Relevant bibliographies by topics / Small-Signal Stability Analysis

Contents

  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers

Academic literature on the topic 'Small-Signal Stability Analysis'

Author: Grafiati
Published: 4 June 2021
Last updated: 11 June 2025

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Journal articles on the topic "Small-Signal Stability Analysis"

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Shirvani, Mojtaba, Ahmad Memaripour, Meysam Eghtedari, and Hasan Fayazi. "Small signal stability analysis of power system following different outages." International Journal of Academic Research 6, no. 2 (2014): 268–72. http://dx.doi.org/10.7813/2075-4124.2014/6-2/a.38.

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Matoba, Seiichi, Masanori Hagihira, and Masahiro Sekita. "A Small Signal Stability Analysis Using Parallel Algorithm." IEEJ Transactions on Power and Energy 118, no. 1 (1998): 63–70. http://dx.doi.org/10.1541/ieejpes1990.118.1_63.

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Lim Zhu Aun, Shalom, Marayati Bte Marsadek, and Agileswari K. Ramasamy. "Small Signal Stability Analysis of Grid Connected Photovoltaic." Indonesian Journal of Electrical Engineering and Computer Science 6, no. 3 (2017): 553. http://dx.doi.org/10.11591/ijeecs.v6.i3.pp553-562.

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This paper primarily focuses on the small signal stability analysis of a power system integrated with solar photovoltaics (PV). The test system used in this study is the IEEE 39-bus. The small signal stability of the test system are investigated in terms of eigenvalue analysis, damped frequency, damping ratio and participation factor. In this study, various conditions are analyzed which include the increase in solar PV penetration into the system and load variation. The results obtained indicate that there is no significant impact of solar PV penetration on the small signal stability of large scaled power system.
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Makarov, Yu V., Zhao Yang Dong, and D. J. Hill. "A general method for small signal stability analysis." IEEE Transactions on Power Systems 13, no. 3 (1998): 979–85. http://dx.doi.org/10.1109/59.709086.

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Radwan, Amr. "Small-Signal Stability Analysis of Multi-Terminal DC Grids." Electronics 8, no. 2 (2019): 130. http://dx.doi.org/10.3390/electronics8020130.

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This paper presents a detailed small-signal analysis and an improved dc power sharing scheme for a six terminal dc grid. The multi-terminal DC (MTDC) system is composed of (1) two voltage-source converters (VSCs) entities operating as rectification stations; (2) two VSCs operating as inverting stations; (3) two dc/dc conversion stations; and (4) an interconnected dc networking infrastructure. The small-signal state-space sub-models of the individual entities are developed and integrated to formulate the state-space model of the entire system. Using the modal analysis, it is shown that the most critical modes are associated with the power sharing droop coefficients of the rectification stations, which are constrained by the steady-state operational requirements. Therefore, a second degree-of-freedom compensation scheme is proposed to improve the dynamic response of the MTDC system without influencing the steady-state operation. Time domain simulation results are presented to validate the analysis and show the effectiveness of the proposed techniques.
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Dong, Zhao Yang, Yuri V. Makarov, and David J. Hill. "Analysis of small signal stability margins using genetic optimization." Electric Power Systems Research 46, no. 3 (1998): 195–204. http://dx.doi.org/10.1016/s0378-7796(98)00009-1.

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Verma, Mayank Singh, Poonam Khatarkar, and Kumar Prabhakar. "Power System Small Signal Stability Analysis Using Facts Pod." International Journal of Computer Trends & Technology 67, no. 07 (2019): 57–61. http://dx.doi.org/10.14445/22312803/ijctt-v67i7p109.

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Yousin Tang and A. P. S. Meliopoulos. "Power system small signal stability analysis with FACTS elements." IEEE Transactions on Power Delivery 12, no. 3 (1997): 1352–61. http://dx.doi.org/10.1109/61.637014.

