simulations, and the results give a clear insight into the performance of the investigated methods. In frequency domain, MED outperforms both the MME detector and Periodogram-based energy detection even in a worst case scenario of noise uncertainty, while the MME detector exhibits heavy-tailed statistical characteristics and thus its receiver operating characteristics tend to stay on the line of no-discrimination. The performance of MED is further enhanced by careful choice of combinations of the total length of the sensing frame and number of sub-slots. [ABSTRACT FROM PUBLISHER]
- Published
- 2016
- Full Text
- View/download PDF
22. Topology optimization for minimum dynamic compliance using an antiresonant frequency constraint
- Author
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Meng, Fanwei, Meng, Liang, Wang, Jintao, Zhu, Jihong, Wang, Bo Ping, Yuan, Shangqin, and Zhang, Weihong
- Published
- 2024
- Full Text
- View/download PDF
23. Safe Operation of DFIG-Based Wind Parks in Series-Compensated Systems.
- Author
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Karaagac, Ulas, Mahseredjian, Jean, Kocar, Ilhan, Jensen, Simon, Gagnon, Richard, and Fecteau, Martin
- Subjects
WIND power plants ,INDUCTION generator performance ,ELECTRIC transients ,ELECTRIC lines ,ELECTRIC power system faults ,EIGENVALUES ,SAFETY - Abstract
Subsynchronous control interaction (SSCI) is the interaction between the power-electronics control and the series-compensated transmission system that occurs at frequencies below the system nominal frequency. SSCI may occur between the doubly-fed induction generator (DFIG) control system and the series-compensated transmission line, to which the wind park (WP) is connected. Not only do the DFIG control system parameters, but also the WP operating conditions have a significant impact on SSCI. In this paper, the impact of WP operating conditions and DFIG control system parameters on SSCI is analyzed in detail. Guidelines are presented for modifying the DFIG control system parameters to ensure safe operation and acceptable transient responses due to faults. This paper also examines the accuracies of various analytical tools used for SSCI problem identification and proposes a new frequency scan analysis approach for accurate prediction of potential SSCI problems. [ABSTRACT FROM PUBLISHER]
- Published
- 2018
- Full Text
- View/download PDF
24. Analysis of Synchronous Generators' Local Mode Eigenvalues in Modern Power Systems.
- Author
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Ritonja, Jožef and Polajžer, Boštjan
- Subjects
SYNCHRONOUS generators ,POWER electronics ,EIGENVALUES ,FREQUENCIES of oscillating systems ,ELECTRIC lines ,POWER plants - Abstract
New energy sources, storage facilities, power electronics devices, advanced and complex control concepts, economic operating doctrines, and cost-optimized construction and production of machines and equipment in power systems adversely affect small-signal stability associated with local oscillations. The objective of the article is to analyze local oscillations and the causes that affect them in order to reduce their negative impact. There are no recognized analyses of the oscillations of modern operating synchronous generators exposed to new conditions in power systems. The basic idea is to perform a numerical analysis of local oscillations of a large number of synchronous generators in the power system. The paper represents the local mode data obtained from a systematic analysis of synchronous generators in the Slovenian power system. Analyzed were 74 synchronous generators of the Slovenian power system, plus many additional synchronous generators for which data were accessible in references. The mathematical models convenient for the study of local oscillations are described first in the paper. Next, the influences of transmission lines, size of the synchronous generators, operating conditions, and control systems were investigated. The paper's merit is the applicable rules that have been defined to help power plant operators avoid stability-problematic situations. Consequently, boundaries were estimated of the eigenvalues of local modes. Finally, experiments were performed with a laboratory-size synchronous generator to assess the regularity of the numerically obtained conclusions. The obtained results enable the prediction of local oscillations' frequencies and dampings and will be useful in PSS planning. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
25. Suboptimal attitude tracking control law and eigenvalue analysis for a near-space hypersonic vehicle based on Koopman operator and stable manifold method.
- Author
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Mi, Peichao, Wu, Qingxian, and Wang, Yuhui
- Subjects
EIGENVALUES ,STABILITY of linear systems ,EXPONENTIAL stability ,VECTOR fields ,CLOSED loop systems ,LINEAR systems - Abstract
This paper proposes a novel strategy to design a suboptimal attitude tracking control law for a near-space hypersonic vehicle (NSHV) based on the Koopman operator and stable manifold theory. The nonlinear vector field of the NSHV attitude model is locally Lipschitz continuous and can be approximated by a high-dimensional linear system over a compact set. Linear and nonlinear parts of the attitude dynamics are determined based on this system. Subsequently, the stable manifold theory is applied to determine the unconstrained approximated optimal control law that is used to further consider the control input constraints of the NSHV attitude model. The suboptimality of the control law is analyzed, and the local exponential stability of the closed-loop system with input constraints is proven. Furthermore, the eigenvalues for the closed-loop nonlinear attitude error dynamics are analyzed. After the control input saturation, the nonlinear closed-loop error dynamics of the NSHV can be approximated by a high-dimensional linear system with a minimal dimension. The eigenvalues of this linear system indicate the stability and time response characteristics of the attitude error dynamics of the NSHV. The numerical simulation results demonstrate the effectiveness and suboptimality of the proposed attitude tracking control law and workflow of the eigenvalue analysis. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
