Your search keyword '"Eigenvalue analysis"' showing total 1,464 results

1. Flow characteristics analysis and combustion oscillation mitigation of a hydrogen industrial burner.

Author

Zhang, Long, Li, Shan, Liu, Tengyu, Zhou, Hua, and Ren, Zhuyin

Subjects

*LARGE eddy simulation models, *MODAL analysis, *CARBON offsetting, *HYDROGEN analysis, *COMBUSTION

Abstract

With the promotion of carbon neutrality policies, hydrogen burners are widely used in the industrial field, and exploring the combustion characteristics and stable combustion technology of hydrogen industrial burners has important engineering application significance. This study investigates the flow characteristics and combustion oscillation mitigation of a specific hydrogen industrial burner for heating thermal oil through experiments and numerical simulations. The oscillating combustion with a frequency of 100 Hz is discovered during the field test. The dynamic characteristics are reproduced via large eddy simulation (LES), and the pressure amplitude is reduced by 22% via the active control strategy. LES results show that corner recirculation zone and main recirculation zone occur in the flame holding chamber, with maximum recirculation velocity and maximum temperature of −20 m/s and 2110 K, respectively. The unstable modes and key elementary reactions are revealed by modal analysis and eigen-analysis. The clustered neural network with horizons (CNNH) controller is constructed to suppress the combustion instability. The CNNH controller can effectively suppress the pressure oscillation by perturbing the inlet mass flow rate of main H 2 , reducing the peak amplitude in the frequency domain by 67%. By optimizing the controller parameters, the CNNH controller can be further applied to different scenarios of hydrogen industrial burners. • Flow characteristics of a hydrogen industrial burner are analysed with LES. • Oscillating combustion is analysed by modal analysis and eigen-analysis. • Dominant species and reactions are identified during oscillating combustion. • Active control strategy is constructed to suppress the oscillating pressure. • The influence of controller parameters on control performance is studied. [ABSTRACT FROM AUTHOR]

Published

2025

2. Constructive eigenvalue analysis based velocity observer design for mechanical systems.

Author

Wen, Haowei, Liu, Li, Shi, Peng, Yue, Xiaokui, and Gong, Shengping

Abstract

This paper presents a novel and constructive solution for the velocity estimation of a large class of mechanical systems. By employing the technical results in non-smooth analysis, a specific eigenvalue analysis problem that can be systematically solved through structured computational procedures is formulated, and the resulting globally exponentially convergent observer can therefore be generated automatically for any appropriate model input with arbitrarily complex configurations. The proposed method applies directly to non-holonomic systems with Pfaffian constraints, and its structural simplification can be further achieved for systems with uniformly bounded inertia matrix. The established results provide a major breakthrough on both the dimension and practical realizability of the prevailing Immersion & Invariance velocity observer designs, and its effectiveness is verified with numerical simulations of several representative examples. [ABSTRACT FROM AUTHOR]

Published

2024

3. Small-Signal Modeling of Grid-Forming Wind Turbines in Active Power and DC Voltage Control Timescale.

Author

Jiang, Kezheng, Ji, Xiaotong, Liu, Dan, Zheng, Wanning, Tian, Lixing, and Chen, Shiwei

Subjects

REACTIVE power, VOLTAGE control, WIND turbines, VOLTAGE, SYNCHRONOUS generators

Abstract

Grid-forming wind turbines (GFM-WTs) based on virtual synchronous control can support the voltage and frequency of power system by emulating the synchronous generator. The dynamic characteristics of a GFM-WT decided by virtual synchronous control, dq-axis voltage, and current control is significant for small-signal stability analysis. This paper builds a small-signal model of a GFM-WT in active power control (APC) and DC voltage control (DVC) timescale from the perspective of internal voltage. The proposed model describes how the magnitude and phase of the internal voltage are excited by the unbalanced active and reactive power when small disturbances occur. Interactions in different control loops can be identified by the reduced order model. We verify the accuracy of the proposed model in APC and DVC timescales by time domain simulations based on MATLAB/Simulink. Case studies show how the control parameters interact with each other in the two timescales. [ABSTRACT FROM AUTHOR]

Published

2024

4. Two RMIL-type schemes with compressed sensing applications.

Author

Ahmed, Kabiru, Waziri, Mohammed Yusuf, Sani Halilu, Abubakar, and Murtala, Salisu

Subjects

*NONLINEAR equations, *COMPRESSED sensing, *SEARCH algorithms, *IMAGE analysis, *EIGENVALUES

Abstract

It has been proven that the conjugate gradient (CG) method by Rivaie, Mustafa, Ismail and Leong (RMIL) (Appl. Math. Comput. 218 (2012) 11323–11332), does not satisfy the sufficient descent condition, and its global convergence is attained only by employing the exact line search (ELS) procedure. In this study, two RMIL-type algorithms are proposed for system of monotone nonlinear equations, where both properties hold regardless of the line search strategy used. Two approximations of the nonnegative parameter that is embedded in search directions of the algorithms are determined by analysing eigenvalues and singular values of their iteration matrices. The new solvers are also ideal for nonsmooth problems. Four recent solvers are employed to show effectiveness of the new methods. Furthermore, the schemes are used to solve some signal and image recovery problems. [ABSTRACT FROM AUTHOR]

Published

2024

5. Adaptive hybrid synchronization control of grid-connected converters in renewable power plants and its small-signal stability analysis

Author

GONG Kai, XIAO Huangqing, ZHANG Zhan, HE Hongliang, HUANG Ying, and LI Yan

Subjects

grid-following control, grid-forming control, hybrid synchronous control loop, small signal stability, eigenvalue analysis, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

As the capacity of renewable power plants connected to the grid increases year by year， optimizing the control strategies for their converters becomes crucial for enhancing system stability. Currently， the primary control strategies in renewable power plants focus on grid-following （GFL） and grid-forming （GFM） converters. The former tends to exhibit poor stability in weak grids， while the latter may lose stability in strong grids. To address this challenge， the paper first proposes a hybrid synchronous control structure for grid-connected converters that incorporates adaptive coefficients. This structure combines the phase-locked loop （PLL） commonly used by GFL converters with the power-synchronization loop （PSL） utilized by GFM converters， creating a hybrid synchronous control loop through a proportional coefficient. Subsequently， the corresponding small-signal model is developed， and based on the analysis results of small-signal stability， a method for determining adaptive parameter values is introduced. Finally， simulation results validate that the converter-connected system employing adaptive hybrid synchronous control maintains good stability in weak grids with a short-circuit ratio of 1 and in strong grids with a short-circuit ratio of 30. This provides a new control scheme suitable for the stable operation of grid-connected converters in renewable power plants under varying grid conditions.