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Mahdavian, Aram, Ali Asghar Ghadimi, and Mohammad Bayat. "Microgrid small‐signal stability analysis considering dynamic load model." IET Renewable Power Generation 15, no. 13 (2021): 2799–813. http://dx.doi.org/10.1049/rpg2.12203.

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Li, Jun, Jie Chen, Yaru Xue, Ruichang Qiu, and Zhigang Liu. "Stability Analysis Method of Parallel Inverter." Mathematical Problems in Engineering 2017 (2017): 1–14. http://dx.doi.org/10.1155/2017/6062798.

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In order to further provide theoretical support for the stability of an auxiliary inverter parallel system, a new model which covers most of control parameters needs to be established. However, the ability of the small-signal model established by the traditional method is extremely limited, so this paper proposes a new small-signal modeling method for the parallel system. The new small-signal model not only can analyze the influence of the droop parameters on the system performance, but also can analyze the influence of the output impedance of the inverter, the unbalanced and nonlinear loads, and the power calculation method and cut-off frequency of the low-pass filter on the system performance and stability. Based on this method, this paper carries out a comprehensive analysis on the performance of a parallel inverter system. And the correctness of the modeling method and analysis process of the system performance and stability are verified by the consistency of the simulation and experimental results.
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Dissertations / Theses on the topic "Small-Signal Stability Analysis"

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McIlhagger, David. "Acceleration of power system small signal stability analysis." Thesis, Queen's University Belfast, 2007. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.486529.

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Electric power networks comprise large complex interconnections of generation and loads. The generators, and their controllers, are non-linear dynamic systems which on interconnection form a very complex control problem. Traditionally the models used to capture the small signal Rtability of these systems were not highly detailed. This waR jURtified Rince the generation was provided by large centralized power Rtations, however with the current trend towards small scale and diRtributed generation, as provided by.wind farmR and diesel genRetR, the power system modelR require a greater level of detail. This means that the stability assessment of theRe models involves greater detail and requires greater computation time, thus rendering near future predictions obsolete. ThiR thesis studies the methods that are Ilsed to determine • power system small signal stability, in order to provide acceleration to this analysis. A method based on wavelet approximations to provide an approximate solution was developed and its effectiveneRs against the traditional QR algorithm waR investigated. The method was applied to a four generator RyRtem and the IEEE New England 39 bus Rystem. Alternative methods to form accelerating polynomials for eigenvalue methodR were developed and evaluated against the IEEE New England 39 bus system. A new algorithm, called the polygon polynomial Arnoldi method (PPAM) was developed and tested against the implicitly restarted Arnoldi method (IRAM), from the linear algebra literature. The effectiveness of both theRe methods was tested against the IEEE New England 39 bus system and the one area IEEE reliability test system along with that for the QR algorithm.
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Rudraraju, Seetharama raju. "SMALL SIGNAL AND TRANSIENT STABILITY ANALYSIS OF MVDC SHIPBOARD POWER SYSTEM." MSSTATE, 2009. http://sun.library.msstate.edu/ETD-db/theses/available/etd-11052009-170217/.

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Recent developments in high power rated Voltage Source Converters (VSCs) have resulted in their successful application in Multi-Terminal HVDC (MTDC) transmission systems and also have potential in the Medium Voltage DC (MVDC) distribution systems. This work presents the findings of stability studies carried out on a zonal MVDC architecture for the shipboard power distribution system. The stability study is confined to rotor angle stability of the power system, i.e. the transient and small signal stability analysis. The MTDC ring structure similar to MVDC shipboard power system was implemented in MATLAB/Simulink to look at the transient behavior of the MVDC system. Small signal stability analysis has been carried out with the help of Power System Toolbox (PST) for both MVAC as well as MVDC architectures. Later, Participation Analysis has been carried out to address the small signal instability in the case of MVAC architecture and methods for enhancement were also presented.
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Fourie, Gert. "Power system stabilizer and controlled series capacitor small-signal stability performance analysis." Thesis, Stellenbosch : Stellenbosch University, 2002. http://hdl.handle.net/10019.1/53013.