26. Robust Subsynchronous Damping Control of PMSG-Based Wind Farm †.
- Author
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Wang, Yun, Luo, Fengyun, Long, Chaoyang, Tao, Guoqing, Xu, Ying, and Yang, Rong
- Subjects
PERMANENT magnet generators ,SUBSYNCHRONOUS resonance ,PHASE-locked loops ,ROBUST control ,WIND power plants ,UNCERTAIN systems ,OFFSHORE wind power plants - Abstract
This paper provides an H
∞ robust control strategy for a permanent magnet synchronous generator (PMSG)-based wind farm to realize subsynchronous resonance suppression (SSR) subject to uncertain system distortions and parameter perturbation. Firstly, an eighth-order state space mathematical model of a PMSG-based wind farm is established, including the grid-side converter (GSC), GSC controller, and phase-locked loop (PLL) model. Secondly, the SSR characteristics of a PMSG-based wind farm are analyzed through eigenvalue analysis. Thirdly, a robust subsynchronous damping controller is designed based on eigenvalue analysis of SSR. Finally, the designed robust subsynchronous damping controller is validated with case studies of wind farms. The results show that the controller can increase the stability of PMSG-based wind farm systems and restrain SSR. [ABSTRACT FROM AUTHOR]- Published
- 2023
- Full Text
- View/download PDF
27. Clustering-Based Modeling and Interaction Analysis of Multiple Differently Parameterized Grid-Side Inverters in PMSG Wind Turbines.
- Author
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Liao, Shuhan, Chen, Yandong, Huang, Meng, Fu, Xikun, Zha, Xiaoming, Wang, Lei, Luo, An, and Guerrero, Josep
- Subjects
TRANSFER functions ,TRANSFER matrix ,MATRIX functions ,DYNAMIC models ,LOCUS (Mathematics) ,WIND power plants ,OFFSHORE wind power plants - Abstract
Interactions of identical inverters in weak grids have received wide attentions. However, in a practical wind farm, parameters of grid-side inverters and lengths of collecting lines are not completely the same. In this case, a multi-inverter system is not symmetric, and thus the interaction mechanism could be more complicated than that of identical inverters. To investigate the interaction mechanism of differently parameterized inverters, this paper proposes a clustering-based modeling method, in which inverters with identical parameters are classified as one group. The clustering-based model allows for efficient stability assessment using three low-order transfer function matrices, instead of a full-order dynamic model. The root locus analysis is applied in the clustering-based model for stability analysis. Results show that the interconnection of distinct groups of inverters deteriorates common current stability, but has no impact on interactive current stability. The simulation and rtlab-based experimental results validate the effectiveness of the proposed model and the interaction mechanism of differently parameterized inverters. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
28. Calculation of Dynamic Response Using Eigenvectors in Redundancy Analysis of Truss Bridges.
- Author
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Tajima, Keiji, Inoue, Ryuichi, Hasuike, Rina, and Aso, Toshihiko
- Subjects
TRUSS bridges ,EIGENVECTORS ,FOURIER transforms ,IRON & steel bridges - Abstract
In the redundancy analysis of truss bridges, the calculation of the dynamic response caused by member damage requires accuracy. This paper presents a practical method of calculating the dynamic responses of truss bridge due to member damage considering its vibration characteristic, using eigenvectors instead of using dynamic amplification factor of one-degree-of-freedom system. A steel Pratt-truss bridge of long three-span with multiple influential vibration modes was the object of this research. The investigation of the dynamic response waveform due to member damage showed that there were multiple frequency peaks close to natural frequencies of the damaged truss bridge, and that the constant term of the Fourier transform was same as the result analyzed for the member damage using static analysis. Based on these results, a method for calculating the dynamic response by adding the cross-sectional force obtained by static analysis and by eigenvector was proposed. The range of vibration modes was set using the total modal participating mass ratio as an index, and the eigenvector that most affected the dynamic response of each member was selected for each member. Indeed, the dynamic response of cross-sectional force obtained by proposed method gave redundancy evaluation close to time-history-response analysis. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
29. Methodology for predicting brake squeal propensity using complex eigenvalue analysis, including thermo-mechanical effects.