Published

2024

6. Topology optimization for minimum dynamic compliance using an antiresonant frequency constraint.

Author

Meng, Fanwei, Meng, Liang, Wang, Jintao, Zhu, Jihong, Wang, Bo Ping, Yuan, Shangqin, and Zhang, Weihong

Abstract

As studied in previous works, dynamic compliance presents widespread antiresonances in its spectrum, which could trap gradient-based topology optimization for minimum dynamic compliance and cause the optimization procedure to converge prematurely. In order to solve this problem, a novel method for predicting the frequencies that correspond to points of antiresonance in dynamic compliance spectrum is presented in this paper. By leveraging this eigenvalue formulation method, a strategy for introducing antiresonant frequency constraint is developed to solve one-material topology design for minimum dynamic compliance under high-frequency (above the first resonance of the initial design) excitations. In order to facilitate the exploitation of antiresonances, accurate track and eigenvalue sensitivity analysis for the prescribed antiresonant frequency are also discussed in detail. Numerical results show that the proposed method can achieve well-defined topologies with excellent dynamic performance. [ABSTRACT FROM AUTHOR]

Published

2024

7. 一类具有交叉反应扩散的 捕食-食饵模型的动态分歧.

Author

亓子成, 刘瑞宽, and 吴辰龙

Subjects

FINITE difference method, BIFURCATION theory, SPECTRAL theory, NUMERICAL analysis, EIGENVALUES, HOPF bifurcations

Abstract

Copyright of Journal of Jilin University (Science Edition) / Jilin Daxue Xuebao (Lixue Ban) is the property of Zhongguo Xue shu qi Kan (Guang Pan Ban) Dian zi Za zhi She and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

8. Rotating Stall Inception Prediction Using an Eigenvalue-Based Global Instability Analysis Method †.

Author

Xu, Shenren, Yuan, Caijia, He, Chen, Cao, Dongming, Sun, Dakun, Martel, Carlos, Chen, Huihao, and Wang, Dingxi

Subjects

DYNAMICAL systems, EIGENANALYSIS, EIGENVECTORS, FORECASTING, GLOBAL analysis (Mathematics)

Abstract

The accurate prediction of rotating stall inception is critical for determining the stable operating regime of a compressor. Among the two widely accepted pathways to stall, namely, modal and spike, the former is plausibly believed to originate from a global linear instability, and experiments have partially confirmed it. As for the latter, recent computational and experimental findings have shown it to exhibit itself as a rapidly amplified flow perturbation. However, rigorous analysis has yet to be performed to prove that this is due to global linear instability. In this work, an eigenanalysis approach is used to investigate the rotating stall inception of a transonic annular cascade. Steady analyses were performed to compute the performance characteristics at a given rotational speed. A numerical stall boundary was first estimated based on the residual convergence behavior of the steady solver. Eigenanalyses were then performed for flow solutions at a few near-stall points to determine their global linear stability. Once the relevant unstable modes were identified according to the signs of real parts of eigenvalues, they were examined in detail to understand the flow destabilizing mechanism. Furthermore, time-accurate unsteady simulations were performed to verify the obtained eigenvalues and eigenvectors. The eigenanalysis results reveal that at the rotating stall inception condition, multiple unstable modes appear almost simultaneously with a leading mode that grows most rapidly. In addition, it was found that the unstable modes are continuous in their nodal diameters, and are members of a particular family of modes typical of a dynamic system with cyclic symmetries. This is the first time such an interesting structure of the unstable modes is found numerically, which to some extent explains the rich and complex results constantly observed from experiments but have never been consistently explained. The verified eigenanalysis method can be used to predict the onset of a rotating stall with a CPU time cost orders of magnitude lower than time-accurate simulations, thus making compressor stall onset prediction based on the global linear instability approach feasible in engineering practice. [ABSTRACT FROM AUTHOR]

Published

2024

9. Analysis of Low-Frequency Oscillations in the Bosnia and Herzegovina Power System.

Author

Dedović, Maja Muftić, Avdaković, Samir, Alihodžić, Ajdin, and Memić, Adin

Subjects

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

10. Buckling and Post-buckling Analyses of Porous Composite Plates

Author

Mohsin, Mateen, Patel, B. P., Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Tolio, Tullio A. M., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Schmitt, Robert, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Chandrashekara, C. V., editor, Mathivanan, N. Rajesh, editor, and Hariharan, K., editor

Published

2024

11. Research on Variable Droop Control Method for Improving Stability of Low-Voltage DC Distribution System

Author

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

12. Seismic performance evaluation of concrete buttress dram (Dynamic linear analysis)

Author

Al-Bayati Noor Nazar, Arslan Chelang A., and Hassan Waqed H.

Subjects

concrete buttress dam, khassa chi, diana fea, eigenvalue analysis, response spectrum analysis, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Due to a variety of reasons, including the water retained inside and the intrinsic weight of the dam itself, dam constructions have the ability to move both horizontally and vertically. If these displacements exceed a crucial limit, a dam’s structural integrity is jeopardized. Concrete buttress dams in particular may be susceptible to high-frequency vibrations because of their slender structure, especially when the flow of water is involved. The Khassa Chi Dam, which is located northeast of Kirkuk City, is the subject of this study’s attempt to offer an alternative since the constructed dam is an embankment dam. In this research, a concrete buttress dam design was studied as an alternative dam to the constructed one. Such designs exemplify one form of gravity dams widely implemented on diverse soil types. Finite element model (FEM) was employed to simulate the behavior of the dam. The simulation utilized DIANA FEA, which relies on governing equations. There are several steps involved in developing an accurate FEM that faithfully simulates the actual behavior of a dam and predicts its future responses. The model is evaluated in later analyses in terms of stress and displacement. In this context, RSA was conducted on the modeled buttress dam. The outcome of the displacement analysis of the buttress dam exhibited its safety across all load combinations after undergoing linear dynamic analysis. This analysis included Eigenvalue Analysis and RSA. The response remained low at seismic frequencies below 3 Hz, and the extent of displacement correlated with the frequency values.

