Your search keyword '"Steady state"' showing total 2,379 results

1. A 3-D Finite Difference Method for Obtaining the Steady-State Temperature Field of a PCB Circuit.

Author

Wan, Guochun, Zhang, Kaifeng, and Fu, Kang

Abstract

The temperature rise caused by the heat generated by the on-board LED driver module during work will lead to the rise of product failure rate. The thermal analysis of this drive module should not only consider the heat and packaging of the LED itself, but also the influence of other power components. Common commercial thermal simulation software, such as ANSYS ICEPAK or FLOTHEM, usually requires detailed thermal models for such printed circuit board (PCB)-level thermal simulation, and requires a large number of simulation parameter settings and a long simulation time to obtain temperature results that are barely close to the actual. In this article, a 3-D finite difference method is proposed to obtain the steady-state temperature field of PCB circuit. The model can be used to calculate the steady-state temperature field of PCB circuit by setting different component sizes, power, and thermal conductivity. This article uses this method to calculate the temperature field of PCB steady-state working with MATLAB. The experimental measurement of PCB is compared with thermal simulation by ANSYS ICEPAK. It proves that the temperature results obtained by this method are similar to the actual test temperature compared with ANSYS ICEPAK. The time required for calculation is greatly reduced. [ABSTRACT FROM AUTHOR]

Published

2023

2. Novel Equivalent Circuit Model Applicable to All Operation Modes for Brushless Doubly Fed Induction Machines.

Author

Ge, Jian, Xu, Wei, Liu, Yi, and Xiong, Fei

Subjects

*MACHINERY, *MAGNETIC fields, *POWER (Social sciences), *INDUCTION generators, *WIND power

Abstract

The equivalent circuit is an indispensable tool for analyzing the steady-state characteristics of the brushless doubly fed induction machine (BDFIM). However, the most commonly used equivalent circuits are not available to analyze some special operation modes, such as the natural synchronous mode with one set of winding powered by dc current. In order to overcome the limitation, in this article, a novel equivalent circuit is proposed. At first, the electromagnetic relations within BDFIMs are described by a new approach in which the cause of working magnetic fields is refined. Then, the equivalent circuit is built by the rigorous derivation of electromagnetic relations. And a few features of BDFIMs in some typical operation modes including the natural synchronous mode are introduced in details. Finally, the validity of the equivalent circuit is made by comparison of model and experimental results based on a wound-rotor BDFIM prototype. The proposed model with clear physical concept can cover all operation modes. And both power relationship and torque components reflected in the proposed model is more detailed and clearer than those reflected in the traditional one. [ABSTRACT FROM AUTHOR]

Published

2022

3. Detailed Model of the Grid-Connected Cascaded Doubly Fed Induction Machine.

Author

Mehrjardi, Ramin Tafazzoli, Ershad, Nima Farrokhzad, Rahrovi, Babak, and Ehsani, Mehrdad

Subjects

*INDUCTION generators, *WIND power, *MACHINERY, *DYNAMIC models, *TORQUE

Abstract

The cascaded (brushless) doubly fed induction machine (CDFIM) is a promising substitute for the commonly used doubly fed induction machine (DFIM) for wind power application. The CDFIM offers reliable performance and low maintenance due to the absence of slip rings and graphite brushes. In this study, a detailed analytical model for the CDFIM is proposed in order to clearly show the controllable input (i.e., current from the inverter side) and output (i.e., total output torque) relationship. The proposed model is expressed in the frequency (Laplace) domain. Field-oriented (i.e., vector) control approach is adopted in order to achieve a precise dynamic model for the grid-connected CDFIM. The steady-state and dynamic behaviors of derived torque terms are presented and explained individually. Dynamic response of the total output torque is calculated both analytically and numerically in a simulation, and the results are shown to be consistent. Next, the torque-sharing and power-sharing concepts of the CDFIM are presented to further study the system behavior under different rotor velocities. Finally, to verify the proposed model, an experimental setup using a cascaded DFIM was used, and the results are reported. [ABSTRACT FROM AUTHOR]

Published

2022

4. Integrated Scheduling of a Dual-Armed Cluster Tool for Maximizing Steady Schedule Patterns.

Author

Kim, Woojin, Yu, Tae-Sun, and Lee, Tae-Eog

Subjects

*MATRICES (Mathematics), *PETRI nets, *SCHEDULING, *SCHOOL schedules, *LINEAR systems

Abstract

A cluster tool consists of several single-wafer processing chambers and a wafer handling robot. A wafer has to wait within a chamber after being processed there until it is unloaded by the robot. Such wafer delays may cause wafer quality degradation or variability due to residual gases and heat in the chamber. The tool operation schedule has to maintain identical timing patterns or schedules for each cycle so as to keep wafer delays constant for every wafer. However, at the beginning of the tool operation, the tool is in an empty state and hence we need to make the tool reach such steady schedule by loading wafers into the tool. In this article, we develop a method of scheduling the robot tasks during the start-up period of a cluster tool to reach a target steady schedule quickly as possible. To do this, we model the behaviors of a cluster tool using timed Petri nets and linear system matrices in the max-plus algebra. By analyzing the matrices, we first identify a class of steady schedules which can be reached from the empty tool. We develop the matrices that explain the schedule evolution of the start-up period before reaching the steady period. By examining the matrices, we develop a method of choosing the most desirable one from such class of reachable steady schedules that can be achieved in the minimum time. We also prove that the schedule also minimizes the time duration of the close-down. Finally, we present computational experiments. [ABSTRACT FROM AUTHOR]

Published

2021

5. Numerical Study on the Temporal Evolution of a Helicon Discharge.

Author

Chang, Yunju, Chang, Lei, Yuan, Xiaogang, Yang, Xin, Xu, Qian, Wang, Yong, Niu, Guojian, Zhou, Haishan, and Luo, Guangnan

Subjects

*MAGNETIC flux density, *ELECTRON temperature, *ELECTRON density, *PLASMA sources, *MAGNETIC fields, *ELECTRIC fields

Abstract

A numerical model is developed to study the temporal evolution of helicon discharge. The initiation of helicon discharge is first presented in terms of time-dependent electron density and temperature, electric and magnetic fields, and power deposition; then, their steady-state values are compared with experimental data and previous simulations for benchmark. It is found that the evolutions of electron density and temperature arrive steady state around 100 and $1.5~\mu \text{s}$ , respectively, while electric and magnetic fields become steady prior to 2 $\mu \text{s}$. The spatial distributions of power deposition indicate that RF power is absorbed mostly near the edge, similar to those of electron temperature. Parameter studies show that high background pressure, confining magnetic field strength, and RF power are beneficial to obtaining high-density helicon plasma, while the driving frequency has little effect. These findings are interesting for the design and optimization of helicon plasma source. [ABSTRACT FROM AUTHOR]

Published

2021

6. Pinning Control for Stabilization of Boolean Networks Under Knock-Out Perturbation.

Author

Zhong, Jie, Liu, Yang, Lu, Jianquan, and Gui, Weihua

Subjects

*MAMMALIAN cell cycle, *COMPUTATIONAL complexity, *CELL death

Abstract

In genetic regulatory networks, steady states represent cell types of cell death or unregulated growth, which are of significant interest in modeling networks. In this article, a pinning control intervention is studied for global stabilization of Boolean networks (BNs) under knock-out perturbation. Knock-out perturbation means that logical variables of some nodes of a BN remain 0 s. In order to reduce the impact of perturbation on stability, a pinning control approach is proposed to maintain global stabilization for the rest nodes other than those knocked out nodes, based on the network structure (the connection rule among nodes). Compared with the existing references, the proposed pinning control dramatically reduces the high computational complexity. In addition, the design of pinning controllers is based on local neighbors’ information. Finally, the proposed method is well demonstrated by a mammalian cell cycle network and a network with 30 nodes. [ABSTRACT FROM AUTHOR]

Published

2022

7. An Improved Direct Power Control for Doubly Fed Induction Generator.

Author

Gao, Shuning, Zhao, Haoran, Gui, Yonghao, Zhou, Dao, and Blaabjerg, Frede

Subjects

*INDUCTION generators, *LINEAR time invariant systems, *PHASE-locked loops, *CLOSED loop systems, *EXPONENTIAL stability