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Thesis (MScEng)--University of Stellenbosch, 2002.<br>ENGLISH ABSTRACT: This thesis presents results of a study on the small-signal stability of a single-machine infinite-bus power system. Conditions of generator loading and network impedance are identified that require additional stability support. Two methods of stability enhancement are investigated, namely the power system stabilizer and the controlled series capacitor. Both stabilizers employ the conventional (classic) control structure, and parameters are evaluated for optimum performance using an integral-of-the-squared-error-based method. Results for damping capability versus generator loading and system impedance were generated. The ability of the power system stabilizer and controlled series capacitor to provide stability support is compared. This comparison is based on (a) the ability to provide more damping torque when needed, and (b) the amount of damping torque contributed by the stabilizer.<br>AFRIKAANSE OPSOMMING: Hierin word die resultate van 'n studie op die klein-sein stabiliteit van 'n enkel-masjien oneindige-bus kragstelsel weergegee. Kondisies van generator belasting en netwerk impedansie waar dempings-ondersteuning benodig word, word geïdentifiseer. Twee metodes van stabiliteits-verbetering word ondersoek, naamlik die kragstelstel stabiliseerder en die beheerde serie kapasitor. Beide stabiliseerders maak gebruik van die konvensionele (klassieke) beheerstruktuur, waarvan parameters geëvalueer word deur gebruik te maak van 'n integraal-van-die-vierkant-fout-gebaseerde metode. Resultate vir dempingsvermoë teenoor generator belasting en stelsel impedansie word verkry. Die vermoë van die kragstelsel stabiliseerder en beheerde serie kapasitor om stabiliteits-ondersteuning te verskaf, word vergelyk. Hierdie vergelyking is gebasseer op (a) die vermoë om meer dempingswrinkrag te voorsien wanneer benodig, en (b) die hoeveelheid dempingswrinkrag deur die stabiliseerder bygedra.
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Mudau, Dovhani Selby. "Comparison of three power system software packages for small-signal stability analysis." Master's thesis, University of Cape Town, 2009. http://hdl.handle.net/11427/8935.

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Includes bibliographical references (leaves 131-133).<br>Many power system simulation tools exist for small-signal stability analysis. This is due to the rapid development of computer systems, higher industrial growth and the need for reliable power system simulation tools for efficient planning and control of electric power systems. Three power system small-signal stability simulation tools have been selected for comparison and these are: PSAT 2.1.2, MatNetEig and PacDyn 8.1.1. These combine both open and closed source code industrial-grade power system analysis tools. The objective of this thesis is to compare three simulation tools on power system small-signal stability analysis. Input formats, data output flexibility, dynamic components and synchronous machine saturation modelling in all three simulation tools were amongst other features investigated for comparative studies.
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Aree, Pichai. "Small-signal stability modelling and analysis of power systems with electronically controlled compensation." Thesis, University of Glasgow, 2000. http://theses.gla.ac.uk/2600/.

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Flexible AC Transmission Systems (FACTS) equipment is currently being incorporated into the power system for controlling key networks parameters aiming at improving the power system steady-state and dynamic performances. The vast array of power system analysis tools used by planners and system operators, on a daily basis, for the successful running of the network are to be upgraded to include comprehensive modelling for FACTS plant components. Commensurate with this global objective, this research work is aimed at developing comprehensive power system models of FACTS devices suitable for small-signal stability studies. The FACTS components covered in this research are the Static Var Compensator (SVC) and the Thyristor-Controlled Series Capacitor (TCSC). More specifically, the modelling of these devices combined with advanced modelling of synchronous generators has positioned the current work in the area of small-signal stability modelling and analysis of power systems with electronically controlled compensation. The work has been developed within the framework of the block-diagram methodology because it yields physical insight and offers the opportunity to gain fundamental knowledge of the dynamic interactions taking place between synchronous generators and FACTS plant components. The key issues of synchronous generator modelling, from the viewpoint of small-signal stability analysis, are addressed in this thesis. In particular, the impact of synchronous generator modelling order, with emphasis on system damping, is discussed in depth. Various representations of salient-pole synchronous generators are used to enable a variety of models suitable for small-signal stability studies. The models range from synchronous generators with no danger windings, to cases when one damper winding is included in each of the rotor axes, i.e. d and q-axis. The drive behind the study is to settle the issue of what is a suitable number of machine damper windings to be used in small-signal stability analysis that adequately represents the system model with a good level of reliability while keeping engineering complexity manageable.
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Li, Chi. "Impedance-Based Stability Analysis in Power Systems with Multiple STATCOMs in Proximity." Diss., Virginia Tech, 2018. http://hdl.handle.net/10919/85053.