Published

2024

13. Impact of Short-Circuit Ratio on Control Parameter Settings of DFIG Wind Turbines.

Author

Pedra, Joaquín, Sainz, Luis, and Monjo, Lluís

Subjects

*WIND turbines, *PHASE-locked loops, *DYNAMIC simulation, *EIGENVALUES, *INDUCTION generators

Abstract

This work deals with doubly fed induction generator (DFIG) modeling and stability when connected to weak AC grids. A detailed state-space model that includes the phase-locked loop (PLL) is developed. This work aims to determine the influence of the network's strength on DFIG stability through the short-circuit ratio (SCR). The critical values of the proportional control parameters of the grid-side and rotor-side converters (RSC and GSC), as well as PLL, which make the system unstable, are calculated for different SCR values. Finally, PSCAD/EMTDC dynamic simulations are used to validate the critical control parameters obtained by studying the eigenvalues of the DFIG state-space model regarding system stability. [ABSTRACT FROM AUTHOR]

Published

2024

14. Stability Analysis in Multi-VSC (Voltage Source Converter) Systems of Wind Turbines.

Author

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

15. Analysis of Grid-Connected Stability of VSG-Controlled PV Plant Integrated with Energy Storage System and Optimization of Control Parameters.

Author

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

16. 受端近区光伏电站对 LCC-HVDC 系统 稳定性影响分析.

Author

周于清, 李大虎, 姚伟, 宗启航, 周泓宇, and 文劲宇

Abstract

Copyright of Electric Power is the property of Electric Power Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

17. Applying Particle Swarm Optimization for Investigating the Stability of DC-DC Buck-Boost Converter: A Software Based Approach.

Author

Nishat, Mirza Muntasir, Sakib, Sadman, Rahman, Kazi Asif, Ahmed, Moshiur, Shagor, Md. Rafid Kaysar, Faisal, Fahim, and Ahmed, Ashik

Abstract

Stability of power converters has always been a major concern when dealing with nonlinear behavior of the system and swarm-based optimization techniques are proven to be handy as they are widely employed. Hence, this study presents an investigative approach to explore the compatibility of applying different variants of Particle Swarm Optimization (PSO) to design an optimized PID controller for DC-DC Buck-Boost converter. This work assesses converter stability through optimization of the PID controller using classical PSO (cPSO), Time-Varying Inertia Weight PSO (TVIW-PSO), Chaotic Descending Inertia Weight PSO (CDIW-PSO), Self-organizing Hierarchical PSO (HPSO) and Random inertia weight PSO (RIW-PSO). The State Space Average (SSA) method is utilized to model and attain the transfer function; eigenvalue analysis and time domain simulation analysis are considered to investigate the stability. Moreover, four objective functions and various performance parameters such as percentage of overshoot, rise time, settling time, and peak amplitude are tabulated to assess the system’s efficiency and the outcomes of different approaches are compared extensively. Amongst all, CDIW-PSO showcased better performances e.g. overshoot of 1.08%, settling time 0.000228s and rise time 0.000143s. The findings illustrate algorithm’s capacity to reduce transient and steady-state faults and makes it compatible with more nonlinear applications. [ABSTRACT FROM AUTHOR]

Published

2024

18. Analyzing wrinkling instabilities in constrained dielectric elastomers: A symplectic eigenvalue approach.

Author

ZHANG Teng

Subjects

PERMITTIVITY, ELASTOMERS, SURFACE waves (Seismic waves), EIGENVALUES, WAVENUMBER

Abstract

Copyright of Chinese Journal of Computational Mechanics / Jisuan Lixue Xuebao is the property of Chinese Journal of Computational Mechanics Editorial Office, Dalian University of Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

19. Advanced Mathematical Science for Mobility Society

Author

Ikeda, Kazushi, Kawamura, Yoshiumi, Makino, Kazuhisa, Tsujimoto, Satoshi, Yamashita, Nobuo, Yoshizawa, Shintaro, and Sumita, Hanna

Subjects

Mobility society, Many-body particle systems, Box-ball systems, Discrete integrable systems, LR transformations, Car-sharing systems, Control theory, Blockchains, Eigenvalue analysis, Tensor network formalism, Machine learning, Network algorithm, Mechanism design, thema EDItEUR::U Computing and Information Technology::UY Computer science::UYA Mathematical theory of computation, thema EDItEUR::P Mathematics and Science::PB Mathematics::PBW Applied mathematics::PBWH Mathematical modelling, thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBJ Maths for engineers, thema EDItEUR::U Computing and Information Technology::UN Databases, thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TN Civil engineering, surveying and building::TNH Highway and traffic engineering

Abstract

This open access book presents the mathematical methods for huge data and network analysis. The automotive industry has made steady progress in technological innovations under the names of Connected Autonomous-Shared-Electric (CASE) and Mobility as a Service (MaaS). Needless to say, mathematics and informatics are important to support such innovations. As the concept of cars and movement itself is diversifying, they are indispensable for grasping the essence of the future mobility society and building the foundation for the next generation. Based on this idea, Research unit named "Advanced Mathematical Science for Mobility Society" was established at Kyoto University as a base for envisioning a future mobility society in collaboration with researchers led by Toyota Motor Corporation and Kyoto University. This book contains three main contents. 1. Mathematical models of flow 2. Mathematical methodsfor huge data and network analysis 3. Algorithm for mobility society The first one discusses mathematical models of pedestrian and traffic flow, as they are important for preventing accidents and achieving efficient transportation. The authors mainly focus on global dynamics caused by the interaction of particles. The authors discuss many-body particle systems in terms of geometry and box-ball systems. The second one consists of four chapters and deals with mathematical technologies for handling huge data related to mobility from the viewpoints of machine learning, numerical analysis, and statistical physics, which also includes blockchain techniques. Finally, the authors discuss algorithmic issues on mobility society. By making use of car-sharing service as an example of mobility systems, the authors consider how to construct and analyze algorithms for mobility system from viewpoints of control, optimization, and AI.