Abstract

A novel voltage-modulated direct power control (VM-DPC) is first designed for a back-to-back (BTB) converter in the doubly fed induction generator (DFIG) system. The proposed VM-DPC is built in the stator stationary reference frame ($\alpha \beta$). The proposed method uses a simple feed-forward and feedback structure without a phase-locked loop and the Park transformation. Therefore, it can be easily implemented in the BTB converter. Another essential advantage of the proposed VM-DPC is that it can transform the closed-loop DFIG system into a linear-time-invariant one, which can be analyzed and designed through multiple linear control techniques. The proposed method guarantees exponential stability in the stiff grid as well as in weak-grid integration, which is proved based on eigenvalue analysis. Simulation results demonstrate that the proposed VM-DPC has a faster transient response than conventional vector-oriented control (VOC). Also, it maintains a satisfactory steady-state performance at the same level as the VOC. The robustness of proposed VM-DPC against distorted voltage conditions and parameter mismatch is also tested. Finally, the proposed VM-DPC control strategy is validated in an experimental hardware prototype of a 7.5-kW DFIG system operating in real time. [ABSTRACT FROM AUTHOR]

Published

2021

8. On the Approximation of Moments for Nonlinear Systems.

Author

Faedo, Nicolas, Scarciotti, Giordano, Astolfi, Alessandro, and Ringwood, John V.

Subjects

*NONLINEAR systems, *SIGNAL generators, *MATCHING theory, *LINEAR systems, *DIFFERENTIAL equations

Abstract

Model reduction by moment-matching relies upon the availability of the so-called moment. If the system is nonlinear, the computation of moments depends on an underlying specific invariance equation, which can be difficult or impossible to solve. This article presents four technical contributions related to the theory of moment matching: first, we identify a connection between moment-based theory and weighted residual methods. Second, we exploit this relation to provide an approximation technique for the computation of nonlinear moments. Third, we extend the definition of nonlinear moment to the case in which the generator is described in explicit form. Finally, we provide an approximation technique to compute the moments in this scenario. The results are illustrated by means of two examples. [ABSTRACT FROM AUTHOR]

Published

2021

9. DC IR-Drop Analysis of Multilayered Power Distribution Network by Discontinuous Galerkin Method With Thermal Effects Incorporated.

Author

Li, Ping, Tang, Min, Huang, Zhi Xiang, Jiang, Li Jun, and Bagci, Hakan

Subjects

*POWER distribution networks, *GALERKIN methods, *DOMAIN decomposition methods, *SYLVESTER matrix equations

Abstract

Due to the temperature-dependent resistivity of power distribution network (PDN) interconnects, a wiser and necessary strategy is to proceed the electrical–thermal cosimulation in order to include the thermal effects caused by Joule heating. As a natural domain decomposition method (DDM), in this article, a discontinuous Galerkin (DG) method is proposed to facilitate the steady-state electrical and thermal coanalysis. With the intention to avoid solving a globally coupled steady-state matrix system equations resulted from the implicit numerical flux in DG, the block Thomas method is deployed to solve the entire domain in a subdomain-by-subdomain scheme. As a direct solver, the block Thomas method is free of convergence problem frequently occurring in iterative methods, such as block Gauss–Seidel method. The capability of the proposed DG method in handling multiscale and complex 3-D PDNs is validated by several representative examples. [ABSTRACT FROM AUTHOR]

Published

2020

10. Simultaneous Multi-VENC and Simultaneous Multi-Slice Phase Contrast Magnetic Resonance Imaging.

Author

Park, Suhyung, Chen, Liyong, Townsend, Jennifer, Lee, Hyunyeol, and Feinberg, David A.

Subjects

*PHASE contrast magnetic resonance imaging, *FLOW velocity, *PHASE coding

Abstract

This work develops a novel, simultaneous multi-VENC and simultaneous multi-slice (SMV+SMS) imaging in a single acquisition for robust phase contrast (PC) MRI. To this end, the pulse sequence was designed to permit concurrent acquisition of multiple VENCs as well as multiple slices on a shared frequency encoding gradient, in which each effective echo time for multiple VENCs was controlled by adjusting net gradient area while multiple slices were simultaneously excited by employing multiband resonance frequency (RF) pulses. For VENC and slice separation, RF phase cycling and gradient blip were applied to create both inter-VENC and inter-slice shifts along phase encoding direction, respectively. With an alternating RF phase cycling that generates oscillating steady-state with low and high signal amplitude, the acquired multi-VENC k-space was reformulated into 3D undersampled k-space by generating a virtual dimension along VENC direction for modulation induced artifact reduction. In vivo studies were conducted to validate the feasibility of the proposed method in comparison with conventional PC MRI. The proposed method shows comparable performance to the conventional method in delineating both low and high flow velocities across cardiac phases with high spatial coverage without apparent artifacts. In the presence of high flow velocity that is above the VENC value, the proposed method exhibits clear depiction of flow signals over conventional method, thereby leading to high VNR image with improved velocity dynamic range. [ABSTRACT FROM AUTHOR]

Published

2020

11. Turn-OFF Transient Analysis of Superjunction IGBT.

Author

Wang, Zhigang, Zhang, Hao, and Kuo, James B.

Subjects

*TRANSIENT analysis, *INSULATED gate bipolar transistors, *ANODES, *ELECTRIC potential, *DOPING agents (Chemistry)

Abstract

A turn-OFF transient analysis of the superjunction (SJ) insulated-gate bipolar transistor (IGBT) based on an analytical model as a function of structural parameters is presented in this paper. The physical phenomenon dependent on the doping density of the n-/p-pillar of the SJ IGBT could be explained using the analytical model to predict the static and transient characteristics. From this model, tradeoff between turn-OFF loss and ON-state voltage has been obtained, as verified by the TCAD simulations with a good agreement. [ABSTRACT FROM AUTHOR]

Published

2019

12. Diode Reverse Recovery Process and Reduction of a Half-Wave Series Cockcroft–Walton Voltage Multiplier for High-Frequency High-Voltage Generator Applications.

Author

Mao, Saijun, Popovic, Jelena, and Ferreira, Jan Abraham

Subjects

*HIGH voltages, *METAL oxide semiconductor field-effect transistors, *INSULATED gate bipolar transistors, *ELECTRIC current converters, *PULSE width modulation transformers

Abstract

This paper investigates the diode reverse recovery process and reduction of a half-wave (HW) series Cockcroft–Walton (CW) voltage multiplier based on the steady-state analysis for high-frequency high-voltage (HV) generator applications. The diode reverse recovery process for a multistage voltage multiplier is analyzed after the introduction of steady-state operation. The diode reverse recovery problem is the bottleneck to further increase the circuit operation switching frequency for achieving high power density and short HV pulse rise and decay times. The diode reverse recovery problem is mainly caused by the diodes in the first-stage voltage multiplier. It is suggested that the most effective and economic way to alleviate the diode reverse recovery problem is by employing diodes without reverse recovery such as silicon carbide Schottky diodes in the first stage only. The silicon carbide Schottky diode without reverse recovery needs to be used only in the first stage of the voltage multiplier to effectively mitigate the reverse recovery problems at high frequency. The 300 kHz switching frequency three-stage voltage multiplier circuit hardware prototype experimental results finally validate the analysis. A technology demonstrator of a 300 kHz 8 kW 160 kV HV generator based on the proposed hybrid silicon carbide and silicon diode solution for the HW series CW voltage multiplier is provided finally. [ABSTRACT FROM AUTHOR]

Published

2019

13. Closed-Form Approximation for the Convergence Time of pth-Order Kalman Filters.

Author

Locubiche-Serra, Sergi, Seco-Granados, Gonzalo, and Lopez-Salcedo, Jose A.