- Author
-
Tirovic, Marko, Vianello, Michele, and Bannister, Paul
- Subjects
AUTOMOBILE brakes ,BRAKE design & construction ,AUTOMOBILE brake equipment ,AUTOMOBILE noise ,VIBRATION (Mechanics) ,EIGENVALUES - Abstract
With brake squeal being the most prevalent noise vibration and harshness issue in modern vehicles, this paper presents an improved methodology for brake squeal propensity prediction at the design stage. The research established four clearly defined 'Stages' in conducting finite element squeal analyses, describing crucial input data, modelling procedures, output and validation results. Stage 1 deals with free-free modal characteristics of individual brake components and their material characteristics. Stage 2 combines individual parts, conducting brake assembly mechanical finite element analyses. Stage 3 concentrates on fully coupled thermo-mechanical finite element analyses, and the concluding stage, Stage 4, focuses on brake assembly stability analyses. Validations proved that very accurate predictions are possible, but the geometries, material characteristics and established modelling procedures must be strictly followed. Material characteristics were most prone to introduce discrepancies with measured values. 'Generic' values are found to be unacceptable and conducting own measurements was necessary, in particular for the friction material, whose anisotropic properties have been measured in detail, leading to high accuracy in predicting pad natural modes and frequencies. In Stage 4, the stability analyses of the full brake assembly were based on the complex eigenvalue analysis (which included thermal aspects), with the sign of the real part giving an indication of stability and the imaginary part defining the frequency of the unstable mode. Instabilities and frequencies predicted match well with the values measured in dynamometer tests, clearly demonstrating the influence of thermal effects. The final output of the procedures described in this paper is a validated three-dimensional thermo-mechanical finite element noise vibration and harshness brake assembly model in which natural frequencies and modes, instabilities and contributing factors can be predicted at any time during a brake application. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
30. Sub-Synchronous Resonance Damping Control for Series-Compensated DFIG-Based Wind Farm With Improved Particle Swarm Optimization Algorithm.
- Author
-
Yao, Jun, Wang, Xuewei, Li, Jiawei, Liu, Ruikuo, and Zhang, Hailin
- Subjects
MATHEMATICAL optimization ,PARTICLE swarm optimization ,WIND power plants ,WIND speed ,INDUCTION generators ,RESONANCE ,OFFSHORE wind power plants - Abstract
In this paper, we propose an improved sub-synchronous resonance (SSR) damping controller (SSRDC) and a related control strategy to mitigate the SSR in a capacitive series-compensated double-fed induction generator based wind farms, based on the damping torque analysis. The proposed strategy is utilized for enhancing the system stability. Compared with the traditional damping controller, the proposed SSRDC is simultaneously embedded into the $d$ -axis and $q$ -axis control channels in the inner current loop of the rotor-side converter. On this basis, combined with the eigenvalue analysis and improved particle swarm optimization algorithm, the optimum gain coefficients of the SSRDC can be determined for maximizing the mitigation effect under different operation conditions of the series compensation levels and wind speeds. Moreover, the effect of the weight coefficients in the objective function on the SSR suppression is also investigated. Finally, the time-domain simulations are carried out to demonstrate the effectiveness of the proposed control strategy for mitigating the SSR and suppressing the connected power system oscillations. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
31. Coupled Analysis of Acoustic Space and Thin-Plate Vibrations by a Lumped-Mass Model Using Raviart–Thomas Elements.
- Author
-
Hisano, Shotaro, Ishikawa, Satoshi, and Iwamoto, Hiroyuki
- Subjects
SOUND pressure ,COORDINATE transformations ,FINITE element method ,NUMERICAL calculations ,DEGREES of freedom ,EIGENVALUES - Abstract
Suppression of noise and vibration in machine products is an important problem, and many methods have been studied. In particular, structural–acoustic coupled effects due to the weight reduction of machines cannot be ignored. In structural–acoustic coupled analysis, the finite-element method in which the acoustic space is described by sound pressure and the structure is described by displacement is often used. However, the eigenvalue analysis in that method takes a great deal of computational time because the mass and stiffness matrices are asymmetric. Instead, in this paper, we propose an efficient coupled analysis method for a three-dimensional acoustic space and a two-dimensional thin plate using a lumped-mass model. The proposed modeling method is derived systematically using Raviart–Thomas elements. In addition, we propose a coordinate transformation method that accelerates the calculations by reducing the number of degrees of freedom (DOF). In this way, a symmetric eigenvalue problem with no extra DOF is derived. The effectiveness of the proposed method is confirmed by numerical calculations. This analysis method is particularly effective for systems in which the acoustic space contributes to the majority of the DOF, since the acoustic space is sparse owing to the adoption of edge elements. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
32. Optimal Design and Tuning of Novel Proportional Integral Derivative with Filter Thyristor-Controlled Series Compensator Stabiliser Using a New Hybrid Technique.