Published

2024

20. Analysis and Dynamic Stabilization of a High-Voltage VSC-MTDC Grid With DC Power Flow Controller Connected to Extremely Weak AC Systems

Author

Hassanien Ramadan A. Mohamed, Yasser Abdel-Rady I. Mohamed, and Ehab F. El-Saadany

Subjects

Critical short-circuit ratio, eigenvalue analysis, multi-terminal dc (MTDC) grid, power flow controller (PFC), sensitivity analysis, small-signal stability, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The high-voltage voltage-source converter (VSC)-based multi-terminal dc (MTDC) grid is a key technology for integrating offshore wind energy and enabling bulk power transmission across nations and continents. This paper addresses the small-signal stability of an MTDC grid equipped with a power flow controller (PFC) under extremely weak ac system interconnections. Using a comprehensive linearized state-space model, eigenvalue analysis uncovers that beyond the well-documented low-frequency oscillations (LFO), an MTDC grid may experience unstable medium-frequency oscillations (MFO) under rectifier operation of droop voltage-controlled VSCs when interfaced to an extremely weak ac system. Moreover, it was shown that the most challenging scenario is when multiple droop voltage-controlled VSCs are interfaced to very weak ac systems, with unstable LFO and MFO observed at short-circuit ratio values of 1.4 and 1.8, respectively. Sensitivity analysis is conducted to assess the impact of the droop voltage control gains, PFC control parameters, and dc breaker reactor on the system dominant eigenmodes in such critical weak conditions. Simple yet efficient LFO and MFO compensators are proposed to stabilize the system, and their parameters design was detailed. Extensive simulation studies and real-time validation tests verify the analytical analysis and demonstrate the effectiveness of the proposed compensators and their feasibility for real-time implementation.

Published

2024

21. Classification of Converter-Driven Stability and Suitable Modeling and Analysis Methods

Author

Christina Eckel, Davood Babazadeh, and Christian Becker

Subjects

Converter-driven stability, converter interfaced generation, dynamic phasors, eigenvalue analysis, electromagnetic transients, impedance based analysis, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The significant increase of converter interfaced generation, consumption, storage, and transmission in power systems, results in the need to consider converter-driven stability in detail, as well as to study modelling and analysis methods with which such stability effects can be represented and investigated. Due to the multiple causes of converter-driven stability effects, a classification into further categories of fast and slow converter-driven stability is necessary, which is systematically presented in this paper. We further provide a detailed overview on appropriate modelling methods including static, quasi-dynamic and dynamic modelling and their respective applications. Typical analysis methods such as eigenvalue and impedance based analysis are explained and related to the previous modelling approaches. Based on that, a guide to which modelling and analysis method is appropriate for which type of converter-driven stability, is provided. In addition, open and recent research questions with regard to studies on nonlinear analyses of large systems with acceptable computational costs are pointed out.

Published

2024

22. Improved State-space Modelling for Microgrids Without Virtual Resistances

Author

Paranagamage S. A. Peiris, Shaahin Filizadeh, and Dharshana Muthumuni

Subjects

Low-voltage converter, state-space modelling, dynamic phasor, time-domain simulation, eigenvalue analysis, Production of electric energy or power. Powerplants. Central stations, TK1001-1841, Renewable energy sources, TJ807-830

Abstract

Power converters and their interfacing networks are often treated as modular state-space blocks for small-signal stability studies in microgrids; they are interconnected by matching the input and output states of the network and converters. Virtual resistors have been widely used in existing models to generate a voltage for state-space models of the network that require voltage inputs. This paper accurately quantifies the adverse impacts of adding the virtual resistance and proposes an alternative method for network modelling that eliminates the requirement of the virtual resistor when interfacing converters with microgrids. The proposed nonlinear method allows initialization, time-domain simulations of the nonlinear model, and linearization and eigenvalue generation. A numerically linearized small-signal model is used to generate eigenvalues and is compared with the eigenvalues generated using the existing modelling method with virtual resistances. Deficiencies of the existing method and improvements offered by the proposed modelling method are clearly quantified. Electromagnetic transient (EMT) simulations using detailed switching models are used for validation of the proposed modelling method.

Published

2024

23. Comprehensive Analysis and Stabilization of a B2B HVDC System Connecting Two Extremely Weak Grids Considering the Impact of Power Feedforward Compensation

Author

Hassanien Ramadan A. Mohamed and Yasser Abdel-Rady I. Mohamed

Subjects

B2B HVDC systems, stability analysis, critical short circuit ratio (CSCR), eigenvalue analysis, active compensators, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Back-to-Back (B2B) HVDC systems can enhance cross-regional transmission capacity and overall power system stability. However, their use in interconnecting two extremely weak grids can compromise system stability. This paper presents a comprehensive stability analysis of a B2B HVDC system to distinguish the root causes of instability mechanisms and identify the critical short circuit ratio (CSCR) of each converter station under inverter and rectifier operations considering the impact of power feedforward compensation of the dc-bus voltage controller. The study also investigates the stability implications and CSCR changes when a dc transmission line connects the converter stations, creating a point-to-point (P2P) HVDC system. Eigenvalue analysis, based on detailed small-signal modeling, showed that three distinct instability mechanisms, high-, low-, and medium-frequency instabilities, can compromise the operation of VSC stations under extremely weak grid conditions. Notably, the medium-frequency instability observed in the P2P HVDC system during inverter operation is predominantly caused by the power feedforward compensation of the dc-bus voltage controller. Furthermore, the analysis reveals that the CSCRs for dc-bus voltage-controlled VSC stations are higher in comparison to power-controlled ones. This suggests that a dc-bus voltage-controlled VSC is more susceptible to instability in weak grid scenarios than its power-controlled counterpart. Active compensators are designed based on participation factor analysis to mitigate the identified instabilities. The findings are validated with extensive simulations and real-time hardware-in-the-loop tests, demonstrating the analysis's accuracy and the proposed compensators' efficacy.