Subjects

KALMAN filtering, BAYESIAN analysis, MEAN square algorithms, MONTE Carlo method, RICCATI equation

Abstract

The Kalman filter is used in a myriad of applications for estimating a set of time-varying parameters in the minimum mean square error sense. When designing the filter, one of the points of most relevant interest is predicting its estimation performance. However, it is often difficult to find expressions in closed form that allow obtaining this information in a straightforward manner. As a consequence, the designer usually requires resorting to the numerical evaluation of the Bayesian Cramér–Rao bound or the implementation and assessment of the filter through Monte Carlo simulations. In this regard, this letter intends to contribute with a novel closed-form upper bound for the convergence time of a Kalman filter. To this end, the Kalman filtering problem is reformulated in batch mode, and the corresponding Fisher information matrix is analyzed. The contribution presented herein is based on a generic dynamic model and is not restricted to any specific order, in contrast to existing contributions. Simulation results are provided to illustrate the goodness of the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2018

14. Design Considerations for Miniaturized Steady-State Thermal Characterization Instruments.

Author

Warzoha, Ronald J., Smith, Andrew N., Boteler, Lauren, and Bajwa, Ashim

Subjects

*ELECTRONIC packaging, *COMPUTER simulation, *STEADY-state flow, *THERMAL conductivity, *TEMPERATURE measurements, *ELECTRIC heating systems

Abstract

We use numerical simulations to design and optimize a set of miniaturized heat meter bars for high-resolution measurements of interfacial thermal transport across solid, contacting junctions ( $R_{T}$ ) and thermal conductivity within low-resistivity materials ( $\kappa$ ). We find that extreme care must be taken to design both the geometry of the heat meter bars and the cooling technique used to drive thermal transport across the junction. To reduce measurements of $R_{T}$ down to 0.1 mm2 $\cdot$ K/W, a channel heat sink is optimized to remove heat from the lower bar. Results suggest that in order to maintain a sufficient number of temperature measurements, the bar length can be no less than 3 mm in order to maintain a linear thermal gradient a sufficient distance away from the interface. Further reductions in heat meter bar length are insufficient to achieve corresponding reductions in $R_{T}$. To address this limitation, a jet impingement cooling technique is assessed. We find that a $2\times 3$ array of jets ( $D = 1$ mm) is sufficient to maintain a linear thermal gradient around the interface as the heat meter bar length is reduced below 5 mm. Using the jet impingement cooling technique described in this paper, measurements of $R_{T} = 0.01$ mm2 $\cdot$ K/W are found to be theoretically possible. This would represent a two-orders-of-magnitude improvement in the resolution of interfacial thermal resistance measurements made with steady-state thermal characterization techniques. The thermal challenges explored in this paper are critical to the design of instruments that can directly characterize the magnitude of heat flow permitted across high-performance thermal interface materials in electronics packaging systems. [ABSTRACT FROM AUTHOR]

Published

2018

15. A Methodology for Transient State Estimation Based on Numerical Derivatives, Optimal Monitoring, and Filtered Measurements.

Author

Molina-Moreno, Ismael, Medina, Aurelio, Cisneros-Magana, Rafael, and Anaya-Lara, Olimpo

Subjects

*TRANSIENT analysis, *DERIVATIVES (Mathematics), *THERMODYNAMIC state variables, *ELECTRIC power systems research, *ELECTRIC transients, *INFINITE impulse response filters, *NUMERICAL differentiation

Abstract

This paper proposes a methodology for transient state estimation in power systems. The proposed methodology is formulated using approximation methods for derivatives to relate the state variables to measurements. It does not require knowledge of the steady state to establish the predisturbance operation conditions. The method uses an optimal monitoring system based on topological analysis to obtain full observability. A saving index is introduced to analyze the effectiveness of the instrumentation used. The adverse effect of noisy measurements in the estimation process is mitigated by using an infinite impulse response filter. A transient index is introduced to estimate the fault location. The transient state estimation is assessed using two test systems. The results are validated through direct comparison against those obtained by simulation using SimPowerSystems toolbox of Simulink. With the proposed methodology, the transient state estimation can be obtained with an important saving in the implementation of the measuring system and with considerably less computational effort. [ABSTRACT FROM PUBLISHER]

Published

2018

16. Moment-Based Parameter Estimation for Stochastic Reaction Networks in Equilibrium.

Author

Backenkohler, Michael, Bortolussi, Luca, and Wolf, Verena

Abstract

Calibrating parameters is a crucial problem within quantitative modeling approaches to reaction networks. Existing methods for stochastic models rely either on statistical sampling or can only be applied to small systems. Here, we present an inference procedure for stochastic models in equilibrium that is based on a moment matching scheme with optimal weighting and that can be used with high-throughput data like the one collected by flow cytometry. Our method does not require an approximation of the underlying equilibrium probability distribution and, if reaction rate constants have to be learned, the optimal values can be computed by solving a linear system of equations. We discuss important practical issues such as the selection of the moments and evaluate the effectiveness of the proposed approach on three case studies. [ABSTRACT FROM AUTHOR]

Published

2018

17. Initialization of the DFIG Machine for Electromagnetic Transients Calculation.

Author

Guidi-Venerdini, Guillermo David and Mombello, Enrique

Abstract

There is currently a strong trend in the world toward the use of power generation from renewable resources. This poses new challenges with respect to the modeling of electrical generators connected to power electronics devices, such as Doubly Fed Induction Generators (DFIGs). The initialization of DFIG models to be used for transient studies is critical. This article presents an approach to the modeling of DFIG in the ATP calculation environment using the Universal Machine type 4 model, which focuses especially on the automatic model initialization. A methodology for initializing the generator for a desired operating point at subsynchronous speed is proposed, which can be used to initialize a detailed wind DFIG. A case study is presented to validate the methodology. The results show that the initial operating conditions of the DFIG can be calculated very accurately using this approach. [ABSTRACT FROM PUBLISHER]

Published

2018

18. Dynamic Properties of Electrochemical Oxygen Gas Sensor and Method to Estimate of New Steady-State

Author

Dusan Hruby, Vladimír Cviklovič, Vladimir Madola, and Marian Kisev

Subjects

Steady state, Materials science, General Computer Science, Sensors, System of measurement, electrochemical devices, General Engineering, Temperature measurement, Transfer function, measurement techniques, Automotive engineering, Electrochemical gas sensor, TK1-9971, Microcontroller, transfer functions, General Materials Science, Transient (oscillation), Laplace equations, Electrical engineering. Electronics. Nuclear engineering, Oxygen sensor, oxygen

Abstract

The paper presents the designed system to measurements of gas sensor transient characteristics. Electrochemical oxygen sensor SK-25F was selected for measurements from point of view application in health care and ensuring human safety in industrial production facilities and laboratories. The aim of this work is to design an automatic system for measuring the transient function G(s) of electrochemical sensors and to identify the mathematic model from a sample of sensors. The automatic measurement system based on a microcontroller for the measurements of dynamical characteristics of gas sensors was designed and developed. The result is transfer function with fit to estimation data higher as 99.48 %. The bandwidth of gas sensors was calculated on average at 0.0285763 Hz with a maximum deviation of 0.34 %. Finally, an algorithm for detecting the exceeding of the frequency range of an electrochemical gas sensor is proposed. Its application is in speed control UAV with the aim of accurate measurements of gases in the air by electrochemical sensors.

Published

2021

19. A Hybrid Steady-State Compressor Model for Real-Time Applications in Performance Monitoring, Control and Optimization

Author

Peiyong Duan, Xudong Ding, Gang Jing, Chenguang Ning, Qiu Zhong, and Yin Chunjie

Subjects

Volumetric efficiency, parameter identifications, Steady state, General Computer Science, social learning particle swarm optimization, Computer science, 020209 energy, hybrid modeling, Compressor, General Engineering, Particle swarm optimization, 02 engineering and technology, Polytropic process, Refrigerant, 020401 chemical engineering, Control theory, 0202 electrical engineering, electronic engineering, information engineering, Mass flow rate, General Materials Science, lcsh:Electrical engineering. Electronics. Nuclear engineering, 0204 chemical engineering, Vapor-compression refrigeration, Gas compressor, control, lcsh:TK1-9971

Abstract

In this study, a hybrid steady-state compressor model is proposed that can be used in the real-time performance monitoring, control and optimization of the vapor compression cycle. In the proposed model, first, a detailed analysis of the mass flow rate is presented, which is based on the volumetric efficiency concept and the assumption of a polytropic compression process. Then, discharge temperature of the refrigerant and power consumption of the compressor are also investigated. Three semiempirical models are constructed respectively. Further, to tune the unknown empirical parameters of the models, a social learning particle swarm optimization (SLPSO) algorithm is developed by using the real-time experimental data. An experimental apparatus of a refrigerant system is tested to validate the proposed models. The experimental results demonstrate that the proposed models accurately predict the performance of real-time operating compressors. Meanwhile, the models identified by the SLPSO algorithm are more accurate than those identified by the traditional least-squares method.