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Multiple STATCOM units in proximity have been adopted in power transmission systems in order to obtain better voltage regulation and share burdens. Throughout stability assessment in this dissertation, it is shown, for the first time, that STATCOMs could interact with each other in a negative way in the small-signal sense due to their control, causing voltage instability, while loads and transmission lines showed small effects. Since this voltage stability problem is induced by STATCOMs, d-q frame impedance-based stability analysis was used, for the first time, to explore the inherent power system instability problem with presence of STATCOMs as it provides an accurate understanding of the root cause of instability within the STATCOM control system. This dissertation first proposes the impedance model in d-q frame for STATCOMs, including dynamics from synchronization, current and voltage loops and reveals the significant features compared to other types of grid-tied converters that 1) impedance matrix strongly coupled in d and q channel due to nearly zero power factor, 2) different behaviors of impedances at low frequency due to inversed direction of reactive power and 3) coupled small-signal propagation paths on the voltage at point of common coupling from synchronization and ac voltage regulation. Using the proposed impedance model, this dissertation identifies the frequency range of interactions in a viewpoint of d-q frame impedances and pinpointed that the ac voltage regulation was the main reason of instability, masking the effects of PLL in power transmission systems. Due to the high impedance of STATCOMs compared to that of transmission lines around the frequency range of interactions, STATCOMs were seen to interact with each other through the transmission lines. A scaled-down 2-STATCOM power grid was built to verify the conclusions experimentally.<br>Ph. D.
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Lin, Qing. "Small-Signal Modeling and Stability Specification of a Hybrid Propulsion System for Aircrafts." Thesis, Virginia Tech, 2021. http://hdl.handle.net/10919/103515.