Published

2024

24. Subsynchronous oscillation analysis method based on broad learning system

Author

Ling Li, Yang Mao, Zhencheng Liang, Shaozhe Li, Cuiyun Luo, Yangtian Ning, Li Xiong, Yude Yang, and Bin Li

Subjects

Subsynchronous oscillations, Eigenvalue analysis, Broad learning system, Feature importance, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper presents a method to analyze the Sub Synchronous Oscillation (SSO) problem based on broad learning system (BLS), which can quickly analyze the risk of SSO in a system and take measures. The simulation system is constructed by the eigenvalue analysis method to obtain training data, that solves the problem which is difficult to obtain actual data in SSO problem and makes the model more accurate and the conclusion more convincing. Subsequently, BLS is applied for feature extraction and the prediction model is constructed, the model can show the deep relationship between the oscillation source and topology of the system as well as various operating data, which is difficult to be expressed by formula. The system was tested and validated in the 41-bus system. The feature importance analysis method which comes from eXtreme Gradient Boosting (XGboost) algorithm is proposed and combined with the BLS prediction model, which can analyze the influence of each variable on the prediction results in different series compensation levels, and is validated in the 41-bus system, that makes the results of prediction more interpretable. Finally, the results of simulation show that the model can predict data with high accuracy and give adjustment plans for effective control of the system to avoid the risk of SSO.

Published

2023

25. An adaptive wide-area neuro-fuzzy based controller for variable frequency transformer in damping inter-area oscillations

Author

Basit Mushtaq and Mairaj ud-din Mufti

Subjects

Variable Frequency Transformer, Adaptive neuro fuzzy inference system (ANFIS), Low-frequency Oscillation (LFO) Damping, Participation Factor (PF), Eigenvalue analysis, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Due to the dynamic, non-linear, and complex character of large-scale power networks, prolonged inadequately damped low frequency oscillations may develop, leading to loss of synchronisation of generating units. Flexible AC transmission controller when equipped with an appropriate additional damping mechanism offers substantial damping in mitigating these oscillations. In this context, a smart flexible transmission device namely variable frequency transformer (VFT) is integrated into a multimachine power system network to effectively damp low-frequency oscillations. An adaptive model free neuro-fuzzy inference system (ANFIS) based damping controller is developed for VFT in order to damp inter-area oscillations. The ANFIS is a resilient and intelligent system that combines fuzzy logic and neural network capabilities with attributes like robustness, adaptability, speed, and flexibility. The proposed damping controller, which provides additional damping proportionate to the frequency variation, was included into the VFT’s power loop. The controller input is determined as the center-of-inertia difference of generator rotor speeds and is a remote signal delivered by a wide-area measuring system. Depending on the observability of crucial modes, participation factor (PF) investigation is used to extract the appropriate feedback signal, which provides details on the overall the system’s dynamics. The ANFIS-based scheme for the VFT is designed to impart sufficient damping qualities to the critical modes of the examined system under a variety of operating conditions. Using extensive non-linear time-domain simulations and eigenvalue analysis, the effectiveness of the suggested technique was evaluated on a popular 2-area, 4-generator, 11-bus test system.

Published

2024

26. Eigenvalue Analyses on the Memoryless Davidon–Fletcher–Powell Method Based on a Spectral Secant Equation.

Author

Dargahi, Fatemeh, Babaie-Kafaki, Saman, and Aminifard, Zohre

Subjects

*EQUATIONS, *EIGENVALUES, *QUASI-Newton methods

Abstract

The subject of this study is the analysis of the spectral secant equation for the well-known Davidon–Fletcher–Powell (DFP) quasi-Newton updating formula. More precisely, we plan to make the memoryless DFP formula well conditioned in several aspects. We first focus our efforts on obtaining eigenvalues of the DFP formula and directly analyzing its spectral condition number. Then, we proceed in a different direction by using the Byrd–Nocedal measure function as well. Lastly, we propose a hybrid adaptive formula for the spectral parameter of the method. [ABSTRACT FROM AUTHOR]

Published

2024

27. SSR Mitigation in Power System by LQR Control of nearby DFIG.

Author

Patel, Nilaykumar A. and Patel, Khush N.

Subjects

SUBSYNCHRONOUS resonance, REACTIVE power, TEST systems, POWER semiconductor switches, SYNCHRONOUS generators, ELECTRIC lines, INDUCTION generators

Abstract

This study examines the influence of a direct-power control technique for a DFIG (Doubly-Fed Induction Generator)-based wind generator on sub-synchronous resonance (SSR). A series capacitor of a transmission line will exchange power with the synchronous generator when it runs via an SSR. DFIG includes power converters built into its rotor circuit, allowing for quick control of both the active and reactive power of the device. This is made possible by the rotor converter circuit's fast IGBT switching. Examining the ability of the LQR (Linear Quadratic Regulator) on the DFIG to provide the required active power and reactive power during SSR is the primary goal of this work. Additional DFIG is added to the test system in addition to the original test system, and during SSR its performance is evaluated using an additional control signal that is obtained from the synchronous generator and supplied to DFIG through LQR. The analysis of SSR was completed based on eigenvalue analysis utilizing the D-Q model test system and transient simulation using MATLAB Simulink. Independent model control is used to control the DFIG rotor converter that dampens multimodal SSR oscillations. The test system was developed using the IEEE first benchmark model's adopted system. [ABSTRACT FROM AUTHOR]

Published

2024

28. Stability of stationary solutions to a multidimensional parabolic–parabolic chemotaxis-consumption model.

Author

Li, Xiaowen and Li, Jingyu

Subjects

*CHEMOTAXIS, *OXYGEN consumption, *EIGENVALUES, *MULTIPLICITY (Mathematics)

Abstract

We study the dynamical stability of nontrivial steady states to a multidimensional parabolic–parabolic chemotaxis-consumption model in a bounded domain, where the physical zero-flux boundary condition for the bacteria and the nonhomogeneous Dirichlet boundary condition for the oxygen are prescribed. We first prove that the spectrum set of the linearized operator at the steady state only consists of eigenvalues with finite algebraic multiplicity. Then we show that all eigenvalues have negative real part if the concentration of the oxygen at boundary is small, or the diffusive coefficient of the oxygen is large, or is small. In the radial setting, we further show that all eigenvalues have negative real part without any assumption on the parameters. This result of spectral analysis implies the local asymptotic stability of the nontrivial steady states to the chemotaxis-consumption model under the above assumptions. [ABSTRACT FROM AUTHOR]

Published

2023

29. 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

30. Enhancing grid stability: a hybrid control strategy for DFIG-based wind turbines to mitigate sub-synchronous oscillations

Author

Anju, M., Shihabudheen, K. V., and Mija, S. J.

