Showing total 20,322 results

1. A state model for the drying paper in the paper product industry.

Author

Berrada, Mouhsine and Tarasiewicz, Stanislaw

Subjects

INDUSTRIAL electronics, PAPERMAKING machinery industry

Abstract

Presents a state variable model for the drying section of a paper-making machine. Linearization and design of the model; What the solution for the model yielded; Specification of boundary conditions; Comparison of the obtained results with dynamic model results; What the study concluded.

Published

1997

2. Repetitive Control Meets Continuous Zero Phase Error Tracking Controller for Precise Tracking of B-Spline Trajectories.

Author

Biagiotti, Luigi, Califano, Federico, and Melchiorri, Claudio

Subjects

TRACKING control systems, FEEDBACK control systems, LINEAR control systems, CONFERENCE papers, DYNAMICAL systems, ARTIFICIAL satellite tracking

Abstract

In this paper, a novel repetitive control scheme is presented and discussed, based on the so-called B-spline filters. These dynamic filters are able to generate a B-spline trajectory if they are fed with the sequence of control points defining the curve. Therefore, they are ideal tools for generating online reference signals with the prescribed level of smoothness for driving dynamic systems, possibly together with a feedforward compensator. In particular, a continuous zero phase error tracking controller (ZPETC) can be used for tracking control of nonminimum phase systems but because of its open-loop nature it cannot guarantee the robustness with respect to modeling errors and exogenous disturbances. For this reason, ZPETC and trajectory generator have been embedded in a repetitive control scheme that allows to nullify interpolation errors even in nonideal conditions, provided that the desired reference trajectory and the disturbances are periodic. This paper is based on the results presented in the conference paper [L. Biagiotti, F. Califano, and C. Melchiorri, “Repetitive control of non-minimum phase systems along b-spline trajectories,” in Proc. IEEE 55th Conf. Decis. Control, 2016, pp. 5496–5501.], where asymptotic stability of the overall control scheme has been proved mathematically, but extends such results with an experimental validation based on a nonminimum phase system. Different models of the same physical system have been identified and used in the implementation of this model-based control scheme, allowing a real evaluation of the relationship between control system performance and model accuracy. [ABSTRACT FROM AUTHOR]

Published

2020

3. Dynamic and Vibration Analysis of a Multimotor DC Drive System With Elastic Shafts Driving a Tissue Paper Machine.

Author

Michael, Costas A. and Safacas, Athanasios N.

Subjects

*ROTATIONAL motion (Rigid dynamics), *RIGID dynamics, *ELECTRONIC systems, *FREQUENCIES of oscillating systems, *OSCILLATIONS, *THYRISTORS, *ELECTRIC current rectifiers, *COMPUTER software, *POWER transmission

Abstract

In this paper, the influence of the stiffness and damping of real elastic shafts on the behavior of a multidrive system driving a tissue paper machine is investigated. The drive system consists of four dc motors, where two of them drive the Yankee drying cylinder and the other two drive the presses section. Six-pulse thyristor bridge power converters that are connected to the same power transformer supply the motors. The inertias of the motors and the driven machines, in conjunction with the shaft stiffness, form mechanical resonators. Thus, resonance phenomena may occur, which may lead to undesirable results. This particular case results to two three-mass and one five-mass systems. This paper presents an analysis of the resonance frequencies of two sections of the machine during startup and machine production, considering the shaft stiffness (shaft diameter, length, and thickness). The elastic shafts eliminate the ripple of the motor electromagnetic torque, which is transferred to the driven machine. The behavior of elastic shafts with different stiffness in the transmission system is studied. Moreover, the steady state and dynamic behavior of the system considering the influence of the elastic shafts and vibration analysis were investigated using simulation. A model algorithm for system simulation was developed using the MATLAB/SIMULINK software. Characteristic simulation results are presented and are expressed in terms of speed and torque response. Considering the resonance frequency analysis and simulation results, mechanical design guidelines can be given for the most significant drive components in order to avoid torsional oscillation resonance phenomena and minimize torsional oscillations of the drive system. [ABSTRACT FROM AUTHOR]

Published

2007

4. Outstanding Paper Awards and Distinguished Reviewers.

Subjects

*AWARD winners

Abstract

Presents IES society award recipients and distinguished reviewers for 2021. [ABSTRACT FROM AUTHOR]

Published

2022

5. Best Papers and Distinguished Reviewers.

Author

Levi, E.

Subjects

*INDUSTRIAL electronics, *EMAIL, *DIGITAL Object Identifiers

Abstract

The article announces winners of the periodical's 2020 outstanding papers including a paper by L. Guo on deep convolutional transfer learning network, and a paper by C. Li on modified neutral point balancing space vector modulation.

Published

2021

6. Realization of Rewinder With a Reduced Number of Sensors.

Author

Jeftenić, Borislav I. and Bebić, Milan Z.

Subjects

MACHINERY, ESTIMATION theory, PROGRAMMABLE logic devices, FIELD programmable gate arrays, PAPER industry

Abstract

When adequately maintained, the mechanical system of rewinders and similar machines in paper industry may have a significantly longer service life than its electrical and control systems. Over the lifetime of the facility, a rewinder may experience several major maintenance cycles, and these generally include significant upgrades to the electrical drive and control system. These upgrades present an opportunity to modify the design of the control system to eliminate some of the sensors or to provide signal redundancy by using state estimation. During such major reconstruction of a paper-board rewinder, it was noticed that the shipping-roll radius and the web tension force can be accurately estimated from the measurements available within the drive's control system. This paper presents the implementation of the two estimators on a commercial production rewinder. Test results from the equipment in service show that the measured signals can be supplemented with the estimated ones to provide an alternative in the event of sensor malfunction or to enable trending of accuracy of calibration. Both applications have an entitlement to reduce the downtime of the rewinder, as the replacement of the faulted sensor can be scheduled for the next planned idle period of the machine. [ABSTRACT FROM AUTHOR]

Published

2010

7. Best Papers and Distinguished Reviewers.

Author

Levi, E.

Subjects

*INDUSTRIAL electronics, *PERMANENT magnet motors, *EMAIL

Published

2020

8. Smart Test Strips: Next-Generation Inkjet-Printed Wireless Comprehensive Liquid Sensing Platforms.

Author

Su, Wenjing and Tentzeris, Manos M.