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This work utilizes the small-signal impedance-based stability analysis method to develop stability assessment criteria for a single-aisle turboelectric aircraft with aft boundary-layer propulsion (STARC-ABL) system. The impedance-based stability analysis method outperforms other stability analysis methods because it does not require detailed information of individual components for system integration, therefore, a system integrator can just require the vendors to make the individual components meet the impedance specifications to ensure whole system stability. This thesis presents models of a generator, motor, housekeeping loads, and battery all with power electronics interface which form an onboard electrical system and analyzes the relationship between the impedance shape of each component and their physical design and control loop design. Based on the developed small-signal model of the turbine-generator-rectifier subsystem and load subsystem, this thesis analyzes the impact of electromechanical dynamics of the turbofan passed through the generator on the dc distribution system, concluding that the rectifier can mitigate the impact. Finally, to ensure the studied system stable operation during the whole flying profile, the thesis provides impedance specifications of the dc distribution system and verifies the specifications with several cases in time-domain simulations.<br>M.S.<br>Electric aircraft propulsion (EAP) technologies have been a trend in the aviation industry for their potential to reduce environmental emissions, increase fuel efficiency and reduce noise for commercial airplanes. Achieving these benefits would be a vital step towards environmental sustainability. However, the development of all-electric aircraft is still limited by the current battery technologies and maintenance systems. The single-aisle turboelectric aircraft with aft boundary-layer (STARC-ABL) propulsion concept is therefore developed by NASA aiming to bridge the gap between the current jet fuel-powered aircraft and future all-electric vehicles. The plane uses electric motors powered by onboard gas turbines and transfers the generated power to other locations of the airplane like the tail fan motor to provide distributed propulsion. Power electronics-based converter converts electricity in one form of electricity to another form, for example, from ac voltage to dc voltage. This conversion of power is very important in the whole society, from small onboard chips to Mega Watts level electrical power system. In the aircraft electrical power system context, power electronics converter plays an important role in the power transfer process especially with the recent trend of using high voltage dc (HVDC) distribution instead of conventional ac distribution for the advantage of increased efficiency and better voltage regulation. The power generated by the electric motors is in ac form. Power electronics converter is used to convert the ac power into dc power and transfer it to the dc bus. Because the power to drive the electric motor to provide distributed propulsion is also in ac form, the dc power needs to be converted back into ac power still through a power electronics converter. With a high penetration of power electronics into the onboard electrical power system and the increase of electrical power level, potential stability issues resulted from the interactions of each subsystem need to be paid attention to. There are mainly two stability-related studies conducted in this work. One is the potential cross-domain dynamic interaction between the mechanical system and the electrical system. The other is a design-oriented study to provide sufficient stability margin in the design process to ensure the electrical system’s stable operation during the whole flying profile. The methodology used in this thesis is the impedance-based stability analysis. The main analyzing process is to find an interface of interest first, then grouped each subsystem into a source subsystem and load subsystem, then extract the source impedance and load impedance respectively, and eventually using the Nyquist Criterion (or in bode plot form) to assess the stability with the impedance modeling results. The two stability-related issues mentioned above are then studied by performing impedance analysis of the system. For the electromechanical dynamics interaction study, this thesis mainly studies the rotor dynamics’ impact on the output impedance of the turbine-generator-rectifier system to assess the mechanical dynamics’ impact on the stability condition of the electrical system. It is found that the rotor dynamics of the turbine is masked by the rectifier; therefore, it does not cause stability problem to the pre-tuned system. For the design-oriented study, this thesis mainly explores and provides the impedance shaping guidelines of each subsystem to ensure the whole system's stable operation. It is found that the stability boundary case is at rated power level, the generator voltage loop bandwidth is expected to be higher than 300Hz, 60˚ to achieve a 6dB, 45˚ stability margin, and load impedance mainly depends on the motor-converter impedance.
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Chompoobutrgool, Yuwa. "Concepts for Power System Small Signal Stability Analysis and Feedback Control Design Considering Synchrophasor Measurements." Licentiate thesis, KTH, Elektriska energisystem, 2012. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-103032.

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In the Nordic power network, the existence of poorly damped low-frequency inter-area oscillations (LFIOs) has long affected stability constraints, and thereby, limited power transfer capacity. Adequate damping of inter-area modes is, thus, necessary to secure system operation and ensure system reliability while increasing power transfers. Power system stabilizers (PSS) is a prevalent means to enhance the damping of such modes. With the advent of phasor measurement units (PMUs), it is expected that wide-area damping control (WADC), that is, PSS control using wide-area measurements obtained from PMUs, would effectively improve damping performance in the Nordic grid, as well as other synchronous interconnected systems. Numerous research has investigated one ``branch'' of the problem, that is, PSS design using various control schemes. Before addressing the issue of controller design, it is important to focus on developing proper understanding of the ``root'' of the problem: system-wide oscillations, their nature, behavior and consequences. This understanding must provide new insight on the use of PMUs for feedback control of LFIOs. The aim of this thesis is, therefore, to lay important concepts necessary for the study of power system small signal stability analysis that considers the availability of synchrophasors as a solid foundation for further development and implementation of ideas and related applications. Particularly in this study, the focus is on the application addressed damping controller design and implementation. After a literature review on the important elements for wide-area damping control (WADC), the thesis continues with classical small signal stability analysis of an equivalent Nordic model; namely, the KTH-NORDIC32 which is used as a test system throughout the thesis. The system's inter-area oscillations are identified and a sensitivity analysis of the network variables directly measured by synchrophasors is evaluated. The concept of network modeshapes, which is used to relate the dynamical behavior of power systems to the features of inter-area modes, is elaborated. Furthermore, this network modeshape concept is used to determine dominant inter-area oscillation paths, the passageways containing the highest content of the inter-area oscillations. The dominant inter-area paths are illustrated with the test system. The degree of persistence of dominant paths in the study system is determined through contingency studies. The properties of the dominant paths are used to construct feedback signals as input to the PSS. Finally, to exemplify the use of the dominant inter-area path concept for damping control, the constructed feedback signals are implemented in a PSS modulating the AVR error signal of a generator on an equivalent two-area model, and compared with that of conventional speed signals.
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Jiao, Yu Ming. "MPI parallel computing on eigensystems of small signal stability analysis for large interconnected power grids." Thesis, McGill University, 2010. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=95151.