Published

2024

31. Impact of DFIM Controller Parameters on SSR Characteristics of Wind Energy Conversion System with Series Capacitor Compensation

Author

Velpula, Srikanth, Hussaian Basha, C. H., Manjusree, Y., Venkatesh, C., Prashanth, V., Rafikiran, Shaik, Bansal, Jagdish Chand, Series Editor, Deep, Kusum, Series Editor, Nagar, Atulya K., Series Editor, Shukla, Praveen Kumar, editor, Mittal, Himanshu, editor, and Engelbrecht, Andries, editor

Published

2023

32. Stability and Bifurcation Linear Analysis

Author

Luongo, Angelo, Ferretti, Manuel, Di Nino, Simona, Luongo, Angelo, Ferretti, Manuel, and Di Nino, Simona

Published

2023

33. Gaussian quantum particle swarm optimization-based wide-area power system stabilizer for damping inter-area oscillations

Author

Kondattu Mony, Sreedivya, Peter, Aruna Jeyanthy, and Durairaj, Devaraj

Published

2023

34. Rotating Stall Inception Prediction Using an Eigenvalue-Based Global Instability Analysis Method

Author

Shenren Xu, Caijia Yuan, Chen He, Dongming Cao, Dakun Sun, Carlos Martel, Huihao Chen, and Dingxi Wang

Subjects

rotating stall, global instability, eigenvalue analysis, unsteady simulation, Mechanical engineering and machinery, TJ1-1570

Abstract

The accurate prediction of rotating stall inception is critical for determining the stable operating regime of a compressor. Among the two widely accepted pathways to stall, namely, modal and spike, the former is plausibly believed to originate from a global linear instability, and experiments have partially confirmed it. As for the latter, recent computational and experimental findings have shown it to exhibit itself as a rapidly amplified flow perturbation. However, rigorous analysis has yet to be performed to prove that this is due to global linear instability. In this work, an eigenanalysis approach is used to investigate the rotating stall inception of a transonic annular cascade. Steady analyses were performed to compute the performance characteristics at a given rotational speed. A numerical stall boundary was first estimated based on the residual convergence behavior of the steady solver. Eigenanalyses were then performed for flow solutions at a few near-stall points to determine their global linear stability. Once the relevant unstable modes were identified according to the signs of real parts of eigenvalues, they were examined in detail to understand the flow destabilizing mechanism. Furthermore, time-accurate unsteady simulations were performed to verify the obtained eigenvalues and eigenvectors. The eigenanalysis results reveal that at the rotating stall inception condition, multiple unstable modes appear almost simultaneously with a leading mode that grows most rapidly. In addition, it was found that the unstable modes are continuous in their nodal diameters, and are members of a particular family of modes typical of a dynamic system with cyclic symmetries. This is the first time such an interesting structure of the unstable modes is found numerically, which to some extent explains the rich and complex results constantly observed from experiments but have never been consistently explained. The verified eigenanalysis method can be used to predict the onset of a rotating stall with a CPU time cost orders of magnitude lower than time-accurate simulations, thus making compressor stall onset prediction based on the global linear instability approach feasible in engineering practice.

Published

2024

35. Eigenvalue-based approach for buckling analysis of metre gauge railway tracks incorporating train load effects

Author

Sorawish Machan, Siriwan Tangwongwan, Pimsuda Chuadchim, and Chayut Ngamkhanong

Subjects

Extreme temperature, Rail buckling, Eigenvalue analysis, Ballasted railway track, Transportation engineering, TA1001-1280

Abstract

Railway track buckling is a significant concern that can jeopardise train operations and passenger safety. This paper presents a comprehensive buckling analysis of railway tracks using Eigenvalue-based simplified approach in the finite element method, while considering the influence of passing trains. The study focuses on evaluating the buckling behaviour of the track, taking into account dynamic response and the interaction between the train and track. The finite element model encompasses the track structure, including rails, sleepers, ballast, and fasteners, and incorporates material properties, geometrical constraints, and boundary conditions. Through eigenvalue analysis, critical buckling modes and corresponding buckling loads are determined, providing insights into the track's stability under different loading scenarios. Furthermore, a parametric study is conducted to investigate the effects of various factors such as unconstrained length, lateral resistance and rail sections on the buckling behaviour. This study enhances the understanding of buckling phenomena in railway tracks and offers valuable information for track design, maintenance, and safety considerations. The findings contribute to improving the resilience and reliability of railway track systems, ultimately ensuring safe and efficient train operations.

Published

2023

36. An approach on nonlinear integration of MMC to linear model of ROPS in transient analysis.

Author

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

37. Looking into the Market Behaviors through the Lens of Correlations and Eigenvalues: An Investigation on the Chinese and US Markets Using RMT.