Published

2021

20. Modified Phase-Shift Scheme for Optimal Transient Response of Dual-Active-Bridge DC/DC Converters Considering the Resistive Impact

Author

Jian Lu, Hui Jiang, Yitao Liu, Jianchun Peng, and Jian Yin

Subjects

Scheme (programming language), Resistive touchscreen, Steady state, Materials science, Current bias, General Computer Science, General Engineering, dual-active-bridge (DAB), Converters, transient response, Bridge (nautical), Dual (category theory), TK1-9971, phase-shift, Control theory, single-phase-shift (SPS), General Materials Science, Transient response, Transient (oscillation), Electrical engineering. Electronics. Nuclear engineering, Electrical and Electronic Engineering, computer, hard switching, computer.programming_language

Abstract

The scattered resistive elements residing in a dual-active-bridge (DAB) dc/dc converter can adversely affect its transient performance especially when the load change is large. Conventional phase-shift methods do not take the resistive impact into account in their modeling and analysis. In this paper, a comprehensive analysis of the detrimental influence on the transient performance of a DAB converter due to resistive elements is presented, based on which a modified phase-shift scheme is proposed to further optimize the transient response of the converter. A DAB prototype is designed to verify the resistive impact discussed and validate the proposed phase-shift scheme. The experimental results confirm that better transient response can be effectively achieved with the proposal.

Published

2021

21. Research on Control Strategy of Two Dimensional Output Force Vibration Damping Electric Actuator

Author

Xin Cao, Qiyao Zhang, Tao Wang, Zhenyang Hao, and Xue Li

Subjects

Coupling, 0209 industrial biotechnology, Steady state, General Computer Science, Computer science, cross-coupling control, General Engineering, Vibration control, 02 engineering and technology, Aerodynamics, Linear actuator, state space method, Rotating frame space-time coupling method, Valve actuator, Vibration, 020901 industrial engineering & automation, Control theory, Control system, General Materials Science, Sensitivity (control systems), lcsh:Electrical engineering. Electronics. Nuclear engineering, sensitivity H∞ control, Actuator, hysteresis matrix eigen-value method, lcsh:TK1-9971

Abstract

The main spiral blades of helicopter and other non fixed wing aircraft are in the asymmetric and unsteady aerodynamic environment for a long time, which will make the body produce large-scale multi-directional low-frequency vibration, which will become the main vibration source of the body. The linear actuator can only produce single direction driving force, which is difficult to meet the high-precision vibration reduction requirements. Based on this, a direct drive vibration control system based on the space-time coupling method of rotating coordinate system is proposed. Firstly, the mathematical model of the output force of the single side of the electric actuator is deduced, and the space-time coupling method of the rotating coordinate system is proposed to derive the mathematical expression of the two-dimensional vibration suppression output force. Secondly, the two-dimensional output force control strategy based on the cross coupling control of multiple motors is proposed. The controller parameters are designed by state space method and the method of characteristic value of the feedback matrix to ensure the stability of the control system. The controller parameters are optimized according to the sensitivity H∞ control theory to improve the anti-interference of the closed-loop system. Finally, a 14kg prototype is designed by the proposed control strategy, which completes the synchronous verification experiment of position and speed, steady state and dynamic verification experiment of output force. The experimental results show that the coordinated control strategy of multi motors proposed in this paper makes the actuator output force meet the performance requirements of the system vibration reduction and has a good stability.

Published

2021

22. Angle Stability Analysis for Voltage-Controlled Converters.

Author

Lin, Hengwei, Jia, Chenxi, Guerrero, Josep M., and Vasquez, Juan C.

Subjects

*STABILITY (Mechanics), *VOLTAGE-frequency converters, *DAMPING capacity, *EIGENVALUES, *ELECTRICAL engineering equipment, *EQUIVALENT electric circuits

Abstract

Power-electronics-based voltage-source converters (VSCs) keep increasing in modern electrical systems. As a branch of stability problems, angle stability is significant for an electrical system. Based on small disturbance analysis and time scale decomposition perspective, this paper proposes a criterion to analyze the quasi-steady angle stability and the direct current side stability for VSCs. The operating limit and the angle instability mechanism are revealed, which is generally applicable to the voltage-controlled converters. During the analysis, the influence of the parameters on angle stability is studied. Furthermore, the difference on instability mechanism between power electronic converters and synchronous generators is explained in detail. Finally, experiment results with corrective actions verify the analysis. [ABSTRACT FROM AUTHOR]

Published

2017

23. A Method for Filtering Low Frequency Disturbance in PMU Data Before Coordinated Usage in SCADA.

Author

Dong, Qing, Sun, Jinzhu, Wu, Qiannan, and Liu, Yilu

Subjects

*SUPERVISORY control & data acquisition systems, *FREQUENCIES of oscillating systems, *ELECTRIC power distribution grids, *ELECTRIC potential, *OSCILLATIONS

Abstract

The PMU data is increasingly used in the grid monitoring system SCADA. As the DFT algorithm used in PMUs fails to distinguish the fundamental frequency signal with low-frequency interference, the low-frequency disturbance (LFD) included in fundamental frequency variable data, which are collected from PMUs, will affect the correctness of calculation and analysis of the power system's steady state. In order to extract the fundamental frequency variable from PMU data, taking low-frequency forced oscillation as an example, a method for filtering LFD in PMU data is proposed. First, the effect of low-frequency oscillation to the fundamental frequency variable is analyzed in this paper. Then, the component of LFD in PMU data is explained. By finding the maximum value and minimum value of voltage or current in PMU data to draw the envelopes and add them together, the mean value or fundamental frequency variable of voltage and current is obtained. The mechanism of error in calculating active power is analyzed when low-frequency oscillation occurs in the power grid. The results of analyzing actual PMU data under low-frequency oscillation verify the correctness of the method proposed in this paper. This method is of great significance to improve the accuracy of calculation in SCADA. [ABSTRACT FROM AUTHOR]

Published

2017

24. Bubbles and Blisters Impact on Diecasting Cage to the Designs and Operations of Line-Start Synchronous Reluctance Motors.

Author

Liu, Huai-Cong, Hong, Hyun-Seok, Cho, Sooyoung, Lee, Ju, and Jin, Chang-Sung

Subjects

*BUBBLES, *BLISTERS, *STEEL bars, *RELUCTANCE motors, *FINITE element method

Abstract

This study investigates the starting capability of a high-efficiency synchronous reluctance motor for direct online industrial applications. Because of structural limitations, line-start synchronous reluctance motors (LS-SynRMs) are commonly diecasted by reducing pressure to ensure safe manufacturing. Hence, the shape of the squirrel-cage bars, including bubbles and blisters in the rotors of LS-SynRM, needs to be analyzed. In this paper, three different models are proposed to model the random bubble and blister phenomena by using 2-D finite-element analysis (FEA); their impacts on the flux paths and the change in exciting current of the squirrel-cage bars due to the unbalanced bubbles are thoroughly evaluated. Finally, consider that the bubbles’ impacts are confirmed by manufacturing the prototype motor and performing the experiment. The results of FEA and the experiment clearly indicate that the impacts of additional bubbles and blisters need to be considered in the design of LS-SynRMs. [ABSTRACT FROM AUTHOR]

Published

2017

25. Comparative Analysis of Steady-State Models for a Switched Capacitor Converter.

Author

Wu, Bin, Wang, Laili, Yang, Lei, Smedley, Keyue Ma, and Singer, Sigmond

Subjects

*STEADY state conduction, *SWITCHING circuits, *CASCADE converters, *SIMULATION methods & models, *ELECTRIC charge