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Eigenanalysis is widely used in power system stability study. With PC technologies available today, it takes long time to compute the entire eigensystems of large interconnected power grids. Since power transmission lines are connected & disconnected and line loads keep changing frequently, tracking eigensystems in real-time requires parallel computation. Recently, a parallel eigensystem computation method, the Break and Bind (B & B) method, has been proposed by Dr. H. M. Banakar in McGill University. This method is viewing connection of two isolated sub-networks as being equivalent to a rank-one modification (ROM) of the stiffness matrix and considering the two sub-networks as a single entity. Research of this thesis consists of implementing the B & B method based on Message Passing Interface (MPI) parallel programming in #C. The developed MPI codes were executed on super-computers - Krylov cluster of CLUMEQ and Mammouth Series II cluster of RQCHP. The testing results have demonstrated that the eigensystem of a power system composed of around 4,000 generators can be updated within two seconds.<br>L'analyse des valeurs propres est largement utilisée dans les études de stabilité des réseaux électriques. En utilisant les ordinateurs personnels disponibles aujourd'hui, le calcul de la totalité des valeurs propres de plusieurs grands réseaux électriques interconnectés requiert beaucoup de temps. Étant donné que les lignes de transport d'électricité sont connectées et déconnectées et que les charges ne cessent de varier, le suivi des valeurs propres en temps réel nécessite des calculs en parallèles. Récemment, une méthode de calcul en parallèle des valeurs propres, la Break et Bind (B & B), a été proposée par le Dr. H. M. Banakar à l'Université McGill. Cette méthode voit la connexion de deux sous-réseaux isolés comme étant équivalent à une modification de rang un de la matrice de raideur et considère les deux sous-réseaux comme une entité entière. La recherche de cette thèse consiste à implanter la méthode B & B avec une programmation parallèle en #C basé sur l'interface Message Passing Interface (MPI). Le code de programmation développé en MPI a été exécuté avec des superordinateurs - Krylov de CLUMEQ et Mammouth série II de RQCHP. Les résultats des tests ont démontrés que les valeurs propres d'un système composé d'environ 4,000 alternateurs peuvent être calculées à l'intérieur de deux secondes.
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Shah, Shahil. "Small and Large Signal Impedance Modeling for Stability Analysis of Grid-connected Voltage Source Converters." Thesis, Rensselaer Polytechnic Institute, 2018. http://pqdtopen.proquest.com/#viewpdf?dispub=10786614.