Author

Tang, Yong, Xiong, Jason, Cheng, Zhitao, Zhuang, Yan, Li, Kunqi, Xie, Jingcong, and Zhang, Yicheng

Subjects

*FINANCIAL markets, *RANDOM matrices, *STOCK prices, *MARKET design & structure (Economics), *FRACTIONS

Abstract

This research systematically analyzes the behaviors of correlations among stock prices and the eigenvalues for correlation matrices by utilizing random matrix theory (RMT) for Chinese and US stock markets. Results suggest that most eigenvalues of both markets fall within the predicted distribution intervals by RMT, whereas some larger eigenvalues fall beyond the noises and carry market information. The largest eigenvalue represents the market and is a good indicator for averaged correlations. Further, the average largest eigenvalue shows similar movement with the index for both markets. The analysis demonstrates the fraction of eigenvalues falling beyond the predicted interval, pinpointing major market switching points. It has identified that the average of eigenvector components corresponds to the largest eigenvalue switch with the market itself. The investigation on the second largest eigenvalue and its eigenvector suggests that the Chinese market is dominated by four industries whereas the US market contains three leading industries. The study later investigates how it changes before and after a market crash, revealing that the two markets behave differently, and a major market structure change is observed in the Chinese market but not in the US market. The results shed new light on mining hidden information from stock market data. [ABSTRACT FROM AUTHOR]

Published

2023

38. Stability Analysis and Control Strategy Optimization of a Paralleled IPOS Phase-Shifted Full-Bridge Converters System Based on Droop Control.

Author

Qin, Zhenghao, Cai, Huafeng, and Lin, Xinchun

Subjects

PARTICLE swarm optimization

Abstract

The application of high-power DC equipment further increases the power supply scale of DC systems. But, it is difficult for a single converter to support high transmission power, so multiple converters must operate in parallel for efficient power transmission. In a parallel system comprising many IPOS phase-shifting full-bridge converters, current sharing can be realized via droop control. However, the stability of the parallel system using current-sharing control will appear poor in light load conditions, so it is necessary to analyze the stability of parallel systems in light load conditions. Firstly, a single IPOS phase-shifted full-bridge control system is modeled; on this basis, the state space model of the n-module paralleled IPOS phase-shifted full-bridge converters system is derived. Then, the influence of load power and the number of parallel IPOS phase-shifted full-bridge converters on the system stability is analyzed via eigenvalue analysis, and an optimal control strategy based on a particle swarm optimization algorithm is proposed. The control parameters are optimized for the parallel system of eight IPOS phase-shifted full-bridge converters. Finally, the above results are simulated to verify the accuracy of the stability analysis and the feasibility of the optimized control strategy. [ABSTRACT FROM AUTHOR]

Published

2023

39. 虚拟同步直驱风电场经MMC-HVDC并网的 低频振荡特性分析.

Author

李永刚, 褚文从, and 刘华志

Subjects

PERMANENT magnet generators, PHASE-locked loops, SYNCHRONOUS generators, ELECTRIC transients, WIND power, WIND power plants, CONVERTERS (Electronics), MAXIMUM power point trackers

Abstract

Copyright of Electric Power Automation Equipment / Dianli Zidonghua Shebei is the property of Electric Power Automation Equipment Press and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

40. 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

41. Stability Analysis of Inverse Lax-Wendroff Procedure for a High order Compact Finite Difference Schemes

Author

Li, Tingting, Lu, Jianfang, and Wang, Pengde

Published

2024

42. Dynamic Interactions between Parallel Grid-Forming Inverters in a Microgrid.

Author

Almutairi, Sulaiman Z.

Subjects

MODE shapes, MICROGRIDS, IMPEDANCE control, ELECTRIC circuits, ELECTRIC transients

Abstract

The potential instability issues caused by the dynamic interactions between parallel grid-forming inverters are examined. The approach adopted for analysis is s-domain admittance-based eigenvalue and mode shape analysis. This admittance is based on a five-node circuit diagram after the conversion of each electric circuit element and inverter control unit into impedance models. Eigenvalue analysis results show that unstable resonance modes may exist due to the interactions of two parallel inverters. Impacts of transmission line length, the converter control's virtual impedance unit, and the voltage feed-forward unit are examined via the eigenvalue and mode shape analysis. The results show that the virtual impedance control has a negligible influence on the resonance while the voltage feed-forward unit stabilizes the resonance. Finally, the stability analysis is validated using electromagnetic transient (EMT) simulations. [ABSTRACT FROM AUTHOR]

Published

2023

43. Bifurcation and path-following continuation analysis of periodic orbits of an extended Fermi oscillator model.

Author

Ma, Wei and Mapuranga, Tafara

Abstract

In this research, we offer eigenvalue analysis and path following continuation to describe the impact, stick, and non-stick between the particle and boundaries to understand the nonlinear dynamics of an extended Fermi oscillator. The principles of discontinuous dynamical systems will be utilized to explain the moving process in such an extended Fermi oscillator. The motion complexity and stick mechanism of such an oscillator are demonstrated using periodic and chaotic motions. The major parameters are the frequency, amplitude in periodic excitation force, and the gap between the top and bottom boundary. We employ path-following analysis to illustrate the bifurcations that lead to solution destabilization. We present the evolution of the period solutions of the extended Fermi oscillator as the parameter varies. From the viewpoint of eigenvalue analysis, the essence of period-doubling, saddle-node, and Torus bifurcation is revealed. Numerical continuation methods are used to do a complete one- and two-parameter bifurcation analysis of the extended Fermi oscillator. The presence of codimension-one bifurcations of limit cycles, such as saddle-node, period-doubling, and Torus bifurcations, is shown in this work. Bifurcations cause all solutions to lose stability, according to our findings. The acquired results provide a better understanding of the extended Fermi oscillator mechanism and demonstrate that we may control the system dynamics by modifying the parameters. [ABSTRACT FROM AUTHOR]