Subjects

MICROFLUIDICS, FLUIDICS, NANOFLUIDS, RADIO frequency identification systems, IDENTIFICATION equipment

Abstract

By combining radio-frequency identification (RFID) and paper-microfluidics technologies, a low-cost first-of-its-kind platform for comprehensive liquid sensing, i.e., the “smart test strip,” is presented, which enables portable wireless real-time liquid sensing with handhold devices (e.g., cell phones), and integration of various multifunctional electrical and chemical sensors, for numerous Lab-on-Chip applications, including manufacturing control, environmental monitoring, and point-of-care medical diagnostics. The fabrication of RFID tags and two types of microfluidics are accomplished by a single inkjet-printing process in a cost-effective environmental-friendly additive manufacturing approach, which makes possible the production of disposable, lightweight, and flexible sensing platforms. Taking advantage of the proposed smart test strips platforms, we demonstrate two proof-of-concept high-performance electrical sensors based on interdigitated electrode topologies: a resistivity-based sensor with a 1782 $\Omega$/( $\Omega$*m) sensitivity; nevertheless, the proposed permittivity-based sensor with a 15%/$\epsilon _r$ sensitivity, but the proposed integrated wireless platform, can facilitate the integration of even more chemical and electrical sensors. In addition, two on-strip antenna prototypes have been designed, optimized, and tested to work at 2.4 GHz and 13.56 MHz, respectively. Furthermore, the wireless interrogation of a complete proof-of-concept smart test strip is presented, which shows an excellent sensing resolution of 1.33 $\Omega$ over the range of 0–1371 $\Omega$. [ABSTRACT FROM PUBLISHER]

Published

2017

9. Guest Editorial.

Author

Kaynak, Okyay, Bartoszewicz, Andrzej, and Utkin, Vadim I.

Subjects

SOFT computing, WIND turbines

Abstract

The article discusses various topics published within the issue including one about the development of soft computing, another on the concept of variable-structure control for uniform ultimate boundedness control and one about the power generation control in wind turbines.

Published

2009

10. Guest Editorial.

Author

Capolino, Gérard-André and Boglietti, Aldo

Subjects

PERMANENT magnet motors, BRUSHLESS direct current electric motors, FAULT tolerance (Engineering)

Abstract

An introduction is presented in which the author discusses topics in the issue including permanent-magnet motors, brushless direct current (dc) motors, and fault tolerance in the electrical drives of aircraft.

Published

2012

11. Guest Editorial.

Author

Capolino, Gérard-André and Boglietti, Aldo

Subjects

MACHINERY

Abstract

The article discusses various topics published within the issue including one by R. R. Moghaddam and colleagues on the theoretical and experimental reevaluation of synchronous reluctance machine, one by J. Smajic and colleagues on the coupling effects between electromagnetic and thermal phenomena, and one by M. I. Masoud and colleagues on the theoretical aspects of special machines.

Published

2010

12. Adaptive Power Transformer Lifetime Predictions Through Machine Learning and Uncertainty Modeling in Nuclear Power Plants.

Author

Aizpurua, Jose Ignacio, McArthur, Stephen D. J., Stewart, Brian G., Lambert, Brandon, Cross, James G., and Catterson, Victoria M.

Subjects

TRANSFORMER insulation, PREDICTION models, MEASUREMENT errors, POWER transformers, NUCLEAR power plants

Abstract

The remaining useful life (RUL) of transformer insulation paper is largely determined by the winding hot-spot temperature (HST). Frequently the HST is not directly monitored and it is inferred from other measurements. However, measurement errors affect prediction models and if uncertain variables are not taken into account this can lead to incorrect maintenance decisions. Additionally, existing analytic models for HST calculation are not always accurate because they cannot generalize the properties of transformers operating in different contexts. In this context, this paper presents a novel transformer condition assessment approach integrating uncertainty modeling, data-driven forecasting models, and model-based experimental models to increase the prediction accuracy and handle uncertainty. The proposed approach quantifies the effect of measurement errors on transformer RUL predictions and confirms that temperature and load measurement errors affect the RUL estimation. Forecasting results show that the extreme gradient boosting (XGB) algorithm best captures the nonlinearities of the thermal model and improves the prediction accuracy among a number of forecasting approaches. Accordingly, the XGB model is integrated with experimental models in a particle filtering framework to improve thermal modeling and RUL prediction tasks. Models are tested and validated using a real dataset from a power transformer operating in a nuclear power plant. [ABSTRACT FROM AUTHOR]

Published

2019

13. Spectral Leakage-Driven Loopback Scheme for Prediction of Mixed-Signal Circuit Specifications.

Author

Kim, Byoungho and Abraham, Jacob A.

Subjects

INTEGRATED circuits, SYSTEMS on a chip, BUILT-in self tests (Engineering), HARMONIC analysis (Mathematics), ANALOG-to-digital converters

Abstract

The rising cost of production testing for a system-on-a-chip (SoC) is one of the crucial matters to chip makers, due to long test time and costly automated-test-equipment. This paper proposes a spectral leakage-driven built-in self-test (BIST) scheme to precisely predict the nonlinearity of mixed-signal circuits in the loopback mode, thereby accomplishing cost-effectiveness (compared to previous BIST-based works). A digitally synthesized single-tone sinusoidal stimulus used for conventional harmonic testing is incoherently sampled by a device under test (DUT). The DUT output signal exhibits the correlation between the DUT harmonics and the spectral leakage introduced by the incoherent sampling. The DUT output signal is then fed to another DUT through a loopback path, so that the harmonics of a pair of DUTs are correlated with the spectral leakage on the loopback response; the magnitude of the spectral leakage is considered as a weighting factor on the harmonic magnitude of those DUTs. The correlation is quantitatively modeled as characteristic equations in , and postprocessing predicts the harmonics of the two individual DUTs, by simultaneously solving the characteristic equations using on-chip DSP core available in an SoC. Simulation and hardware measurements validated that this paper can be practically used for production testing by showing less than 0.3 and 0.6 dB of the prediction errors, respectively. [ABSTRACT FROM AUTHOR]

Published

2019

14. Guest Editorial.

Author

Chang, Elizabeth, Dillon, Tharam S., Damiani, Ernesto, Manic, Milos, Karduck, Achim P., Kuster, Marc, Talevski, Alex, Stan, Sergiu-Dan, and Petersen, Stig

Subjects

EDITORIALS, INDUSTRIAL electronics, PUBLICATIONS, PUBLISHING, PERIODICAL articles, AUTHORS, EDITORS

Published

2011

15. High-Performance LED Drivers.

Author

Wang, Yijie, Alonso, J. Marcos, and Ruan, Xinbo

Subjects

LIGHT emitting diodes, PERFORMANCE of light emitting diodes, LIGHT emitting diode efficiency, LIGHT emitting diode equipment, LIGHT emitting diode design & construction