Abstract

A recently reported modeling methods for a switched capacitor converter either assume output as “firm” voltage or a resistor to facilitate calculation. When the size of output filter capacitor is moderate, accompanied by noticeable output ripple, previous modeling results may not provide accurate prediction and design guidelines. In this paper, a new modeling technique taking into account the output capacitor effect is proposed for simple dual-phase switched capacitor converters without complex coupling loops. The proposed model employs transient calculation, takes charge redistribution phase into account, and includes the duty cycle, switching frequency as well as output capacitor simultaneously in the final output impedance formula, which enhances accuracy of the model. It is suitable for interleaved and noninterleaved switched capacitor converters. The simulation and experimental results for the unity gain SC converter are provided to verify the proposed theory. [ABSTRACT FROM PUBLISHER]

Published

2017

26. Multi-Dimensional Taylor Network-Based Adaptive Funnel Tracking Control of a Class of Nonlinear Systems With Prescribed Performance

Author

Lei Chu, Yu-Qun Han, and De-Yu Duan

Subjects

0209 industrial biotechnology, Steady state (electronics), business.product_category, General Computer Science, Computer science, 02 engineering and technology, Tracking (particle physics), adaptive control, Tracking error, 020901 industrial engineering & automation, Control theory, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, funnel control, Steady state, General Engineering, Nonlinear system, Backstepping, Bounded function, 020201 artificial intelligence & image processing, Funnel, lcsh:Electrical engineering. Electronics. Nuclear engineering, nonlinear systems, business, Multi-dimensional Taylor network, lcsh:TK1-9971

Abstract

This paper presents an adaptive funnel control combined with multi-dimensional Taylor Network (MTN) for the prescribed tracking performance of a class of nonlinear systems. In order to make the tracking error satisfies the prescribed performance regarding the transient and steady state responses, a funnel variable is introduced and merged into the controller design. MTNs are employed to handle the nonlinear functions of systems, and an adaptive controller is constructively designed by the backstepping technique. It is proved that all the signals of the closed-loop system are bounded as well as the tracking error converges to a small neighborhood of the origin. Two examples are provided to illustrate the effectiveness of the control scheme proposed in this paper.

Published

2020

27. Scenario-based Unit Commitment Optimization for Power System with Large-scale Wind Power Participating in Primary Frequency Regulation

Author

Li Wei, Philip Asaah, Lili Hao, Dongliang Xie, Jing Ji, and Wang Haohao

Subjects

Transient state, TK1001-1841, Wind power, Steady state, Scale (ratio), Renewable Energy, Sustainability and the Environment, business.industry, Computer science, primary frequency regulation (PFR), Energy Engineering and Power Technology, TJ807-830, wind power, Renewable energy sources, Reliability engineering, Electric power system, Power system simulation, Production of electric energy or power. Powerplants. Central stations, Unit commitment optimization, Transient (oscillation), transient frequency safety, high-risk stochastic scenario, inner-outer iterative optimization, business, Randomness

Abstract

Continuous increase of wind power penetration brings high randomness to power system, and also leads to serious shortage of primary frequency regulation (PFR) reserve for power system whose reserve capacity is typically provided by conventional units. Considering large-scale wind power participating in PFR, this paper proposes a unit commitment optimization model with respect to coordination of steady state and transient state. In addition to traditional operation costs, losses of wind farm de-loaded operation, environmental benefits and transient frequency safety costs in high-risk stochastic scenarios are also considered in the model. Besides, the model makes full use of interruptible loads on demand side as one of the PFR reserve sources. A selection method for high-risk scenarios is also proposed to improve the calculation efficiency. Finally, this paper proposes an inner-outer iterative optimization method for the model solution. The method is validated by the New England 10-machine system, and the results show that the optimization model can guarantee both the safety of transient frequency and the economy of system operation.

Published

2020

28. An Approximation-Free Methodology to Tracking Control of Pure-Feedback Nonlinear Systems With Application to Hypersonic Flight Vehicles

Author

Huang Hanqiao, Meiyun Zhengmeiyun, and Yang Shui

Subjects

0209 industrial biotechnology, Steady state (electronics), General Computer Science, Computer science, Hypersonic flight, Stability (learning theory), 02 engineering and technology, prescribed performance, 020901 industrial engineering & automation, Control theory, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Non-triangular structural, Barrier function, pure-feedback, Steady state, Artificial neural network, General Engineering, State vector, hypersonic flight vehicles, Function (mathematics), Lipschitz continuity, Nonlinear system, 020201 artificial intelligence & image processing, lcsh:Electrical engineering. Electronics. Nuclear engineering, barrier function, lcsh:TK1-9971

Abstract

This article addresses the problem of approximation-free prescribed performance control (PPC) for a class of non-triangular pure-feedback nonlinear dynamics whose nonaffine function of each subsystem is relaxed to rely on the whole state vector. The assumption made in this work is far more relaxed than all the available works in the sense that some commonly used Lipschitz condition or setting bounding function are never involved and only the continuity of nonlinearities are required. Furthermore, the proposed low-complexity PPC is simplified because neither approximators (neural networks and fuzzy logic systems) nor adaptation technique are embeded in the control design. By utilizing the barrier functions, some transient and steady state performances can be also preserved, while guaranteeing the closed-loop stability. Simulation results of hypersonic flight vehicles (HFVs) dynamics eventually validate the effectiveness of the proposed methodology.

Published

2020

29. A New Non-Smooth Simplified Model for DFIG in Electromechanical Transient Analysis

Author

Wu Yu, Wang Zizhe, Fu Xiaoyu, Dengke Qiao, Ancheng Xue, and Liu Ruihuang

Subjects

Crowbar, electromechanical transient analysis, Steady state, General Computer Science, Computer science, 020209 energy, 020208 electrical & electronic engineering, General Engineering, simplified mode, energy accumulation, 02 engineering and technology, Transient analysis, Non smooth, law.invention, Stator voltage, law, Control theory, 0202 electrical engineering, electronic engineering, information engineering, Limiter, DFIG, General Materials Science, Transient response, lcsh:Electrical engineering. Electronics. Nuclear engineering, Doubly fed electric machine, lcsh:TK1-9971

Abstract

The transient of the DFIG engages a lot of non-smooth elements such as switches of controllers and saturation of limiters, thus, the simplified non-smooth model of DFIG for electromechanical transient analysis is needed. This paper proposes a non-smooth simplified model of DFIG for electromechanical transient analysis, with the viewpoint of the transient response and energy accumulation. First, the general non-smooth dynamic behavior of DFIG during fault-on and post-fault periods are presented and the model is divided into four smooth stages. Then, the detailed model for the transient stage, according to without/with the trigger of the crowbar is presented. Furthermore, the simplified model of DFIG in the steady state is introduced according to without/with the trigger of the crowbar and saturation of limiters, determined by the stator voltage. Moreover, the transient model with/without the crowbar protection are simplified according to the principle of constant energy accumulation. Thus, the overall non-smooth simplified models of DFIG is obtained. Finally, the effectiveness of the proposed non-smooth simplified model is verified with the simulations.

Published

2020

30. Low-Complexity Dual-Vector-Based Predictive Control of Three-Phase PWM Rectifiers Without Duty-Cycle Optimization

Author

Xiaolong Shi, Li Li, Jianguo Zhu, and Dylan Dah-Chuan Lu

Subjects

Steady state, 08 Information and Computing Sciences, 09 Engineering, 10 Technology, General Computer Science, Computer science, model predictive control, General Engineering, Power (physics), Model predictive control, Three-phase, cost function, Duty cycle, Control theory, duty-cycle-control, General Materials Science, duty-cycle optimization, lcsh:Electrical engineering. Electronics. Nuclear engineering, AC/DC conversion, lcsh:TK1-9971, Pulse-width modulation, Power control

Abstract

© 2013 IEEE. The conventional model-predictive-based direct power control (MPDPC) of the three-phase full-bridge AC/DC converters chooses the best single voltage vector for the following control period, which results in variable switching frequency and power distortion, and thus a relatively higher sampling frequency is needed to achieve acceptable results. This paper proposes a simplified dual-vector-based predictive direct duty-cycle-control (SPDDC) with an additional zero vector implemented in contrast to the MPDPC. With the same best vector selection method, the proposed strategy has retained the control simplicity with just one more step added and much better control performance as well as a fixed switching frequency in comparison to the MPDPC. On the other hand, the duty-cycle optimization procedure is eliminated while the negative duration issue is essentially resolved compared with the conventional dual-vector-based model predictive duty-cycle-control (MPDCC). Comprehensive comparisons of various control methods by numerical simulation and experimental testing show that the SPDDC can achieve better steady state and dynamic performance than the MPDPC and simpler algorithms than the MPDCC.