- Author
-
Khawaja, Abdul Waheed, Kamari, Nor Azwan Mohamed, Zainuri, Muhammad Ammirrul Atiqi Mohd, Zulkifley, Mohd Asyraf, Zaman, Mohd Hairi Mohd, and Musirin, Ismail
- Subjects
INTEGRALS ,FLAME ,DESIGN ,MOTHS ,ANGLES - Abstract
This paper proposes a novel robust thyristor-controlled series compensator (TCSC) controller based on proportional integral derivative with filter (PIDF) and uses a new hybrid optimisation evolutionary programming sine cosine algorithm (EPSCA) to improve the power system's angle stability. The problem of the PIDF-TCSC design is transformed into an optimisation problem based on performance indices, such as damping factor, damping ratio, and eigenvalues, where the multi-objective function is employed to obtain the optimal stabiliser parameters. To examine the robustness of PIDF-TCSC, it was tested on a single-machine infinite-bus power system under different operating conditions. The performance of the system with the PIDF-TCSC controller was compared with the simulation results, and the results obtained with the proposed EPSCA were compared with those obtained with SCA, moth flame optimisation, and EP-based PIDF-TCSC methods. Simulation results showed the effectiveness of EPSCA for the PIDF-TCSC design and the superior robust performance for the enhancement of power system stability compared with other techniques in different cases. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
33. Model Reference Adaptive Control for Milk Fermentation in Batch Bioreactors.
- Author
-
Ritonja, Jožef, Goršek, Andreja, and Pečar, Darja
- Subjects
ADAPTIVE control systems ,BIOREACTORS ,TRACKING control systems ,BATCH processing ,PLANT variation ,LACTIC acid - Abstract
This paper presents the advanced control theory's original utilisation to realise a system that controls the fermentation process in batch bioreactors. Proper fermentation control is essential for quality fermentation products and the economical operation of bioreactors. Batch bioreactors are very popular due to their simple construction. However, this simplicity presents limitations in implementing control systems that would ensure a controlled fermentation process. Batch bioreactors do not allow the inflow/outflow of substances during operation. Therefore, we have developed a control system based on a stirrer drive instead of material flow. The newly developed control system ensures tracking of the fermentation product time course to the reference trajectory by changing the stirrer's speed. Firstly, the paper presents the derivation of the enhanced mathematical model suitable for developing a control system. A linearisation and eigenvalue analysis of this model were made. Due to the time-consuming determination of the fermentation model and the variation of the controlled plant during operation, the use of adaptive control is advantageous. Secondly, a comparison of different adaptive approaches was made. The model reference adaptive control was selected on this basis. The control theory is presented, and the control realisation described. Experimental results obtained with the laboratory batch bioreactor confirm the advantages of the proposed adaptive approach compared to the conventional PI-control. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
34. Comparison of Numerical Methods and Open-Source Libraries for Eigenvalue Analysis of Large-Scale Power Systems.
- Author
-
Tzounas, Georgios, Dassios, Ioannis, Liu, Muyang, and Milano, Federico
- Subjects
INDEPENDENT system operators ,ELECTRIC power system stability ,NONSYMMETRIC matrices ,EIGENVALUES ,SOFTWARE development tools ,SOFTWARE libraries (Computer programming) - Abstract
This paper discusses the numerical solution of the generalized non-Hermitian eigenvalue problem. It provides a comprehensive comparison of existing algorithms, as well as of available free and open-source software tools, which are suitable for the solution of the eigenvalue problems that arise in the stability analysis of electric power systems. The paper focuses, in particular, on methods and software libraries that are able to handle the large-scale, non-symmetric matrices that arise in power system eigenvalue problems. These kinds of eigenvalue problems are particularly difficult for most numerical methods to handle. Thus, a review and fair comparison of existing algorithms and software tools is a valuable contribution for researchers and practitioners that are interested in power system dynamic analysis. The scalability and performance of the algorithms and libraries are duly discussed through case studies based on real-world electrical power networks. These are a model of the All-Island Irish Transmission System with 8640 variables; and, a model of the European Network of Transmission System Operators for Electricity, with 146,164 variables. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
35. On the Application of Modal Transient Analysis for Online Fault Localization in HVDC Cable Bundles.
- Author
-
Ashouri, Mani, da Silva, Filipe Faria, and Bak, Claus Leth
- Subjects
MODAL analysis ,TRANSMISSION line matrix methods ,FAULT location (Engineering) ,TRANSIENT analysis - Abstract
This paper presents the modal analysis of different HVDC cable bundles. Using modal theory, specific transformation matrices are presented, and the modal equivalent circuits are illustrated. The behavior of the resulting modes is studied in a wide frequency range, the impact of different cable parameters and burial configurations on the modal characteristics are analyzed. A concept for online fault localization in HVDC cable transmission based on the difference between the modal velocities and consequently the arrival times of the modal traveling wave initial peaks is presented. In this method, modal voltages and currents are used instead of direct measurements and the proposed concept uses one-sided measurement without needing to detect the second TW reflections. Multiple faults are applied to CIGRE HVDC models in PSCAD/EMTDC and the modal analysis is obtained in MATLAB. The impact of different sampling frequencies, fault resistance, fault location and different grounding schemes on the proposed modal fault location principle is analyzed. The theoretical results show the accuracy of the proposed modal fault localization concept for different HVDC cable bundles. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
36. Prediction method for shear stability of composite hat-stringer stiffened panel
- Author
-
Han, Shui, Yin, Yu, YiLe, Hu, Hao, Xiao, and YunYao, Xu
- Published
- 2023
- Full Text
- View/download PDF
37. Utilization of superconducting magnetic energy storage and doubly fed induction generator for enhancing stability of interconnected power system.