Abstract

The fourteen papers in this special section focus on high performance light emitting diode (LED) drivers. In recent years, as the fourth generation of light source, light-emitting diodes (LEDs) have been widely used in many applications such as street lighting, automotive, and residential lighting because of their long lifetime, low maintenance requirement, and environment friendliness. As the performance of LEDs will be influenced obviously by the drivers, researchers have shown a growing interest in optimizing the drivers. Although these problems such as current balancing, eliminating electrolytic capacitor, and improving the topologies are not new, the high-frequency high-efficiency trend of LED drivers has given rise to additional challenges. These papers provide an insight on some of the newly emerging challenges and potential solutions to overcome those issues. [ABSTRACT FROM PUBLISHER]

Published

2017

16. Intelligent Modeling and Optimization for Smart Energy Hub.

Author

Liu, Tianhao, Zhang, Dongdong, Dai, Hang, and Wu, Thomas

Subjects

INTELLIGENT transportation systems

Abstract

This paper proposes an intelligent modeling and optimization method to set up the smart energy hub model for the multiple energy system and optimize the operation of its associated energy hub model automatically. The core idea of the proposed method is to divide the complex energy hub model into several simple energy hub models. In this paper, the proposed computerized algorithm, which is applied to the smart energy hub model division, includes an energy loop intelligent searching method, a real nodes arrangement method, and a virtual nodes insertion method. One case study for the multiple energy system of a residential district in Guangzhou city is performed to validate the effectiveness of the proposed method. Compared with the traditional calculation method, the proposed method guarantees global optimal operation decision for the whole multiple energy system and the computational burden is significantly reduced. [ABSTRACT FROM AUTHOR]

Published

2019

17. Approximate Cost-Optimal Energy Management of Hydrogen Electric Multiple Unit Trains Using Double Q-Learning Algorithm.

Author

Li, Qi, Meng, Xiang, Gao, Fei, Zhang, Guorui, and Chen, Weirong

Subjects

ENERGY management, ELECTRIC multiple units, HYDROGEN as fuel, TOTAL cost of ownership, ENERGY consumption, ALGORITHMS

Abstract

Energy management strategy (EMS) is the key to the performance of fuel cell / battery hybrid system. At present, reinforcement learning (RL) has been introduced into this field and has gradually become the focus of research. However, traditional EMSs only take the energy consumption into consideration when optimizing the operation economy, and ignore the cost caused by power source degradations. It would cause the problem of poor operation economy regarding Total Cost of Ownership (TCO). On the other hand, most studied RL algorithms have the disadvantages of overestimation and improper way of restricting battery SOC, which would lead to relatively poor control performance as well. To solve these problems, this paper establishes a TCO model including energy consumption, equivalent energy consumption and degradation of power sources at first, then adopt the Double Q-learning RL algorithm with state constraint and variable action space to determine the optimal EMS. Finally, using hardware-in-the-loop platform, the feasibility, superiority and generalization of proposed EMS is proved by comparing with the optimal dynamic programming and traditional RL EMS and equivalent consumption minimum strategy (ECMS) under both training and unknown operating conditions. Results prove that the proposed strategy has high global optimality and excellent SOC control ability regardless of training or unknown conditions. [ABSTRACT FROM AUTHOR]

Published

2022

18. Introduction to the Special Section on Industrial Applications and Implementation Issues of the Kalman Filter.

Author

Auger, François, Guerrero, Josep M., Hilairet, Mickaël, Katsura, Seiichiro, Monmasson, Eric, and Orlowska-Kowalska, Teresa

Subjects

KALMAN filtering, SENSORLESS control systems, POWER electronics

Abstract

An introduction to the special section on industrial applications and implementation of Kalman filter (KF) is presented in which the authors discuss various reports within the issue on topics including sensorless control of electrical machines, power electronics, and data processing.

Published

2012

19. Guest Editorial.

Author

Harashima, Fumio, Tanie, Kazuo, and Yamaguchi, Toru

Subjects

HUMAN-machine systems

Abstract

The article discusses various papers published within the issue including one by N. Kubota and K. Nishida on natural interface using pointing behavior for human-robot gestural interaction and another one by G. Ogawa and colleagues on onboard evolutionary risk recognition system for automobiles.

Published

2007

20. Diagnosis and Prognosis for Complicated Industrial Systems—Part II.

Author

Yin, Shen, Ding, Steven X., and Zhou, Donghua

Subjects

FAILURE analysis, CAMERA mounts, ACTUATORS

Abstract

This special section on "Diagnosis and Prognosis for Complicated Industrial Systems?Part II? is the continuation of its previous part I (IEEE Transactions on Industrial Electronics, Vol. 63, Issue 4, 2016). The diagnosis and prognosis approaches can be roughly classified into two categories: 1) model-based and 2) data-driven approaches. The model-based approaches perform the diagnosis and prognosis relying on the physical models from first principles, whereas the data-driven approaches make full use of the process data to monitor the systems under consideration. Due to the increasing complexity of the industrial system, new challenges are encountered in diagnosis and prognosis of such complicated systems, and more efficient process monitoring approaches are needed. From this point of view, the papers included in this section are focused on the recent developments of diagnosis and prognosis for complicated industrial systems, providing novel ideas and referential directions for both the academic and industrial communities. [ABSTRACT FROM PUBLISHER]

Published

2016

21. Advances in Converter Control and Innovative Exploitation of Additional Degrees of Freedom for Multiphase Machines.

Author

Levi, Emil

Subjects

HYBRID electric vehicles, CASCADE converters, TRACTION (Engineering), ELECTRIC power, DEGREES of freedom, WINDING machines

Abstract

Multiphase variable-speed drives and generation systems (systems with more than three phases) have become one of the mainstream research areas during the last decade. The main driving forces are the specific applications, predominantly related to the green agenda, such as electric and hybrid electric vehicles (EVs), locomotive traction, ship propulsion, “more-electric” aircraft, remote offshore wind farms for electric energy generation, and general high-power industrial applications. As a result, produced body of significant work is substantial, making it impossible to review all the major developments in a single paper. This paper therefore surveys the recent progress in two specific areas associated with multiphase systems, namely power electronic supply control and innovative ways of using the additional degrees of freedom in multiphase machines for various nontraditional purposes. [ABSTRACT FROM AUTHOR]

Published

2016

22. A Novel Bidirectional Solid-State Circuit Breaker for DC Microgrid.

Author

Wang, Yufeng, Li, Weilin, Wu, Xuanlyu, and Wu, Xiaohua

Subjects

MICROGRIDS, DIRECT currents, SHORT circuits, ELECTRIC circuit breakers, ELECTRIC potential