Published

2020

31. Dynamics of evanescently-coupled laser pairs with unequal pumping: analysis using a three-variable reduction of the coupled rate equations

Author

Hadi Susanto, Michael J. Adams, Ian D. Henning, Martin P Vaughan, and Rihab Al Seyab

Subjects

Coupling, Physics, QA75, Steady state, Computation, Rate equation, Laser, Atomic and Molecular Physics, and Optics, Vertical-cavity surface-emitting laser, law.invention, QA76, law, Statistical physics, Electrical and Electronic Engineering, Algebraic number, Reduction (mathematics)

Abstract

The five coupled rate equations used to describe laterally-coupled pairs of lasers with weak coupling and unequal pumping are reduced to a new system of three equations. This enables approximate closed-form steady-state solutions and explicit expressions for the boundaries between regions of stable and unstable dynamics to be found. The results of applying these approximations to specific cases of coupled laser pairs are shown to be in good agreement with results obtained from numerical solutions of the original set of five equations as well as earlier results from the literature. In addition the approximations based on the reduced set of equations allow a systematic investigation of the effects of material, device and operating conditions on trends and novel features in the dynamics of laterally-coupled laser pairs. The algebraic results give insight into trends with parameters without the need for extensive numerical computation and should therefore be of use in modelling two-element VCSEL arrays for numerous potential applications.

Published

2022

32. On Age of Information for Discrete Time Status Updating System With Ber/G/1/1 Queues

Author

Jixiang Zhang and Yinfei Xu

Subjects

Signal Processing (eess.SP), FOS: Computer and information sciences, Queueing theory, Steady state, Computer science, Stochastic process, Information Theory (cs.IT), Computer Science - Information Theory, State vector, Expression (mathematics), Distribution (mathematics), Discrete time and continuous time, FOS: Electrical engineering, electronic engineering, information engineering, Electrical Engineering and Systems Science - Signal Processing, Algorithm, Queue

Abstract

In this paper, we consider the age of information (AoI) of a discrete time status updating system, focusing on finding the stationary AoI distribution assuming that the Ber/G/1/1 queue is used. Following the standard queueing theory, we show that by invoking a two-dimensional state vector which tracks the AoI and packet age in system simultaneously, the stationary AoI distribution can be derived by analyzing the steady state of the constituted two-dimensional stochastic process. We give the general formula of the AoI distribution and calculate the explicit expression when the service time is also geometrically distributed. The discrete and continuous AoI are compared, we depict the mean of discrete AoI and that of continuous time AoI for system with M/M/1/1 queue. Although the stationary AoI distribution of some continuous time single-server system has been determined before, in this paper, we shall prove that the standard queueing theory is still appliable to analyze the discrete AoI, which is even stronger than the proposed methods handling the continuous AoI., 9 pages, 3 figures, Accepted for presentation in ITW 2021

Published

2021

33. Research on Abnormal Heating Alarm Technology of Conductor Strain Clamp Based on Thermal Steady State Principle

Author

Wang Yi, Kong Xiaoang, Han Jingshan, and Bai Xu

Subjects

Electric power transmission, Clamp, Steady state, Reliability (semiconductor), Materials science, Transmission line, Thermal resistance, Thermal, Automotive engineering, Conductor

Abstract

With the continuous development of domestic power grid construction, coupled with the serious air pollution in some areas, the transmission line has been put into operation for a long time, resulting in the increasing phenomenon of abnormal heating of the tension clamp of the transmission line, which not only affects the safe operation and reliability of the power grid, but also restricts the improvement of the carrying capacity of the transmission line. Therefore, this paper studies the abnormal heating state of strain clamp in transmission line, and proposes an abnormal heating alarm technology of strain clamp based on online monitoring technology and thermal stability principle.

Published

2021

34. Steady-state Thermal Analysis of the Contact in Bearings Exposed to Electrical Currents

Author

Andreas Binder, O. Safdarzadeh, and Martin Weicker

Subjects

Bearing (mechanical), Steady state, Materials science, law, Bearing surface, Lubrication, Raceway, Mechanics, Temperature measurement, Electrical contacts, law.invention, Voltage

Abstract

Electrical bearing currents, e.g. in inverted-fed electrical machines, may disturb the performance of the bearings. In this paper the steady-state temperature of the bearing surface at the electrical contact point between the balls and the raceway is derived in the mixed lubrication state. The thermal analysis is presented based on the Holm‘s electric contact model, namely the a-spot. The contact model of Andreason is presented as well for comparison. The results are extended to predict the instantaneous contact surface temperature in an axial bearing (type 51208) at 500 rpm with 1 A average bearing current and with an axial bearing force of 800 N. Moreover the average of the contact surface temperature is obtained for the same bearing in a range of operating points, i.e. a rotating speed from 0 rpm to 3000 rpm, a bearing average current from 0.25 A to 3 A, at an axial bearing force 800 N. The results can be utilized to predict the contact temperature on the bearing surface for any given bearing from the measured bearing voltage.

Published

2021

35. Lifetime characterization of partial discharge properties of insulation material exposed to voltage pulse stress

Author

Edgar Moser, Werner Grubelnik, M.A. Vogelsberger, Ali Qerkini, and Thomas M. Wolbank

Subjects

Stress (mechanics), Steady state, Materials science, business.industry, Power electronics, Partial discharge, Optoelectronics, Drop (telecommunication), Signal edge, Transient (oscillation), business, Voltage

Abstract

The development of new technologies in the field of power electronics implies higher switching frequencies. Such frequencies are associated with higher transient voltages. Higher voltages mean stress on the insulation material. As result of this increased load, partial discharge (PD) probability can be increased, which may push the insulation material to its limits. Therefore, it is of high importance to recognize PDs. It is already known that PDs occur not only on the rising edge, but also in the steady state of a voltage pulse. However, double PDs may occur, too. Using a special test arrangement, it is possible to detect also weak PD activity, to localize the time instant and to determine changes in voltage and current. These changes are characterized e.g. by a sudden drop in pulse voltage.

Published

2021

36. A Design of Air System Control Algorithm for Full Power Fuel Cell Vehicles

Author

Jianqiu Li, Minggao Ouyang, Liangfei Xu, Zunyan Hu, Hui Tao, and Zhang Jianhui

Subjects

Steady state, law, Range (aeronautics), Control system, Flow (psychology), Overshoot (signal), Environmental science, Current (fluid), Cathode, Automotive engineering, law.invention, Power (physics)

Abstract

Extended range fuel cell vehicles are developing towards full power fuel cell vehicles, which require fuel cells to undertake most of the vehicle's power demand. Thus, fuel cell output power will change dynamically in a wide range, which may result in local gas shortage. It is necessary to design the control algorithm of fuel cell air supply system to ensure the sufficient reaction gas of fuel cell. This paper focuses on the dynamic characteristics and control method of fuel cell engine air supply system. The model of fuel cell system is built. And a new double-input and double-output control algorithm for air supply system is designed. The simulation results verified that the control algorithm performs well. The actual flow can track the target flow accurately whether the current step is up or down. The rising time of cathode inlet pressure is 0.1s and the overshoot is 1.8% when the load is rising. The falling time of cathode inlet pressure is 0.1s and the overshoot is 1.3% when the load is falling.

Published

2021

37. Control Strategies for Variable Speed Operation of Pumped Storage Plants with Full-size Converter Fed Synchronous Machines

Author

Olve Mo, Roy Nilsen, and Raghbendra Tiwari

Subjects

Steady state, Power station, Water flow, Computer science, Control system, Torque, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Synchronous motor, Turbine, Automotive engineering, Power (physics)

Abstract

The full-size converter fed synchronous machine (CFSM) for variable speed operation of a pumped storage power plant exhibits multiple advantages over the state-of-the-art Doubly Fed Induction Machine (DFIM) technology. The CFSM technology is emerging as the most preferred system for pumped storage plants for efficient operation in wide range of water flow which is not the case in existing power plants. This paper presents the steady state control strategies to execute the variable speed operation of the pumped storage power plants in both turbine and pump mode using full-size back-to-back converter. Also, how the power plant can be started in pump and turbine mode from standstill have been proposed. In addition, the seamless transition of operating modes from turbine to pump mode and vice versa are presented, which is not the case in today’s pumped storage power plants. The proposed control strategies are experimentally verified with a 100 kVA machine and converter setup with emulated reversible pump turbine (RPT).