- Author
-
Waheed Kumar, Abdul, din Mufti, Mairaj Ud, and Yaqoob Zargar, Mubashar
- Subjects
- *
MAGNETIC energy storage , *INTERCONNECTED power systems , *INDUCTION generators , *RENEWABLE energy sources , *SYNCHRONOUS generators , *WIND energy conversion systems , *POWER electronics - Abstract
Summary: As the share of wind power keeps on increasing, the interaction between synchronous and wind generators pose a challenging issue on power system stability. In order to investigate the impact of wind penetration on stability of power system, appropriate modeling of wind energy conversion systems (WECSs) is necessary. Moreover, it is needed to comprehensively study the impact of wind penetration on power system oscillations. This paper presents a didactic approach for integrating a doubly fed induction generator (DFIG)‐based wind farm from SimPower Systems library to a five‐area 68‐bus power system modeled in Simulink. Inter‐area oscillations with and without wind power penetration are investigated for their characteristics. Renewable energy sources are connected to the grid via power electronics converters at the cost of a reduction in inertia. The concept of virtual synchronous generator (VSG) produces virtual inertia by exchanging active power with the power system. The impact of superconducting magnetic energy storage (SMES) and DFIG on enhancing damping performance of inter‐area is investigated. The increase in damping ratios of inter‐area oscillatory modes verifies the enhancement in small signal stability by connecting SMES and DFIG to the power system. The usage of SMES operating in VSG mode to improve the dynamic stability with highly erratic wind profile is also investigated. The developed MATLAB/SIMULINK‐based DFIG model is simple to use and can be expanded to build efficient controllers. The fidelity of the DFIG model and VSG technology is verified in real time by Opal‐RT (OP4510). [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
38. CONVERGENCE ANALYSIS OF INEXACT TWO-GRID METHODS: A THEORETICAL FRAMEWORK.
- Author
-
XUEFENG XU and CHEN-SONG ZHANG
- Subjects
MULTIGRID methods (Numerical analysis) ,PARTIAL differential equations ,LINEAR systems - Abstract
Multigrid is one of the most efficient methods for solving large-scale linear systems that arise from discretized partial differential equations. As a foundation for multigrid analysis, twogrid theory plays an important role in motivating and analyzing multigrid algorithms. For symmetric positive definite problems, the convergence theory of two-grid methods with exact solution of the Galerkin coarse-grid system is mature, and the convergence factor of exact two-grid methods can be characterized by an identity. Compared with the exact case, the convergence theory of inexact twogrid methods (i.e., the coarse-grid system is solved approximately) is of more practical significance, while it is still less developed in the literature (one reason is that the error propagation matrix of inexact coarse-grid correction is not a projection). In this paper, we develop a theoretical framework for the convergence analysis of inexact two-grid methods. More specifically, we present two-sided bounds for the energy norm of the error propagation matrix of inexact two-grid methods, from which one can readily obtain the identity for exact two-grid convergence. As an application, we establish a unified convergence theory for multigrid methods, which allows the coarsest-grid system to be solved approximately. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
39. On the Stability Analysis of Systems of Neutral Delay Differential Equations.
- Author
-
Liu, Muyang, Dassios, Ioannis, and Milano, Federico
- Subjects
DELAY differential equations ,FUNCTIONAL differential equations ,SYSTEM analysis - Abstract
This paper focuses on the stability analysis of systems modeled as neutral delay differential equations (NDDEs). These systems include delays in both the state variables and their time derivatives. The proposed approach consists of a descriptor model transformation that constructs an equivalent set of delay differential algebraic equations (DDAEs) of the original NDDEs. We first rigorously prove the equivalency between the original set of NDDEs and the transformed set of DDAEs. Then, the effect on stability analysis is evaluated numerically through a delay-independent stability criterion and the Chebyshev discretization of the characteristic equations. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