Abstract

DC microgrid has attracted more and more attention due to its unique characteristics, but the development of a dc microgrid is also facing some challenges, such as interruption and isolation of short-circuit fault currents. Therefore, the dc circuit breaker plays an important role in ensuring the normal work of a dc microgrid. In this paper, a novel bidirectional dc solid-state circuit breaker is proposed to realize the bidirectional flow of energy, which ensures the higher operating efficiency of the dc microgrid. Compared with other solid-state circuit breakers, the proposed novel topology has simpler structure, common ground, and fewer components. First, this paper makes a detailed analysis of the different working stages of the circuit when the fault occurs in combination with simulation results of the circuit topology. Then, the standard of selecting the components through the calculation and analysis of the circuit is given in this paper. Finally, the performance of the novel bidirectional solid-state circuit breaker is verified by experiments. [ABSTRACT FROM AUTHOR]

Published

2019

23. A Novel Solid-State Circuit Breaker for On-Board DC Microgrid System.

Author

Li, Weilin, Wang, Yufeng, Wu, Xuanlyu, and Zhang, Xiaobin

Subjects

ELECTRIC circuit breakers, MICROGRIDS, ELECTRIC power systems, FAULT currents, THYRISTORS, ELECTRIC transformers

Abstract

The development of the dc microgrid system on-board has promoted the development of the dc circuit breaker, but short circuit fault may cause serious damage to the system. Many problems exist in the traditional dc circuit breaker such as long periods of fault interruption, complex circuit structure, existing arc, low reliability, and low anti-interference. Aiming to solve these problems, a novel solid-state dc circuit breaker is proposed in this paper. First, this paper analyzes the working principle and process of the circuit in detail according to the results of the simulation based on Saber. Second, this paper gives the criteria on how to choose the parameters of the components correctly in the circuit. The concept of the maximum fault resistance according to the minimum fault current is also introduced. Moreover, this paper analyzes the influence of the minimum fault ramp rate on the circuit performance. Finally, experimental results verify that the performance of this novel solid-state circuit breaker agree with the theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2019

24. Joint Geometric Unsupervised Learning and Truthful Auction for Local Energy Market.

Author

Park, Laihyuk, Jeong, Seohyeon, Kim, Joongheon, and Cho, Sungrae

Subjects

SMART power grids, ELECTRIC power, GEOMETRIC analysis, MATHEMATICAL analysis, ELECTRICAL energy

Abstract

Development of smart grid technologies has created a promising atmosphere for smart cities and energy trading markets. Especially, traditional electricity consumers evolve into prosumers who produce as well as consume electricity in modern power electric systems. In this evolution, the electric power industry has tried to introduce the notion of local energy markets for prosumers. In the local energy market, prosumers purchase electricity from distributed energy generators or the other prosumers with surplus electricity via a local power exchange center. For this purpose, this paper proposes joint geometric clustering and truthful auction schemes in the local energy markets. The proposed clustering scheme is designed for distribution fairness of the distributed energy generator for serving prosumers, where the scheme is inspired by expectation and maximization based unsupervised learning. Moreover, this paper proposes an auction mechanism for truthful electricity trading in a local energy market. In order to guarantee truthful electricity trading, the proposed auction mechanism is constructed based on the Vickrey–Clarke–Groves auction, which was proven to guarantee truthful operations. The Hungarian method is also considered in addition to the auction. The simulation results for the auction verify that the utilities of local market energy entities are maximized when the prosumers are truthful. [ABSTRACT FROM AUTHOR]

Published

2019

25. Introduction to the special section on advances in diagnosis for electrical machines, power electronics, and drives - Part I.

Author

Capolino, Gerard-Andre and Filippetti, Fiorenzo

Subjects

INDUCTION motors, ELECTRIC inverters, INDUCTION machinery

Abstract

Even if modern diagnostic techniques in power electrical engineering are considered as mature, there are still innovations to be published. Therefore, among the 188 papers submitted to this Special Section, 28 have been selected to be published in two parts. This Introduction is related to the first 14 selected papers, which have been divided into three topics dealing with: electrical machines failures detection with bearings (four papers), backlash phenomena (one paper), shaft trajectories (one paper), and winding short circuits (one paper); adjustable-speed drives with permanent-magnet synchronous machines (PMSMs) winding short circuits (one paper), drive sensors (one paper), prognosis (one paper), inverter open-circuit detection (one paper), and multiphase induction motors (one paper); power systems (one paper) and transformers (one paper) particular fault detection. [ABSTRACT FROM PUBLISHER]

Published

2013

26. Robust and Adaptive Estimation of State of Charge for Lithium-Ion Batteries.

Author

Zhang, Caiping, Wang, Le Yi, Li, Xue, Chen, Wen, Yin, George G., and Jiang, Jiuchun

Subjects

BATTERY management systems, SYSTEM identification, SYSTEM analysis, ELECTRIC power system identification

Abstract

The reliable operation of battery management systems depends critically on the accurate estimation of the state of charge (SOC) and characterizing parameters of a battery system. SOC estimation employs models that must be robust against variations in battery cell electrochemical features, aging, and operating conditions. This paper reveals that commonly used SOC estimation schemes are fundamentally flawed in providing the robustness of SOC estimation against model uncertainties. Parameter estimation methodologies and adaptive SOC estimation design are introduced in this paper to enhance SOC estimation accuracy and robustness. By a scrutiny of the impact of parameter variations on SOC estimation accuracy, the SOC–open-circuit-voltage mapping is identified to be the most critical function that must be accurately established. Identification algorithms are introduced, and their convergence properties are established. The integration of the identification algorithms and SOC estimation schemes lead to an adaptive SOC estimation framework that is superior over the existing methods in providing much improved accuracy and robustness. Experimental studies are conducted to validate the algorithms. [ABSTRACT FROM PUBLISHER]

Published

2015

27. A Survey of Fault Diagnosis and Fault-Tolerant Techniques—Part II: Fault Diagnosis With Knowledge-Based and Hybrid/Active Approaches.

Author

Gao, Zhiwei, Cecati, Carlo, and Ding, Steven X.

Subjects

REDUNDANCY in engineering, FAULT tolerance (Engineering), RELIABILITY in engineering, SYSTEMS design, ERRORS

Abstract

This is the second-part paper of the survey on fault diagnosis and fault-tolerant techniques, where fault diagnosis methods and applications are overviewed, respectively, from the knowledge-based and hybrid/active viewpoints. With the aid of the first-part survey paper, the second-part review paper completes a whole overview on fault diagnosis techniques and their applications. Comments on the advantages and constraints of various diagnosis techniques, including model-based, signal-based, knowledge-based, and hybrid/active diagnosis techniques, are also given. An overlook on the future development of fault diagnosis is presented. [ABSTRACT FROM PUBLISHER]

Published

2015

28. Modern Diagnostics Techniques for Electrical Machines, Power Electronics, and Drives.

Author

Capolino, Gerard-Andre, Antonino-Daviu, Jose A., and Riera-Guasp, Martin

Subjects

INDUSTRIAL electronics, INDUCTION machinery, CONVERTERS (Electronics)

Abstract

An introduction is presented in which the editor discusses various reports within the issue on industrial electronics topics including induction machines, synchronous machines, and power components and power converters.