Published

2023

44. A Simplified Model of the HVDC Transmission System for Sub-Synchronous Oscillations.

Author

Wang, Yanwen, Wu, Lingjie, and Chen, Shaoyang

Abstract

As the installed capacity of the power system is scaled up and the distance of transmission increases constantly, high-voltage direct current (HVDC) transmission technology has been widely applied across the power system. The HVDC system can lead to sub-synchronous oscillations (SSO) in the turbine and new energy generation systems. When the SSO caused by HVDC are studied through small signal analysis, it is usually necessary to establish the detailed state space model and electromagnetic transient model, which shows various disadvantages such as the high complexity of the model, the high order of the state space matrix, the complex calculation of eigenvalues, and the slow pace of simulation. In the present study, a simplified model intended for the HVDC transmission system is proposed, which can be used to simplify the calculation model and accelerate the simulation by omitting the high-frequency component and simultaneously keeping the sub-synchronous frequency component unchanged. The time domain simulation method is used to compare the dynamic response of the proposed simplified simulation model with that of the original detailed model, and the accuracy of the proposed model is demonstrated. The proposed simplified simulation model is applied to explore the SSO of wind-thermal power bundling in the HVDC transmission system. Additionally, the simulation results of SSO are compared by using the simplified model and the detailed model; the results of which demonstrate the effectiveness and rapidity of the simplified simulation model. The simplified model proposed can greatly improve the efficiency of SSO risk assessment. By selecting reasonable types and parameters of new energy units, SSO of the system can be avoided under risky operation mode, and the power grid operation mode can be monitored and adjusted to ensure the safe operation of the system. Finally, it can promote the sustainable development of the power system. [ABSTRACT FROM AUTHOR]

Published

2023

45. Suboptimal attitude tracking control law and eigenvalue analysis for a near-space hypersonic vehicle based on Koopman operator and stable manifold method.

Author

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

46. Impact of Short-Circuit Ratio on Control Parameter Settings of DFIG Wind Turbines

Author

Joaquín Pedra, Luis Sainz, and Lluís Monjo

Subjects

DFIG stability, eigenvalue analysis, state-space models, controller parameter settings, weak grid stability, stability boundary, Technology

Abstract

This work deals with doubly fed induction generator (DFIG) modeling and stability when connected to weak AC grids. A detailed state-space model that includes the phase-locked loop (PLL) is developed. This work aims to determine the influence of the network’s strength on DFIG stability through the short-circuit ratio (SCR). The critical values of the proportional control parameters of the grid-side and rotor-side converters (RSC and GSC), as well as PLL, which make the system unstable, are calculated for different SCR values. Finally, PSCAD/EMTDC dynamic simulations are used to validate the critical control parameters obtained by studying the eigenvalues of the DFIG state-space model regarding system stability.

Published

2024

47. Analysis and Mitigation of Middle Frequency Resonance for Grid-Connected Inverter Under Weak Grid

Author

Li, Gaoxiang, Pan, Hongzhi, Angrisani, Leopoldo, Series Editor, Arteaga, Marco, Series Editor, Panigrahi, Bijaya Ketan, 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, Hirche, Sandra, 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, Möller, Sebastian, Series Editor, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Oneto, Luca, 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, Zhang, Junjie James, Series Editor, Yang, Qingxin, editor, Liang, Xidong, editor, Li, Yaohua, editor, and He, Jinghan, editor

Published

2022

48. Fault diagnosis of press dies using dynamic mode decomposition of a sound signal

Author

Yuki KATO and Rintaro KUMAGAI

Subjects

dynamic mode decomposition, fault diagnosis, eigenvalue analysis, press die, finite element method, compressed sensing, Engineering machinery, tools, and implements, TA213-215, Mechanical engineering and machinery, TJ1-1570

Abstract

Although a wide range of machine failure diagnosis methods has been studied for bearings, gears, propellers, etc., there have been few studies on failure diagnosis methods for press machine dies. In this study, we develop a method to diagnose press die failure using a single microphone, which is easy to install, inexpensive, and robust. Because a damped vibration waveform is repeatedly observed in the processing noise of a press, general frequency analysis methods such as the FFT have a problem in that their spectra are blurred and only large amplitude vibrations can be detected from a frequency band comprising multiple vibrations. Therefore, we developed a method to perform dynamic mode decomposition by mapping repetitive vibration waveforms into a two-dimensional array. Based on the obtained eigenmodes and time characteristics, the main vibration components were identified using sparsity and extracted as failure diagnosis indicator values. It was found that the proposed method separates two vibrations that appear as a single peak in the frequency spectrum by the FFT. When this method was applied to the processing noise of abnormal and normal dies, a vibration component at approximately 200 Hz appeared only for an abnormal die. From the eigenvalue analysis of the material using the finite element method, it was realized that a 200-Hz horizontal mode was excited by the force in the direction orthogonal to the pressing direction owing to the die abnormality, resulting in the generation of a 200-Hz abnormal sound. Therefore, by monitoring the sound at the natural frequency of the material’s horizontal mode using the proposed method, die failure can be diagnosed. The proposed method can be applied to vibration analysis of structures and failure diagnosis of bearings, gears, etc., because the frequency, amplitude, and damping ratio of major vibrations can be obtained simultaneously.

Published

2023

49. Study on the Mode and Characteristics of SSOs in Hybrid AC–DC Transmission Systems via Multitype Power Supply.

Author

Wang, Yanwen, Wu, Lingjie, and Chen, Shaoyang

Abstract

The impact of subsynchronous oscillation (SSO) on grid security is becoming increasingly prominent with the rapid development of a large new energy base. However, the SSO modes and characteristics in complex power systems where series-complementary AC systems, DC systems, wind farms, and thermal power plants co-exist simultaneously are still not well understood, and relevant research has yet to be conducted. To address these issues, this study aims to investigate the SSO oscillation modes and the participation of specific influencing factors using eigenvalue and participation factor analysis. Additionally, the influence of system operation mode and control parameters on the SSO characteristics is studied through eigenvalue analysis. The findings of this study suggest that multiple oscillation sources and the co-existence of various oscillation patterns in hybrid AC–DC transmission systems cause SSO problems. The SSOs arise due to inappropriate system operation or parameter selection. As the series compensation increases, the system tends to become unstable. The system stability improves when the wind power output increases or the thermal power output decreases while keeping the output power of other sources constant. On the other hand, the system stability decreases as the DC transmission power gradually decreases. In terms of the control parameters, a higher value of the inner-loop proportionality coefficient of the converter current on the rotor side of the wind turbine results in a more unstable system. However, the rotor-side converter outer loop parameters and the stator-side control loop PI parameters have a negligible effect on the oscillation frequency and damping of the system. Matlab time domain simulations are conducted to verify the accuracy of the theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2023

50. Robust Subsynchronous Damping Control of PMSG-Based Wind Farm †.

Author

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