40. Design of Multi-Machine Power System Stabilizers with Forecast Uncertainties in Load/Generation.
- Author
-
Krishan, Ram, Verma, Ashu, and Mishra, Sukumar
- Subjects
ELECTRIC power systems ,ELECTRICAL load ,VOLTAGE regulators ,METAHEURISTIC algorithms ,MATHEMATICAL optimization - Abstract
Oscillatory instability in modern power system has increased due to increasing complexity and integration of dynamic loads. Stability analysis of such interconnected power system is very prominent in the presence of uncertain load/generation. In this paper, a power system stabilizer (PSS) design approach, which aims at enhancing the oscillatory stability of the multi-machine power system over the specified uncertainty range in forecasted load/generation, is presented. With non-statistical uncertainty, problem of selecting design parameters of the PSS is formulated as an optimization problem with minimization of eigenvalues and damping ratios based multi-objective function. In order to account the non-statistical uncertainties, a boundary active power loss (BAPL) based objective function is proposed. This non-linear BAPL objective function is minimized for determining the optimal setting of the generators voltage and taps of the online tap changing transformers (OLTC) under various power system constraints. In this paper, both the objective functions are solved by a new metaheuristic technique known as gray wolf optimization (GWO). Boundary value-based approach is used to minimize the repeated load flows under uncertain load/generation scenarios. Improved small-signal stability (SSS) is achieved with optimal active power loss of uncertain power system. Eigenvalue and time domain analysis for New England system are carried out under wide range of disturbances to demonstrate the potential of the proposed approach. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
41. Improving the Impedance-Based Stability Criterion by Using the Vector Fitting Method.
- Author
-
Bakhshizadeh, Mohammad Kazem, Blaabjerg, Frede, Hjerrild, Jesper, Kocewiak, Lukasz, and Bak, Claus Leth
- Subjects
ELECTRIC impedance ,CASCADE converters ,COMPUTER simulation - Abstract
In this paper, some issues related to the impedance-based stability criterion, such as RHP poles in the minor-loop gain, how to specify source and load impedances, and node-dependent stability margins are discussed and the vector fitting method is used to improve the method. This results in an eigenvalue analysis of the system instead of using the Nyquist diagram, and leads to obtain more information about the system. Furthermore, a participation factor analysis can be used to identify the problematic subsystem. The proposed method is examined in the assessment of a stable and an unstable system, and simulation results are used for verification. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
42. Impact of control system on small‐signal stability of hybrid multi‐infeed HVDC system.
- Author
-
Guo, Chunyi, Liu, Wei, Zhao, Jian, and Zhao, Chengyong
- Abstract
This paper focuses on the impact of control system on small‐signal stability of the Hybrid Multi‐Infeed HVDC(H‐MIDC) system, in which the Line‐Commutated‐Converter based HVDC (LCC‐HVDC) and Voltage‐Sourced‐Converter based HVDC (VSC‐HVDC) links feed into an AC system in close mutual proximity. A comprehensive linearized small‐signal model is developed for an H‐MIDC system. Based on the eigenvalue analysis and participation factor analysis, the inherent oscillatory modes of the H‐MIDC system are revealed. Then, the impact of the most sensitive control system parameters on the least‐damped modes are investigated. The studies show that (i) the proportional gains of PLL functions of LCC and VSC stations, and AC voltage outer loop controller of VSC station are highly coupled, and presents the most sensitivity to the least damped modes; (ii) parameters of PLL in LCC station, and outer loop of AC voltage control and PLL in VSC station can highly impact the damping of the oscillatory modes and even cause instability, and (iii) smaller PLL gains in LCC and VSC stations, and smaller proportional gain of AC voltage control of VSC station are preferable and can enhance damping of dominant modes. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
43. An Accurate Small Signal Dynamic Model for LCC-HVDC.
- Author
-
Dong, Yuqing, Ma, Junpeng, Wang, Shunliang, Liu, Tianqi, Chen, Xiang, and Huang, He
- Subjects
DYNAMIC models ,PHASE-locked loops ,EIGENVALUES - Abstract
This paper develops an accurate small signal model for line commutated converter based HVDC (LCC-HVDC). The overall process of the model establishment is demonstrated from five parts: AC system, DC system, control system, phase-locked loop (PLL) and the converter. Considering the limitations of the traditional converter equations, the proposed small signal model takes the commutation process into account so that the overlap angle and AC current are calculated with the actual value rather than the estimated value. The accuracy of the proposed model is verified both in the time-domain simulation in PSCAD/EMTDC and by eigenvalue analysis. The results show better performance than the traditional modeling methods, which provides valuable guidance for future LCC-HVDC project design. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
44. Damping Characteristics of Interconnected Power Systems with Wind-Photovoltaic-Thermal-Bundled Power Transmitted by AC/DC Systems.