Published

2015

29. Guest Editorial.

Author

BELLINI, ALBERTO and FILIPPETTI, FIORENZO

Subjects

PREFACES & forewords, INDUSTRIAL electronics

Abstract

The article introduces papers published within the issue, including one about a method for rotor faults and mixed eccentricities relying on the discrete wavelet transformation of stator currents during speed variations and another on four different signal processing methods to pinpoint developing electrical faults.

Published

2008

30. Guest Editorial.

Author

Capolino, Gérard-André and Henao, Humberto

Subjects

EDITORIALS, ELECTRICAL engineering, ELECTRIC machines, ELECTROMECHANICAL devices, ELECTRIC fault location, ELECTRONICS periodicals

Published

2011

31. Multitask Bayesian Spatiotemporal Gaussian Processes for Short-Term Load Forecasting.

Author

Gilanifar, Mostafa, Wang, Hui, Sriram, Lalitha Madhavi Konila, Ozguven, Eren Erman, and Arghandeh, Reza

Subjects

LOAD forecasting (Electric power systems), SPATIOTEMPORAL processes, GAUSSIAN processes, FORECASTING, ELECTRIC power consumption, POWER resources

Abstract

Short-term household electricity load forecasting is important for utility companies to ensure reliable power supplies. Traditional methods for load forecasting relied on historical records from one single data source and have limitations with insufficient or missing data. Recently, an emerging family of machine learning algorithms, multitask learning (MTL), has been developed and has the potential for load forecasting. By MTL, the electricity consumption data from multiple communities can be fused to improve forecasting accuracy. However, appropriate modeling of the relatedness to enable the between-community knowledge transfer remains a challenge. This paper proposes an improved MTL algorithm for a Bayesian spatiotemporal Gaussian process model (BSGP) to characterize the relatedness among the different residential communities. It hypothesizes on the similar impacts of environmental and traffic conditions on electricity consumption in improving short-term load forecasting. Furthermore, this paper proposes a low-ranked dirty model along with an iterative algorithm to improve the learning of model parameters under an MTL framework. This paper uses a real-world case study from two residential communities in Tallahassee, Fl, USA, to demonstrate the method effectiveness. The proposed method significantly outperforms state-of-the-art forecasting methods and effectively captures the relatedness to provide between-community knowledge transfer compared with other MTL methods. [ABSTRACT FROM AUTHOR]

Published

2020

32. Analytical Modeling of Misalignment in Axial Flux Permanent Magnet Machine.

Author

Guo, Baocheng, Huang, Yunkai, Peng, Fei, Dong, Jianning, and Li, Yongjian

Subjects

AIR gap (Engineering), PERMANENT magnets, ELECTROMAGNETIC forces, FLUX (Energy), MAGNETIC fields, MAXWELL equations, FINITE element method, INDUCTION machinery

Abstract

This paper proposes an analytical model for the prediction of air gap magnetic field distribution for axial flux permanent magnet (AFPM) machine with various types of misalignments. The AFPM machine geometry is first transformed to a polar representation. Consequently, the subdomain model based on current sheet technique is developed. Then the stator coordinate system is chosen as reference coordinate to consider both static/dynamic angular and axis misalignments. The back electromagnetic forces and cogging torque are obtained accordingly based on Maxwell's equations. The results show that the proposed approach agrees with the finite-element method. The model is further validated by experiments under healthy, dynamic angular and axis misalignment conditions, which can validate the proposed approach. It turns out that the proposed approach can predict the performance of AFPM machines with types of misalignment quickly and effectively, which is greatly significant for further fault detection. [ABSTRACT FROM AUTHOR]

Published

2020

33. Extending Protection Selectivity in DC Shipboard Power Systems by Means of Additional Bus Capacitance.

Author

Kim, Seongil, Kim, Soo-Nam, and Dujic, Drazen

Subjects

BUSES, ENERGY storage, ELECTRIC potential, ELECTRIC capacity, ENVIRONMENTAL regulations

Abstract

DC shipboard power systems have been considered as a promising solution for stricter environmental regulations on ships due to their main benefits in fuel savings with variable speed engines and easy integration of energy storage systems. In order to employ the dc solution in the shipboard power systems, the dc power systems have to be protected from a system fault with protection selectivity to minimize impacts of the fault or to avoid other undesirable situations in the system. For low-voltage dc shipboard power systems, a three-level protection has been proposed: 1) fast action (first)—bus separation by solid-state dc bus-tie switch; 2) medium action (second)—feeder protection by high-speed fuse; and 3) slow action (third)—generator–rectifier fault controls. This paper proposes a new method by means of additional bus capacitance added in main dc buses to help reliable operation of the three-level protection. The principle of the proposed method is introduced and the sizing of the additional bus capacitance is addressed in this paper. With the modeling of the dc shipboard power systems, the analyses of voltage drops for the bus separation failure and fault clearing time for the feeder protection are carried out to verify the proposed method. The results show that the proposed method not only mitigates the voltage drop for the bus separation failure, but also achieves the selectivity and the sensitivity for the feeder protection. [ABSTRACT FROM AUTHOR]

Published

2020

34. Magnetic Field Analysis and Flux Barrier Design for Modular Permanent Magnet Linear Synchronous Motor.

Author

Tan, Qiang, Huang, Xuzhen, Li, Liyi, and Wang, Mingyi

Subjects

SYNCHRONOUS electric motors, PERMANENT magnets, MAGNETIC fields, MODULAR design, MAGNETIC field effects

Abstract

Modularization design has been widely used to reduce the detent force of permanent magnet linear synchronous motor (PMLSM). For modular PMLSM, ideally, unit motors are independent of each other and the detent force of the whole motor is the sum of that for unit motors; thus, the whole motor's detent force can be suppressed by adjusting the phase difference among the unit motors’ detent forces. But actually, there is coupling effect between adjacent unit motors, which has adverse effect on the detent force suppression. The coupling effect changes the magnetic field distribution, which is often neglected in current research. Hence, this paper carries out the research on magnetic field analysis and flux barrier design for modular PMLSM considering the coupling effect: the influence of the coupling effect on the air gap magnetic field is clarified through magnetic field analysis; the coupling force is isolated by finite element analysis, and then the effects of key parameters are discussed; the whole motor's detent force model considering the coupling effect is established, and an optimal design method of adjusting the flux barrier length is presented to suppress the detent force. Finally, a prototype is made to test the detent force characteristics with different flux barrier lengths, which verifies the research theory in this paper. The research results in this paper can provide guidance and reference for the design of modular PMLSMs. [ABSTRACT FROM AUTHOR]

Published

2020

35. An Analytical AC Resistance Calculation Method for Multiple-Conductor Feeder Cables in Aircraft Electric Power Systems.

