International Journal of Power Electronics (57 papers in press)
Research on Power Quality Comprehensive Control Device under the Situation of Medium Voltage and High Power Based on H-Bridge Cascade Converter
by Zhiqiang Zhou, Yu SHEN, Chengkuan WAN, Wei HU, Tao WANG, Hao TANG
Abstract: This paper proposes a power quality control device based on H-Bridge cascade converter, to solve the problems in current decentralized power quality control, such as huge investment in equipment, expensive operation and maintenance cost, hard to coordinate, and low global technical-economic ratio. It provides a novel thought for the comprehensive control of power quality under the situation of medium voltage and high power. This paper has three parts. In the first part, the topology structure and working principle of the power quality comprehensive control device based on H-Bridge cascade converter are analyzed, and its key parameters are analyzed and designed. In the second part, corresponding coordinated control strategy is proposed according to the function of power quality comprehensive control device. Finally, a 10kV/1MVA medium-voltage and high-power power quality comprehensive control device is designed. The simulation through MATLAB Simulink proves that the parameter design is correct and the coordinated control strategy is effective.
Keywords: H-Bridge Cascade Converter; Comprehensive Control of Power Quality; Coordinated Control Strategy; Parameter Design.
Adaptive Control Algorithm to Interface Fuel Cell and Photo Voltaic Energy Sources
by Shikha Gupta, RACHANA GARG, ALKA SINGH
Abstract: This paper presents the control algorithm for photovoltaic (PV) and fuel cell (FC) interfaced voltage-source converter (VSC). The control algorithm ensures uninterrupted power supply and reliable operation under variable power generation and load conditions. Hyperbolic tangent based least mean square (H-LMS) system is proposed to generate proper gating signal of the inverter. The basic function of generation sources is to meet the active power demand. Furthermore, the proposed system architecture has added features to balance the load, suppress the harmonics and compensate reactive power. These functionalities make sure that the supply current is sinusoidal even under nonlinear and unbalanced load conditions. The proposed algorithm provides fast computation and convergence rate. Comparison with conventional LMS is presented in terms of convergence rate and supply current harmonics under MATLAB/Simulink platform. The control algorithm is also examined for stability through Lyapunov stability criterion, thus, the error function of the algorithm converged to zero asymptotically.
Keywords: Solid oxide fuel cell; photovoltaic; renewable energy sources; voltage source converter; least mean square method; Lyapunov stability.
Effect of PWM Schemes on the Performance and Common-Mode Current of the Proposed Modified 7- Level H-Bridge Inverter
by Uvais Mustafa, M. Saad Bin ARIF
Abstract: In this paper, modified H-Bridge Seven level inverter topology is proposed. The performance of the proposed topology is evaluated in terms of the THD and the fundamental component of the output voltage for open-loop operation and in terms of Common Mode Current for the connected grid system. Implementation feasibility of different PWM techniques and their effect on the performance of the topology has been performed. The PWM switching based on a high frequency is used; as high-frequency PWM technique reduces the THD in the output voltage. The analysis shows that the Alternate Phase Opposite Disposition (APOD-PWM) based on a triangular carrier scheme offers the minimum THD of 15.72% for the unity modulation index while operating in an open loop, and in Phase Disposition (IPD-PWM) triangular carrier scheme offers the minimum common mode current of 222mA. Also, the output voltage decreases and the fundamental component increases with increment in modulation index is observed. Results obtained show that the topology has low THD as well as common mode current is well within limits for grid-tied applications.
Keywords: Total Harmonic Distortion (THD); Multilevel Inverter (MLI); modulation index; Pulse Width Modulation (PWM); Common Mode Current (CMC).