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<p> Interactions between grid-connected converters and the networks at their terminals have resulted in stability and resonance problems in converter-based power systems, particularly in applications ranging from wind and PV farms to electric traction and HVDC transmission networks. Impedance-based modeling and analysis methods have found wide acceptance for the evaluation of these resonance problems. </p><p> This thesis presents small and large signal impedance modeling of grid-connected single and three phase voltage source converters (VSC) to enable the analysis of resonance conditions involving multiple frequency components, and both the ac and dc power systems at the VSC terminals. A modular impedance modeling approach is proposed by defining the VSC impedance as transfer matrix, which captures the frequency cross-coupling effects and also the coupling between the ac and dc power systems interfaced by the VSC. Ac and dc impedance models are developed for a VSC including the reflection of the network on the other side of the VSC. Signal-flow graphs for linear time-periodic (LTP) systems are proposed to streamline and visually describe the linearization of grid-connected converters including the frequency cross-coupling effects. Relationships between the impedance modeling in dq, sequence, and phasor domains are also developed. The phasor-domain impedance formulation links the impedance methods with the phasor-based state-space modeling approach generally used for bulk power systems. A large-signal impedance based method is developed for predicting the amplitude or severity of resonance under different grid conditions. The small-signal harmonic linearization method is extended for the large-signal impedance modeling of grid-connected converters. It is shown that the large-signal impedance of a converter is predominantly shaped by hard nonlinearities in the converter control system such as PWM saturation and limiters. </p><p> This thesis also deals with the problem of synchronizing a generator or microgrid with another power system. A VSC-based synchronizer is proposed for active phase synchronization and a distributed synchronization method is developed for microgrids.</p><p>
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Books on the topic "Small-Signal Stability Analysis"

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Du, Wenjuan, Haifeng Wang, and Siqi Bu. Small-Signal Stability Analysis of Power Systems Integrated with Variable Speed Wind Generators. Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-94168-4.

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Mondal, Debasish, Abhijit Chakrabarti, and Aparajita Sengupta. Power System Small Signal Stability Analysis and Control. Elsevier Science & Technology, 2020.

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Power System Small Signal Stability Analysis and Control. Elsevier Science & Technology Books, 2014.

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Power System Small Signal Stability Analysis and Control. Elsevier Science & Technology Books, 2020.

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Power System Small Signal Stability Analysis and Control. Elsevier, 2020. http://dx.doi.org/10.1016/c2018-0-02439-1.

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Power System Small Signal Stability Analysis and Control. Elsevier, 2014. http://dx.doi.org/10.1016/c2013-0-18470-x.

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Parniani, Mostafa. Small-signal stability analysis and robust control design of static var compensators. 1995.

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Wang, Haifeng, Wenjuan Du, and Siqi Bu. Small-Signal Stability Analysis of Power Systems Integrated with Variable Speed Wind Generators. Springer, 2019.

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Book chapters on the topic "Small-Signal Stability Analysis"

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Wu, Keng C. "Small-Signal Stability Analysis." In Pulse Width Modulated DC-DC Converters. Springer US, 1997. http://dx.doi.org/10.1007/978-1-4615-6021-0_6.

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Murugan, A., S. Jayaprakash, and R. Raghavan. "Contingency Analysis Reliability Evaluation of Small-Signal Stability Analysis." In Advances in Power Systems and Energy Management. Springer Singapore, 2017. http://dx.doi.org/10.1007/978-981-10-4394-9_24.

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Aluf, Ofer. "Small Signal (SS) Amplifiers and Matching Network Stability Analysis." In Microwave RF Antennas and Circuits. Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-45427-6_4.

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Zhang, Xiao-Ping, Christian Rehtanz, and Bikash Pal. "Modeling of Power Systems for Small Signal Stability Analysis with FACTS." In Flexible AC Transmission Systems: Modelling and Control. Springer Berlin Heidelberg, 2012. http://dx.doi.org/10.1007/978-3-642-28241-6_13.

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Nazari, Masoud Honarvar. "Small-Signal Stability Analysis of Electric Power Systems on the Azores Archipelago." In Power Electronics and Power Systems. Springer US, 2013. http://dx.doi.org/10.1007/978-0-387-09736-7_17.

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Du, Wenjuan, Haifeng Wang, and Siqi Bu. "Small-Signal Stability of a Power System with a VSWG Affected by the PLL." In Small-Signal Stability Analysis of Power Systems Integrated with Variable Speed Wind Generators. Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-94168-4_6.

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Zhang, Lin, Dengmeng Fu, and Haoxing Liu. "The Small-Signal Model Stability Analysis of Full-Bridge Buck Converter with Compensation Network." In Lecture Notes in Electrical Engineering. Springer Berlin Heidelberg, 2012. http://dx.doi.org/10.1007/978-3-642-33741-3_19.