Author

Zhang, Yaojia, Wang, Li, and Meng, Lexuan

Subjects

ELECTRIC power systems, ELECTRIC cables, MICROGRIDS, SIMULATION software

Abstract

In multiphase ac power systems, e.g., aircraft electric power systems (EPS), the proximity effect between the feeder cables can be severe and complex due to the tightly wired cable bundles. Simulation software is widely used to analyze such effects in order to guarantee proper system operation, but it is highly time consuming and requires extensive computational resources. Accordingly, this paper proposes an analytical calculation method for estimating the ac resistance of closely bundled power cables, namely multiconductor cables. Simulation and experimental tests are performed to validate the effectiveness and accuracy of the method, showing that the algorithm developed in this paper is easy to implement with a minimum accuracy of 92% in all the tests. It allows online estimation of cable resistances, which can be beneficial for advanced system monitoring and management to enhance safety and reduce losses. Aircraft EPS and cables are used as the example in this paper, while the proposed method is also applicable for other applications, such as shipboard EPS, renewable energy parks, or microgrids where multiconductor cables are used. [ABSTRACT FROM AUTHOR]

Published

2020

36. Active Disturbance-Rejection-Based Speed Control in Model Predictive Control for Induction Machines.

Author

Yan, Liming, Wang, Fengxiang, Dou, Manfeng, Zhang, Zhenbin, Kennel, Ralph, and Rodriguez, Jose

Subjects

TORQUE control, PREDICTION models, TORQUE, SPEED

Abstract

Finite set model predictive torque control (FCSMPTC) of induction machines has received widespread attention in recent years due to its fast dynamic response, intuitive concept, and ability to handle nonlinear constraints. However, FCSMPTC essentially belongs to the open-loop control paradigm, and unmatched parameters inevitably cause electromagnetic torque tracking error. In addition, the outer loop (i.e., the speed loop) based on a proportional-integral (PI) regulator cannot achieve optimal control between speed dynamic response and torque tracking error compensation. The traditional control paradigm is abbreviated as PI-MPTC. In order to solve the aforementioned problem, this paper proposes active disturbance-rejection-based model predictive torque control (ADR-MPTC). First, the influence mechanism of mismatched parameters on torque prediction error in PI-MPTC is studied, and then the performance of a traditional PI regulator used to compensate for torque prediction error is analyzed. Second, this paper introduces several parts of the proposed ADR-MPTC, including the design of the torque prediction error observer, nonlinear prediction error compensation strategies, an enhanced predictive torque control, and a simplified full-order flux observer. Finally, PI-MPTC and ADR-MPTC are studied experimentally. The experimental results show that compared with PI-MPTC, ADR-MPTC performs better in dynamic and steady states, and has stronger robustness. [ABSTRACT FROM AUTHOR]

Published

2020

37. Prognostics for Linear Stochastic Degrading Systems With Survival Measurements.

Author

Si, Xiaosheng, Li, Tianmei, Zhang, Qi, and Hu, Changhua

Subjects

WIENER processes, STATE-space methods, MEASUREMENT, STOCHASTIC systems

Abstract

This paper addresses the problem of how to estimate the remaining useful life (RUL) for partially observed linear stochastic degrading systems with survival measurements. The motivation of this paper arises from two engineering facts—the measured degradation signals are taken from a survival degradation path and the degradation progression of the system is inevitably affected by multisource variability. To do so, we first revisit the linear degradation modeling framework driven by the Wiener process to account for the above two facts, and a new state-space model with non-Gaussian state transitions is constructed based on the constraint of survival measurements. Then, the particle filtering algorithm is applied to real-time estimate the non-Gaussian degradation state and random-effect parameter from measurements. Furthermore, we derive the probabilistic distribution of the RUL which can be real-time updated based on the available measurements. To apply the presented method, a two-stage estimation procedure based on particle expectation maximization algorithm is presented to determine and update the model parameters. The novelty of the presented method is to exclude the probability of failure before the current monitoring time and account for both impacts of the multisource variability and surviving degradation path on the RUL estimation. Finally, we demonstrate the proposed approach by a case study on gyros in the inertial platform. [ABSTRACT FROM AUTHOR]

Published

2020

38. Virtual Temperature Detection of Semiconductors in a Megawatt Field Converter.

Author

Rannestad, Bjorn, Fischer, Katharina, Nielsen, Peter, Gadgaard, Kristian, and Munk-Nielsen, Stig

Subjects

POWER semiconductors, DATA conversion, SEMICONDUCTORS, WIND turbines, BIPOLAR transistors, ELECTRIC current rectifiers

Abstract

A converter monitoring unit (CMU) that monitors the power modules of the converter in a multimegawatt test wind turbine is presented in this paper. A method of calculating the virtual temperature ($T_{v}$) of the power semiconductors is laid out. Contrary to previous work, the method enables $T_{v}$ characterization of the semiconductors by means of sampled data during normal operation of the converter, without the need for special calibration routines. The dynamic operation of the wind turbine and the large amount of data sampled in the CMU enables a statistical approach to generate reference data for $T_{v}$ calculations. The method was tested on machine side converter diodes of the test turbine, based on samples of collector-emitter voltage ($vce_{\text{on}}$) and current ($i_{c}$). Other temperature sensitive electrical parameters may also be used as input to the method. The CMU has been operating for more than a year in the test turbine, showing consistent data throughout the whole period. While the monitoring method and results are based on measurements on a single test turbine, the paper also link these to converter failure data from a large fleet of operating turbines. [ABSTRACT FROM AUTHOR]

Published

2020

39. Online Fault Diagnosis of External Short Circuit for Lithium-Ion Battery Pack.

Author

Xiong, Rui, Yang, Ruixin, Chen, Zeyu, Shen, Weixiang, and Sun, Fengchun

Subjects

FAULT diagnosis, SHORT circuits, LITHIUM-ion batteries, ELECTRIC vehicle batteries, ELECTRIC batteries

Abstract

Battery safety is one of the most crucial issues in the utilization of lithium-ion batteries (LiBs) for all-climate electric vehicles. Short circuit, overcharge, and overheat are three common field failures of LiBs. In this paper, online fault diagnosis for external short circuit (ESC) of LiB packs is investigated. The experiments are carried out to obtain and compare ESC characteristics of 18650-type NMC battery pack and single cell. Based on the analysis of experimental results, a two-step equivalent circuit model is established to describe the ESC process and an online model-based scheme is proposed to diagnose ESC faults of battery packs. The proposed scheme is evaluated by experimental data. The results show that it can effectively diagnose ESC faults in 3.5 s after their occurrences with the terminal voltage error less than 25 mV. The proposed scheme has shown great generalization ability. ESC faults of battery packs under different number of cells connected in series and unavailable current information can also be diagnosed at the terminal voltage error less than 48 and 60 mV, respectively. [ABSTRACT FROM AUTHOR]

Published

2020

40. Omnidirectional Touch Probe With Adaptive Maneuvering for 3-D Object Machining and Measurement Verification Applications.