- Author
-
He, Ping, Li, Zhao, Zheng, Mingming, Wen, Fushuan, Ji, Yuqi, and Wu, Xinxin
- Subjects
INTERCONNECTED power systems ,WIND power ,ALTERNATING currents ,HIGH voltages ,POWER transmission ,DYNAMIC simulation ,PHOTOVOLTAIC power generation ,SAMPLING theorem - Abstract
One of the major ways of delivering renewable energy generation from large-scale energy bases in northeast, northwest, and northern China, is to bundle the power from wind-photovoltaic-thermal units and then transmit it by alternating current/direct current (AC/DC) systems. The interactions among wind power units, photovoltaic (PV) power units, and high voltage direct current (HVDC) systems make the stability of the interconnected power system more complicated. In this paper, a framework model of wind-PV-thermal-bundled power transmitted by AC/DC systems is constructed based on the mathematical models of thermal power units, wind power units, PV power units, and HVDC transmission systems. Considering the fluctuations of wind power outputs and PV power outputs, a small-signal stability model of an interconnected power system with wind-PV-thermal-bundled power transmitted by AC/DC systems is established based on an existing stability theorem. The interactions among various forms of energy and their impacts on wind-PV-thermal-bundled power transmitted by AC/DC systems are studied through theoretical analysis and dynamic simulation. A sample interconnected power system is used to demonstrate the proposed method. It is shown by simulation results that the wind-PV-thermal-bundled power transmission distance; the electrical distance among wind power units, PV power units, and thermal power units; the grid-connected capacities of wind, PV, and thermal power units; and the power loading ratios of AC lines over DC lines all have various degrees of impacts on the stability of the interconnected power system. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
45. Eigenvalue analysis of planar linear multibody system under conservative force based on the transfer matrix method
- Author
-
Jinghong Wang, Xiaoting Rui, Xun Wang, Jianshu Zhang, Qinbo Zhou, and Junjie Gu
- Subjects
conservative forces ,eigenvalue analysis ,ideal hinges ,modal transformation ,multibody system transfer matrix method ,state perturbation ,Mechanical engineering and machinery ,TJ1-1570 ,Systems engineering ,TA168 - Abstract
Abstract The linear multibody system transfer matrix method (LMSTMM) provides a powerful tool for analyzing the vibration characteristics of a mechanical system. However, the original LMSTMM cannot resolve the eigenvalues of the systems with ideal hinges (i.e., revolute hinge, sliding hinge, spherical hinge, cylindrical hinge, etc.) or bodies under conservative forces due to the lack of the corresponding transfer matrices. This paper enables the LMSTMM to solve the eigenvalues of the planar multibody systems with ideal hinges or rigid bodies under conservative forces. For a rigid body, the transfer matrix can now consider coupling terms between forces and kinematic state perturbations. Also, conservative forces that contribute to the eigenvalues can be considered. Meanwhile, ideal hinges are introduced to LMSTMM, which enables the treatment of eigenvalues of general multibody systems using LMSTMM. Finally, the comparative analysis with ADAMS software and analytical solutions verifies the effectiveness of the proposed approach in this paper.
- Published
- 2023
- Full Text
- View/download PDF
46. Subsynchronous Resonance Mitigation for Series-Compensated DFIG-Based Wind Farm by Using Two-Degree-of-Freedom Control Strategy.
- Author
-
Huang, Po-Hsu, El Moursi, Mohamed Shawky, Xiao, Weidong, and Kirtley, James L
- Subjects
ELECTRIC power systems research ,SUBSYNCHRONOUS resonance ,INDUCTION generators ,WIND power plants ,WIND speed - Abstract
This paper investigates a special class of dynamic power system problem, namely subsynchronous resonance (SSR) resulted from a series-compensated network connecting doubly-fed induction generator (DFIG) based wind farms. A novel two-degree-of-freedom (2DOF) control strategy combined with a damping control loop is designed and analyzed for enhancing the system stability and alleviates the SSR that may arise due to the induction generator effect (IGE). The proposed control strategy is tested at different operating conditions of series compensation levels and low wind speeds to ensure the system stability. The doubly-fed induction generator based wind farms without the proposed control strategy leads to overall system instability during high series compensation and low wind speeds. Hence, the mitigation of the SSR and damping enhancement are critical to the entire power system stability. A reliable way of analyzing the system and designing effective control strategies against SSR based on the eigenvalue analysis and impedance based stability criterion is deployed. Moreover, analytical explanations have been elaborated to verify the procedure of the controller design. Fault ride-though capability has also been investigated with the proposed control strategy that is flexible to be integrated with the FRT schemes so as to assist the wind farm in mitigating the SSR during the fault recovery stage. Finally, time domain simulations are carried out to demonstrate the effectiveness of the proposed control strategy for mitigating the SSR and damping power system oscillations. [ABSTRACT FROM PUBLISHER]
- Published
- 2015
- Full Text
- View/download PDF
47. SSR Damping Controller Design and Optimal Placement in Rotor-Side and Grid-Side Converters of Series-Compensated DFIG-Based Wind Farm.