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Du, Wenjuan, Haifeng Wang, and Siqi Bu. "Introduction." In Small-Signal Stability Analysis of Power Systems Integrated with Variable Speed Wind Generators. Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-94168-4_1.

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Du, Wenjuan, Haifeng Wang, and Siqi Bu. "Linearized Model of a Power System with a Grid-Connected Variable Speed Wind Generator." In Small-Signal Stability Analysis of Power Systems Integrated with Variable Speed Wind Generators. Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-94168-4_2.

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Du, Wenjuan, Haifeng Wang, and Siqi Bu. "Damping Torque Analysis of Small-Signal Angular Stability of a Power System Affected by Grid-Connected Wind Power Induction Generators." In Small-Signal Stability Analysis of Power Systems Integrated with Variable Speed Wind Generators. Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-94168-4_3.

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Conference papers on the topic "Small-Signal Stability Analysis"

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Biteznik, C. E., J. L. Aguero, and M. C. Beroqui. "Flexible tool for small signal stability analysis." In 2014 IEEE Power & Energy Society General Meeting. IEEE, 2014. http://dx.doi.org/10.1109/pesgm.2014.6939194.

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Karimi, A., A. Pirayesh, T. S. Aghdam, and M. Ajalli. "DC micro grid small signal stability analysis." In 18th Electric Power Distribution Network Conference. IEEE, 2013. http://dx.doi.org/10.1109/epdc.2013.6565958.

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Ulianov, Y., and S. Lain. "Small signal stability analysis of Jepirachi wind park." In 2012 IEEE International Symposium on Alternative Energies and Energy Quality (SIFAE). IEEE, 2012. http://dx.doi.org/10.1109/sifae.2012.6478909.

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Ndiwulu, Guy Wanlongo, Emmanuel De Jaeger, and Angelo Kuti Lusala. "Islanded Microgrid Voltage Control Structure Small-Signal Stability Analysis." In 2019 IEEE Milan PowerTech. IEEE, 2019. http://dx.doi.org/10.1109/ptc.2019.8810896.

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Ghimire, Sulav, Prabhat Kiran Dhital, and Arbind Kumar Mishra. "Small Signal Stability Analysis Toolbox: A MATLAB based GUI." In 2019 Second International Conference on Advanced Computational and Communication Paradigms (ICACCP). IEEE, 2019. http://dx.doi.org/10.1109/icaccp.2019.8883006.

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Zhao Yang Dong. "Genetic algorithms in power system small signal stability analysis." In APSCOM-97. International Conference on Advances in Power System Control, Operation and Management. IEE, 1997. http://dx.doi.org/10.1049/cp:19971857.

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Liu, Muyang, Ioannis Dassios, and Federico Milano. "Small-signal stability analysis of neutral delay differential equations." In IECON 2017 - 43rd Annual Conference of the IEEE Industrial Electronics Society. IEEE, 2017. http://dx.doi.org/10.1109/iecon.2017.8216978.

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Rowe, C. N., T. J. Summers, R. E. Betz, and D. J. Cornforth. "Small signal stability analysis of arctan power frequency droop." In 2011 IEEE Ninth International Conference on Power Electronics and Drive Systems (PEDS 2011). IEEE, 2011. http://dx.doi.org/10.1109/peds.2011.6147343.

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Ridwan, Muhammad, Joko Hartono, Didik Fauzi Dakhlan, and Eko Aptono Tri Yuwono. "Small Signal Stability Analysis as Impact of System Reconfiguration." In 2019 2nd International Conference on High Voltage Engineering and Power Systems (ICHVEPS). IEEE, 2019. http://dx.doi.org/10.1109/ichveps47643.2019.9011155.

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Li Meiyan, Ma Jin, and Z. Y. Dong. "Uncertainty analysis of load models in small signal stability." In 2009 International Conference on Sustainable Power Generation and Supply. SUPERGEN 2009. IEEE, 2009. http://dx.doi.org/10.1109/supergen.2009.5348369.

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