Published

2021

38. Direct Charge Control Method for Mixed Conduction Mode (DCM and TPCM) Grid-Connected Inverter

Author

Qingxin Guan, Pu Zhao, and Yu Zhang

Subjects

Stress (mechanics), Physics, Steady state, Control theory, Charge control, Linear model, Control variable, Inverter, Charge (physics), Inductor

Abstract

Discontinuous conduction mode (DCM) for inverters requires a small size of inductor, and can realize soft switching for switches. However, the current stress under the DCM for two-level (2L) circuit is relatively high and there are still no linear models for the control. In this paper, T-type three-level (3L) circuit is used to construct the LCL-type grid-connected inverter (GCI). And the inverter-side inductor works under mixed conduction mode (MCM) combined by DCM when the load current is small and under trapezium conduction mode (TPCM) when it is high, so as to realize the soft switching in all switching cycles and reduce the current stress. In order to realize effective closed-loop control for the GCI under MCM, a linear charge quantity model (CQM) which takes the charge quantity output of the bridge as the control variable is proposed in this paper. Based on the proposed model, a direct charge control (DCC) method with a PID regulator working at fixed switching frequency is further proposed. Finally, the great steady-state and dynamic performance of the proposed model and control method is verified by the simulations and experiments.

Published

2021

39. Detection of defects in CFRP composites by Optical Thermographic methods

Author

Waldemar Swiderski

Subjects

Materials science, Steady state, Flash (manufacturing), business.industry, Infrared, Nondestructive testing, Thermography, Thermal, Delamination, Fibre-reinforced plastic, Composite material, business

Abstract

CFRP (Carbon Fibre Reinforced Plastic) composites are increasingly used in a variety of applications. N on-destructive testing methods are used for evaluating their condition both as a finished product and during their use. Damage that may occur in these types of composites includes air bubbles, nonuniform arrangement of fibres, regions of fibres not saturated with resin, delamination, and micro-cracks. Various methods of non-destructive testing are used to detect defects in such structures among the most effective of which are infrared thermography methods, the most common being optical heating with various types of lamps and the method of optical lock-in. Pulsed thermography is one of active IR techniques in which a surface of tested material is stimulated by a short heat pulse and the thermal response of the material is analysed. Flash thermography are used when the specimen is stimulated using a short energy pulse. The response contains information about subsurface material defects. After the heat pulse the temperature decrease rate is different on surface over defect in comparison to that over the sound material. In lock-in thermography, an amplitude modulated heat wave is applied to the inspected specimen in steady state. This paper seeks to compare the results obtained from pulsed and flash thermography with results from using optical lock-in thermography. The paper presents selected results of defect detection in a multilayer CFRP composite structure. The tests were carried out on a sample consisting of three plates made of CFRP connected with resin, in which the inner middle layer is made of four non-adherent elements.

Published

2021

40. Determination of Insulating Properties of SO2 gas from BOLSIG+ Calculated Swarm Transport Coefficients

Author

Mohd. Shahnawaz Khan, Akhilesh Kumar Pandey, Pushpendra Singh, and Jitendra Kumar Singh

Subjects

Sulfur hexafluoride, chemistry.chemical_compound, Materials science, Steady state, chemistry, Transport coefficient, Electrical breakdown, Breakdown voltage, High voltage, Mechanics, Dielectric, Boltzmann equation

Abstract

In this paper, the Transport Coefficient of SO 2 gas are calculated from swarm model design using BOLSIG+ which is user-friendly open-source computer program based on numerical solution of Boltzman equation (BE) up to two-term approximations. To ensure close agreement of calculated transport coefficients for SO 2 gas with impending experimental works, first we calculate these coefficients for SF 6 , and CO 2 compared the results with reported values. Reasonable agreement is found between calculated and report transport coefficients. For realistic acceptance of SO2 gas as SF6 alternative in long-term for high voltage applications, we discussed the utilization of these coefficients in study of various electrical breakdown related phenomenon to understand its dielectric and electrical insulating behavior during electrostatic discharge. We also predict numerical values of insulating properties in uniform electric field under steady state conditions such as electric strength, breakdown voltage and ionization constant for SO 2 gas using transport coefficients. For SO 2 gas, some of these properties and values are being calculated for first time.

Published

2021

41. Steady State Load Flow Model of DFIG-Based Wind Turbine in Voltage Control Mode

Author

Rudy Gianto

Subjects

Electric power system, Steady state, Wind power, Electricity generation, Control theory, business.industry, Computer science, Power-flow study, AC power, business, Turbine, Voltage

Abstract

The application of DFIG (Doubly Fed Induction Generator) in wind driven electric power generation has been increasing lately. In general, DFIG-based wind turbine has the capability to operate at two different control modes (i.e. power factor control mode and voltage control mode). However, the voltage control mode of operation has the advantage that the DFIG can be arranged to operate at a specified voltage magnitude and improve the system voltage profile. Load flow analysis is the most fundamental analysis in power system studies. Load flow analysis is usually carried out to assess the steady performances of a power system. The crucial and important step in conducting load flow analysis is modeling of the power system components. The present paper discusses a simple steady state load flow model of DFIG-based wind turbine in voltage control mode. The proposed model can be used for load flow studies of modern electric power system embedded with DFIG-based wind turbine.

Published

2021

42. Variable Step Perturb and Observe Algorithm for Standalone Solar Photovoltaic (PV) System

Author

Jatin Yadav, M. T. Shah, and Sunil Yadav

Subjects

Operating point, Steady state, Maximum power principle, Computer science, business.industry, Photovoltaic system, Solar energy, business, Algorithm, Maximum power point tracking, Power (physics), Voltage

Abstract

To extract the maximum power from available solar energy, the Maximum Power Point Tracking (MPPT) technique is used in solar photovoltaic system. Due to its simplicity and ease of implementation, the Perturb and Observe (P and O) technique is a commonly used approach to track the maximum power point (MPP). However, P and O algorithm oscillates near MPP point and give slow dynamic response. This paper presents a modified P and O method with a variable step size. This modified method is an effort towards overcoming the two major limitations of the conventional P and O method, first is oscillations near MPP and the second is loss of a tracking of MPP point during sudden change in irradiance. Here, the change in the step size is different according to the region of voltage, which will be decided by the difference between a voltage of the current operating point and MPP at desired irradiance. The proposed P and O gives good tracking accuracy in dynamic conditions and very less oscillations near the MPP as accepted. Detailed simulation analysis is done considering various steady-state and dynamic irradiance conditions for both the conventional and modified P and O methods and detail comparative result analysis is presented to validate the effectiveness of proposed algorithm. Proposed method improves the power quality and increase the efficiency of power conversion. Real time implementation is also easy.

Published

2021

43. An Affine Projection Algorithm based control of Grid-tied PV-DSTATCOM System

Author

Satish Choudhury, Byomakesh Dash, Bidyadhar Subudhi, and Renu Sharma

Subjects

Steady state, Rate of convergence, Maximum power principle, Control theory, Computer science, Integrator, Photovoltaic system, Point (geometry), Transient (oscillation), Grid

Abstract

This paper proposes an affine projection (AP) algorithm based on maximum correntropy criterion (MCC) to mitigate the disturbances in grid parameters of a photovoltaic (PV) based distribution system. Variable step size is introduced in the algorithm to improve the convergence rate and to reduce the steady-state (SS) error during transient conditions. To alleviate the effects of grid disturbances on system performances dual enhanced generalized integrator (DESOGI) is used. Reference dc voltage for voltage control loop is obtained by using P&O maximum power point (MPP) technique. Smooth power flow between the source and grid is accomplished during daytime and during bad weather or night condition, the whole system acts as DSTATCOM to improve the power quality as per IEEE-519 standard.