Author

Luo, Ren C. and Perng, Yi Wen

Subjects

REVERSE engineering, LASER beam cutting, MACHINING, VIDEO excerpts, PERIODONTAL probe, INTERPOLATION, MOLECULAR probes

Abstract

In this paper, automated omnidirectional touch probe (ODTP) including adaptive tuning of the complex contour curve with optimal interpolation and motion planning based on a hybrid multiaxis robot (HMAR) with dual drive gantry-type machine (DDGM) are presented. It is called an “omnidirectional” because the 6-degrees of freedom ODTP in tool center point mode can always maintain normal direction towards the object contour curve. The new optimal solutions of the interpolation and motion planning are provided to tackle the small segments issues for a complex curvature object. We present an algorithm to maintain maximum acceleration, so that it generates smooth and efficient three-dimensional reverse object in a higher order complex contour trajectory composed of piecewise small segments. As a result, the constant moving speed is very important to certain applications, such as gluing, welding, and laser cutting, to preserve quality processing. The utilization of object symmetry, extension, and synthesis properties to simplify the process of performing reverse engineering is described. These methods reduce the time required for the touch probe to detect the points. The experimental implementation to demonstrate the success of this paper with video clip are presented. [ABSTRACT FROM AUTHOR]

Published

2020

41. Sensor Glove Based on Novel Inertial Sensor Fusion Control Algorithm for 3-D Real-Time Hand Gestures Measurements.

Author

Chang, Hsien-Ting and Chang, Jen-Yuan

Subjects

INERTIAL confinement fusion, HAND, MAGNETIC flux density, OPTICAL measurements, DETECTORS, MAGNETIC field measurements

Abstract

In recent years, there has been an increasing interest in hand movements in various application fields. However, the human hand is too dexterous and only has limited space. Developing a proper method to monitor and capture hand motion is meaningful. Conventionally, an optical measurement method is widely used to capture hand gestures. Nevertheless, this method is costly and has the problem of line-of-sight shielding. In this paper, a sensor fusion algorithm is proposed to calculate a more accurate result by calculating acceleration, magnetic field strength, and angular speed from the inertial measurement unit (IMU). The core concept of this algorithm is based on the idea of feedback control. To validate the performance, the active rotary platform is set up to compare the measured results to the references directly. Most of the error results are less than 3°, and the standard deviations are less than 1°. The measurement results ensure the feasibility of the inertial measurement method with the sensor fusion algorithm proposed in this paper. [ABSTRACT FROM AUTHOR]

Published

2020

42. A Pedagogical Study of Aerodynamic Feedback Control by Dielectric Barrier Discharge Plasma.

Author

Kwan, Pok Wang and Huang, Xun

Subjects

PLASMA flow, SHEAR flow, DIELECTRICS, STABILITY criterion, PLASMA confinement, VORTEX shedding

Abstract

Active flow control by means of plasma actuators has potential advantages over conventional strategies, e.g., mechanical or hydraulic components may be replaced by lightweight, compact, fast response plasma actuators. In this paper, several designs of dielectric barrier discharge (DBD) plasma actuators are presented for aerospace applications and the focus is on the associated feedback control implementation. The interdisciplinary nature of aerodynamic feedback control with plasma, however, makes direct experimental demonstrating an outstanding challenge. Here, we propose a realistic experimental control implementation afforded by commercial off-the-shelf electric products and the major achievement is the detailed instruction (in both electricity and aerodynamics) and the successful demonstration of the closed-loop design in controlling the dominant modes from a cylinder flow setup. The essence of our approach is to drive DBD plasma actuations by a downstream sensor and excite aerodynamic velocity perturbations, which are further amplified on the shear flow from the cylinder, leading to airflow structures, such as vortex roll-up and randomization, which are measured by the downstream sensor to complete the whole loop. We benchmark our control approach by comparing to the predicted dominant frequencies of the controlled flow system, which can be achieved by the Barkhausen stability criterion after establishing the corresponding transfer function of the whole flow control system. Overall, this paper shall assist a host of new applications in aerospace applications in the near future. [ABSTRACT FROM AUTHOR]

Published

2020

43. Fine Sensorless Force Control Realization Based on Dither Periodic Component Elimination Kalman Filter and Wide Band Disturbance Observer.

Author

Phuong, Thao Tran, Ohishi, Kiyoshi, and Yokokura, Yuki

Subjects

KALMAN filtering, SENSORLESS control systems, STATIC friction

Abstract

This paper proposes a new force estimation approach based on the dither periodic component elimination (DPCE) Kalman filter and the disturbance observer (DOB) for realization of a fine sensorless force control system under the existence of static friction. A dither signal is inserted to the desired reference signal to eliminate the effect of static friction of a ball-screw system. The DOB estimates the periodical torque caused by dither signal. The DPCE Kalman filter uses the periodical torque for the estimation of the high-order torque responses to achieve the torque estimation with the elimination of periodic component. The problem of noise in the force sensation and the effect of static friction are reduced effectively by using the DPCE Kalman filter. Therefore, the bandwidth of the force sensing is increased and the wide band DOB is achieved. As a result, this paper has accomplished the fine sensorless force control realization. The force control experiments of a ball-screw system are carried out to verify the validity and effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2020

44. Measurement of Refrigeration Capacity of Compressors With Metrological Reliability Using Artificial Neural Networks.

Author

Coral, Rodrigo, Flesch, Carlos Alberto, and Flesch, Rodolfo Cesar Costa

Subjects

MONTE Carlo method, COMPRESSORS, MATHEMATICAL functions, RELIABILITY in engineering, ARTIFICIAL neural networks