- Author
-
Mohammadpour, Hossein Ali and Santi, Enrico
- Abstract
This paper deals with subsynchronous resonance (SSR) phenomena in a capacitive series-compensated DFIG-based wind farm. Using both modal analysis and time-domain simulation, it is shown that the DFIG wind farm is potentially unstable due to the SSR mode. In order to damp the SSR, the rotor-side converter (RSC) and grid-side converter (GSC) controllers of the DFIG are utilized. The objective is to design a simple proportional SSR damping controller (SSRDC) by properly choosing an optimum input control signal (ICS) to the SSRDC block, so that the SSR mode becomes stable without decreasing or destabilizing the other system modes. Moreover, an optimum point within the RSC and GSC controllers to insert the SSRDC is identified. Three different signals are tested as potential ICSs including rotor speed, line real power, and voltage across the series capacitor, and an optimum ICS is identified using residue-based analysis and root-locus method. Moreover, two methods are discussed in order to estimate the optimum ICS, without measuring it directly. The studied power system is a \mathbf100\;MW DFIG-based wind farm connected to a series-compensated line whose parameters are taken from the IEEE first benchmark model (FBM) for computer simulation of the SSR. MATLAB/Simulink is used as a tool for modeling and designing the SSRDC, and power system computer aided design/electromagnetic transients including dc (PSCAD/EMTDC) is used to perform time-domain simulation for design process validation. [ABSTRACT FROM PUBLISHER]
- Published
- 2015
- Full Text
- View/download PDF
48. A bandwidth-enhanced planar endfire antenna based on surface waves.
- Author
-
Cheng, You-Feng, Ding, Xiao, Jin, Fu-Long, and Shao, Wei
- Subjects
ANTENNAS (Electronics) ,BANDWIDTHS ,SURFACE waves (Fluids) ,SURFACE energy ,WAVES (Physics) - Abstract
A surface-wave-based endfire antenna with an enhanced impedance bandwidth is presented in this paper. The antenna consists of a surface-wave guide (SWG) and five strips printed on the SWG. The endfire radiation benefits from the surface-wave diffraction of the SWG which is investigated with the Snell's law, effective surface impedance and eigenvalue analysis. A prototype is fabricated and measured, and the measured results indicate that the antenna has two resonances and its bandwidth is enhanced up to 16.1% (4.0-4.73 GHz). The proposed endfire antenna also exhibits high gain, good gain flatness, low cross-polarization level and low profile. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
49. An Improved Measure of AC System Strength for Performance Analysis of Multi-Infeed HVdc Systems Including VSC and LCC Converters.
- Author
-
Ni, Xiaojun, Zhao, Chengyong, Guo, Chunyi, and Gole, Aniruddha M.
- Subjects
HIGH-voltage direct current converters ,ALTERNATING currents ,PERFORMANCE evaluation ,IDEAL sources (Electric circuits) ,SHORT circuits ,BUS conductors (Electricity) ,ELECTRIC impedance - Abstract
A small signal model of a multi-infeed high-voltage direct current (HVdc) transmission system containing a line commutated converter (LCC) and a voltage source converter (VSC) is developed. This model represents the LCC and VSC converters as operational impedances as seen from the converter ac busbar. This permits the converters to be included in the effective short-circuit ratio (ESCR) calculations. The resulting ESCR is referred to in this paper as the “Impedance based Effective Short Circuit Ratio” (IESCR). It is shown that the maximum power transfer limit (referred to as the maximum available power or MAP) of the converters is better predicted by this index compared to the conventional ESCR which ignores the operational impedances of the converters. The question also arises as to how close to this theoretical maximum power transfer limit can the HVdc system operate. Using the small-signal model, it is shown that with commonly used control strategies, the predicted MAP can only be achieved by reducing the controller gains. The results are validated using detailed electromagnetic transients simulation of the multi-infeed VSC-LCC system. [ABSTRACT FROM PUBLISHER]
- Published
- 2018
- Full Text
- View/download PDF
50. Effects of Front-End Converter and DC-Link of a Utility-Scale PV Energy System on Dynamic Stability of a Power System.
- Author
-
Moradi-Shahrbabak, Zahra and Tabesh, Ahmadreza
- Subjects
DYNAMIC stability ,PHOTOVOLTAIC power systems ,EIGENVALUES ,DIRECT currents ,CAPACITORS - Abstract
This paper presents a method for small-signal dynamic studies of power systems including utility-scale PV energy systems considering the effects of dc-side components. Existing methods commonly model a PV energy system as a dc source connected to a grid-tied inverter. This paper shows that the dc components of a PV energy system can also contribute in the dynamics of the power system in the range of small-signal studies. The paper first develops the model of a PV energy system by merging the submodels of dc- and ac-side components. Then, a method to obtain the augmented model of the power system including a PV energy system will be explained using a study system. The study system consists of a PV energy system in parallel with a synchronous generator connected to a grid. Then, based on eigenvalue analysis, verified by time-domain simulations, it is shown that the dc-link capacitor, front-end converter, and its controller can introduce oscillatory modes in subsynchronous range of frequencies. Furthermore, it is shown that the damping of the sensitive modes can significantly vary with respect to the parameters of the dc-side components. [ABSTRACT FROM PUBLISHER]
- Published
- 2018
- Full Text
- View/download PDF
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