Published

2021

44. A Sliding Mode Control of an Electromagnetic Actuator Used in Aircraft Systems

Author

Salwan Obaid Waheed Khafaji, Hasan H. Ali, Fawaz F. Al-Bakri, and Sarah K. Lami

Subjects

Physics, Nonlinear system, Steady state, Position (vector), Control theory, Electromagnetic coil, Overshoot (signal), Actuator, Sliding mode control, Voltage

Abstract

A nonlinear electromagnetic actuator (EMA) system that consists of a mechanical motion and electromagnetic circuit is considered in this paper. The dynamics of the electrical and mechanical parts of the system were modeled. Steady-state conditions, in which the actuator position, actuator velocity, and coil current were assumed constants, were used as reference approaches for closed-loop scenarios. A sliding mode control method was applied to design the closed-loop coil voltage such that the nonlinear system slides along a certain sliding surface. The reliability of the presented control law was approved under a wide range of steady-state actuator position dispersions and coil voltage disturbances using Monte-Carlo simulation method. Numerical results with 1000 simulations were obtained to test the presented control law. The simulated results ensured the ability of the EMA to reach the steady-state conditions with fast response, excellent overshoot, and outstanding performance despite the wide range of system uncertainties.

Published

2021

45. Performance Comparison of BLDC Permanent Magnet Machines with Different Topologies

Author

Andrii Masliennikov, Oleksandr Dobzhanskyi, Andrii Yehorov, Pavani Gottipati, Oleksii Duniev, Ernest Mendrela, and Ebrahim Amiri

Subjects

Quantitative Biology::Subcellular Processes, Physics, Steady state, Remanence, Electromagnetic coil, Rotor (electric), law, Stator, Magnet, Mechanical engineering, Flux, Topology (electrical circuits), law.invention

Abstract

This paper presents a comparative electromagnetic performance analysis of different topologies of Brushless DC (BLDC) Permanent Magnet (PM) machines. In particular, five distinct motor configurations with different rotor structures (i.e., axial flux machine with disk rotor, radial flux machine with inner rotor, and radial flux machine with outer rotor), stator structure (i.e., slotted and slot-less) and winding arrangements (i.e., concentrated winding and distributed winding) are presented, their steady-state electromagnetic performances are compared and conclusions are made on their key differences. The analysis is carried out using field and circuit models. In addition, the impact of the magnets remanence on the motor performance is highlighted.

Published

2021

46. Identification and Optimal Control of a Dynamical System via ANN-based Approaches

Author

Viatcheslav Loveikin, Yuriy Romasevych, and Oleksandr Shevchuk

Subjects

Identification (information), Work (thermodynamics), Steady state, Artificial neural network, Control theory, Computer science, Particle swarm optimization, Unconstrained optimization, Dynamical system, Optimal control

Abstract

A solution of the optimal control problem has been found in the work. It involves two artificial neural networks for the identification and control of a dynamical system. In order to train them, two different methods were applied: gradient-based and gradient-free. The former is for identification; the latter is for the solution of the optimal control problem. In order to obtain the weights and biases of neurocontroller, the initial problem has been reduced to the unconstrained optimization problem. A modification of particle swarm optimization (gradient-free) method has been applied to train a neurocontroller. Its high performance has been validated by carrying out an experimental study.

Published

2021

47. Analysis of DC-DC Converters by Averaging Method based on Lagrange Theorems

Author

Yurii Rudenko

Subjects

Steady state, Mathematical model, Control theory, Differential equation, Ripple, Choke, Converters, Constant (mathematics), Mathematics, Voltage

Abstract

This paper presents a new approach for generating the state-space averaged model of dc-dc converters in the basis of relative variables using the Lagrange theorems. Averaged mathematical models of boost, buck and buck-boost converters have been developed, allowing the analysis of steady-state processes in continuous conduction mode (CCM) and discontinuous conduction mode (DCM). It is shown that a new approach to obtaining averaged models makes it possible to calculate not only the constant components of the process, but also their pulsation components, as well as the duration of the time intervals of the steady-state process, which is an advantage over traditional averaging methods. Using the obtained models, the dependences of the current ripple of the storage choke relative to the load current and the voltage transfer coefficient of the converters were calculated in the entire range of regulation of the switching duration.

Published

2021

48. Current-Voltage Characteristics Simulations of Organic Solar Cells Using Discontinuous Galerkin Method

Author

A. Khalf, Sandra Zivanovic, J. Gojanović, Petar Matavulj, and N. Ćirović

Subjects

Steady state, Materials science, Organic solar cell, Discretization, business.industry, Finite difference method, Thermionic emission, 7. Clean energy, Robin boundary condition, Computational physics, Discontinuous Galerkin method, Optoelectronics, business, Voltage

Abstract

The steady state drift-diffusion model (DDM) of organic solar cells that considers the surface recombination processes for majority and minority carriers, as well as their thermionic emission on both electrodes, is presented in this paper. When the full Robin boundary conditions (BCs) and the popular finite difference method with Schaffeter-Gummel discretization (FDSG) were applied, significant instabilities were observed when surface recombination velocities (SRVs) for majority carriers on one or both electrodes were reduced. To analyze this problem and perceive the independent impacts of electron and hole contact processes, the model was simplified by assuming a constant electric field in the device and by solving the electron and hole continuity equations separately. The stability of numerical DDM solutions obtained by the FDSG and Discontinuous Galerkin (DG) methods for three different types of BCs (Dirichlet and two mixed BCs) was examined. The DG method showed a better stability when majority carriers SRVs were reduced. The current density versus voltage (J-V) characteristic calculated by the DDM with Dirichlet BCs using the DG method was compared to the measured ITO/PEDOT:PSS/P3HT:PCBM/Al solar cell J-V curve for the model validation.

Published

2021

49. Simulation of L3-Harris L-4953 Crossed-Field Amplifier

Author

Jim Browning, Peter Stoltz, Marcus Pearlman, John W. Luginsland, Allen L. Garner, and Mike Worthington

Subjects

Physics, Crossed-field amplifier, Steady state, law, Amplifier, Bandwidth (signal processing), Saturation (graph theory), Order (ring theory), Approx, law.invention, Computational physics, Power (physics)

Abstract

Currently, there is a lack of publicly available design specifications for Crossed-Field Amplifiers (CFAs), which severely impedes CFA research in the public domain. The L3-Harris CFA, L-4953, was commonly used for the Air Route Surveillance Radar (ARSR-1/2) since the 1970’s. This is a high power $\left( {P_{out}^{peak} \approx 5\;{\text{MW}},P_{out}^{avg} \approx 3.2\;{\text{kW}}} \right)$ , moderate gain (G=11.2 dB), pulsed ( t pulse = 1.8 µs), L-band (f = 1.28 to 1.35 GHz), reentrant, backward wave, thermionic cathode amplifier. Our group has been developing a particle-in-cell (PIC) model of the CFA to study power saturation and the effects of electron injection. Here, VSim is used to validate the model against CFA operation specifications, such as gain, bandwidth, and dispersion. Preliminary, non-optimized simulation results show as table 9 dB gain at in only 10 ns with a relatively coarse grid of 101×101×60 cells. The short time required to reach steady state and the low number of grid cells allows for short simulation times on the order of only a few hours for common multi-core processors. This makes this CFA design an ideal standard for simulation studies. Additional simulation studies are planned using ICEPIC. We will report the results of the simulations, comparison between the two different PIC codes, assessment with operating specifications, and studies of the electron injection models.

Published

2021

50. Investigation of the Acoustic Emission Field in a Half-space from the System of Coplanar Cracks

Author

O. M. Stankevych, M. O. Babyak, and N. V. Stankevych

Subjects

Surface (mathematics), Materials science, Steady state, Dynamic problem, Field (physics), Acoustic emission, Geometry, Half-space, Inverse problem, Integral equation

Abstract

The solution of the dynamic problem of the acoustic-emission field displacements in an elastic half-space generated by steady-state displacements of the surfaces of a circular cracks system is obtained. The solutions are obtained by the boundary integral equations (BIEs) method. For the case of mode III cracks, the dependences of elastic displacements on the surface of the half-space on the wave number, the number of defects and the depths of their location are analyzed.

Published

2021