Abstract

This paper proposes and experimentally evaluates a method, which is able to measure the refrigeration capacity of compressors in extremely short times. Traditionally, the measurement of this parameter is done using specialized and expensive test rigs and can take up to 4.5 h for the measurement of a single compressor. To overcome this long measurement time, it is proposed to use a simpler measuring system, in which, instead of measuring the refrigeration capacity directly, the rate of pressure rise imposed by the compressor to a cylinder with fixed volume is measured. This paper shows that both variables have a high correlation factor when the test and compressor conditions are taken into account. As the correlation among the variables is nonlinear, it is not possible to use simple mathematical correlation functions, so neural networks are used for that purpose. By using the proposed method, the refrigeration capacity of a compressor can be determined in less than 7 s, which is approximately 0.05% of the time required by traditional methods. To guarantee the metrological reliability of the results presented by the proposed neural model, this paper proposes a novel approach based on the Monte Carlo and the bootstrap methods. [ABSTRACT FROM AUTHOR]

Published

2019

45. Precision 3-D Motion Tracking for Binocular Microscopic Vision System.

Author

Liu, Song and Li, You-Fu

Subjects

BINOCULAR vision, MOTION, OBJECT tracking (Computer vision), STATISTICAL accuracy, COMPUTER vision, KALMAN filtering

Abstract

In this paper, a three-dimensional (3-D) motion tracking method is proposed for binocular microscopic vision system to precisely record the motion trajectories of millimeter size objects in the Cartesian space. Primarily two fundamental problems are solved. The first problem arises from the limited depth of field (DOF) of microscope. Considering the motion of the objects, the existing autofocusing methods requiring sequential images either in focus or defocus are not workable. Therefore, a one-shot prior autofocusing approach is desired, which needs to take the motion tendency of objects into account. Besides, the autofocusing process always lags behind the motion of objects, and there inevitably will be prediction deviation on the motion tendency of objects. This leads to the second problem to estimate the 3-D motion states from defocused images. In this paper, we first explain the defocusing process from the perspective of S-Transform, based on which the Bayesian inference inspired method to estimate the depth from defocus from one single image is derived thereafter. Afterwards, a motion states, including both the position and velocity, estimation approach is developed within the Kalman filter framework. The above two aspects mutually supply the necessary information for each other to be functional to accurately realize the DOF tracking and motion tracking of moving objects. Experiments were well-designed to validate the effectiveness of the proposed method, and experiments result showed a tracking precision of 3 μm was achieved. [ABSTRACT FROM AUTHOR]

Published

2019

46. New Emerging Technologies in Motion Control Systems—Part II.

Author

Tsuji, Toshiaki, Sabanovic, Asif, Ohishi, Kiyoshi, and Iwasaki, Makoto

Subjects

MOTION control devices, DIRECT currents, ACTUATORS

Abstract

An introduction is presented in which the editors discuss various reports within the issue including one on new emerging technologies in motion control systems, one on control of direct current (dc) motors, and one on linear actuator with high backdrivability.

Published

2014

47. Fine Force Reproduction Based on Motion-Copying System Using Acceleration Observer.

Author

Yokokura, Yuki, Ohishi, Kiyoshi, and Katsura, Seiichiro

Subjects

HUMAN-computer interaction, ACCELERATION (Mechanics), MECHANICAL impedance, ACTUATORS, VIBRATION (Mechanics)

Abstract

This paper proposes a new motion-copying system that is capable of preserving and reproducing the motion of human operators. In conventional motion-copying systems, when the operator moves quickly, the reproduced force does not correspond to the stored force, owing to the large accelerations. Therefore, the motion-copying system proposed in this paper uses acceleration responses provided by acceleration observers, so the force is reproduced more accurately. The acceleration observer is based on a disturbance observer; it estimates the acceleration of an actuator without acceleration sensors. Furthermore, the estimation performance is not affected by the mechanical impedance of the target environment. In this article, the proposed motion-copying system is compared with current methods, and the validity of the method is demonstrated. [ABSTRACT FROM PUBLISHER]

Published

2014

48. Design of a Sliding-Mode-Controlled SEPIC for PV MPPT Applications.

Author

Mamarelis, Emilio, Petrone, Giovanni, and Spagnuolo, Giovanni

Subjects

SLIDING mode control, PHOTOVOLTAIC cells, CASCADE converters, ELECTRIC inductors, MAXIMUM power point trackers, MATHEMATICAL models

Abstract

In this paper, the procedure for designing a sliding-mode controller for maximum power point tracking photovoltaic (PV) applications is proposed. It is applied to a single-ended primary inductor converter, thus to a fourth-order topology, but it can be extended to a wide class of converters suitable for PV applications. The reachability and existence conditions give rise to a number of design inequalities that add to the classical steady-state conditions in order to have the desired closed-loop converter's performances. The superiority of the control technique over the classical tracking methods is analytically demonstrated through the procedure proposed in this paper. The analytical results have been validated by means of both simulations and experiments. [ABSTRACT FROM PUBLISHER]

Published

2014

49. A Fuzzy Logic Approach by Using Particle Swarm Optimization for Effective Energy Management in IWSNs.

Author

Collotta, Mario, Pau, Giovanni, and Maniscalco, Vincenzo

Subjects

WIRELESS sensor networks, FUZZY logic, PARTICLE swarm optimization, ENERGY consumption, ZIGBEE

Abstract

Industrial Wireless Sensor Networks (IWSNs) allow the use of battery-operated nodes to provide easy deployment, even in harsh environments, and are low maintenance. The optimal network design can be difficult because several constraints and requirements must be considered among all the power consumption. For this reason, specific approaches, also based on soft computing methods, can be applied in such a way as to further decrease the energy consumption in IWSNs. To this end, this paper proposes a fuzzy logic based mechanism that, according to the battery level and the ratio of throughput to workload, defines the sleeping time of sensor devices in an IWSN based on IEEE 802.15.4 protocol. A particle swarm optimization (PSO) algorithm is introduced to obtain the optimal values and parameters of the proposed fuzzy logic controller (FLC), i.e., optimizing the membership functions, by varying their range, to achieve the best results regarding the battery life of sensor nodes. This paper provides a detailed description of the FLC configuration, a logical analysis of the PSO algorithm for the derivation of best performance conditions values, and simulative assessments obtained through MATLAB simulations. [ABSTRACT FROM AUTHOR]

Published

2017

50. Guest Editorial.

Author

Dean Jr., Robert Neal and Luque, Antonio

Subjects

MICROELECTROMECHANICAL systems, ELECTRON beam lithography

Abstract

The article discusses various reports published within the issue, including the reviews on the development of microelectromechanical systems (MEMS) by Dean and Luque, new numerical method to predict the results obtained when using electron-beam lithography by Chen and Yeh, and reports on transmission lines built in alumina on a silicon substrate by Li and Uttamchandani.

Published

2009