Photoelectric Composite Cable Temperature Calculations and Correction of its Parameters
by Tabi Fouda Bernard Marie, Dezhi Han
Abstract: A method for correcting the thermal resistance of the insulation layer by using the current difference and the conductor temperature difference is proposed paper. The optical fiber temperature of the three-core photoelectric composite submarine cable is measured by BOTDA; and the corresponding relationship between the temperature variation of the optical fiber and the conductor is performed by finite element analysis, thereby obtaining the difference in temperature of the conductor. After finite element analysis, the corrected thermal resistance is therefore replaced in the calculation. It has been shown by comparison that, the correction of the thermal resistance of the insulation layer can effectively improve the transmission capacity requirements of the cable and the accuracy of the calculation of the transient temperature rise of the conductor.
Keywords: Transient temperature rise of conductor; thermal path method; high-voltage three-core photoelectric composite submarine cable; thermal resistance of insulation layer; finite element; BOTDA.
Multilevel Converter Topology Suitable for Separate and Variable Magnitude of DC Sources
by Bikram Das, Debashis Chatterjee, Aniruddha Bhattacharya
Abstract: A new configuration of multilevel inverter (MLI) has been presented in this paper requiring less number of power semiconductor switches and driver circuits. The proposed topology has better switch utilization ratio (SUR) with reduction in inverter price. The circuit functional performance of MLI is validated through suitable simulation and experimental results on a laboratory prototype.The MLI has been considered for 5, 11 and 13-level configurations with different resistive and inductive load combinations. Both equal and unequal dc sources are considered to justify the feasibility of the topology.
Keywords: Multilevel inverter; cascaded configuration; loss calculation; switch utilization;.
A Novel Switched Capacitor Based Multilevel Inverter Structure for Renewable Energy Convertion System
by Gashaw Ango, Tapas Roy, Pradip Kumar Sadhu
Abstract: Switched capacitor multilevel inverters (SCMLIs) are one of popular solutions to mitigate the different limitations of conventional multilevel inverters (MLIs). A large number of innovative SCMLIs have been reported in literature in recent years. However, the large requirement of power switches, capacitors and large voltage stress across the switches are the major limitations of SCMLIs. In this paper, a novel MLI structure using switched capacitor principle has been proposed. It does not require any H-bridge circuit which reduces the switch stress voltage of the structure. It has the ability to produce 13 output voltage levels. Further, the cascaded arrangement of proposed basic structure has been realized The structure requires lower number of components as compared to the other SCMLIs. The operating principle, capacitor selection procedure and power losses of proposed structure have been discussed. Extensive simulation and experimental studies have been conducted to validate the effectiveness of the proposed structure.
Keywords: boosting factor; multilevel inverters; switched capacitor; series-parallel; voltage balancing.
SOLAR POWER-DRIVEN PERMANENT MAGNET SYNCHRONOUS MOTOR COUPLED WITH PUMP LOAD: DESIGN, DEVELOPMENT AND CONTROL
by Menka Dubey, Shailendra Sharma, Rakesh Saxena
Abstract: This paper presents design, development and control of solar photo voltaic (SPV) supply system for permanent magnet synchronous motor (PMSM) driven pump load. The proposed system is very effective in curtailing power demand on existing grid supply on highly dense population areas. An Incremental conductance method followed by sliding mode control scheme is used to track SPV array maximum power point (MPP) and vary the speed of the PMSM accordingly under the change in atmospheric conditions. The direct torque controlled (DTC), voltage source inverter (VSI) is employed to control the PMSM speed and to achieve stable operating point. A prototype of single stage SPV supply based PMSM coupled with DC machine is developed in laboratory for emulating the centrifugal pump characteristics. Performances under different environmental and operating conditions, are obtained on the developed prototype to prove the efficacy of the proposed control
Keywords: photo voltaic system; sliding mode control; permanent magnet synchronous motor; water pumping system.
A Passivity based Controller for an Interleaved Boost PFC Converter
by Kumari Shipra, Rakesh Maurya, S.N. Sharma
Abstract: This paper reveals a passivity-based control technique for the interleaved boost PFC converter. First, an Euler-Lagrange (EL) mathematical formulation for the interleaved boost PFC converter is developed. Then, the passivity-based control methodology is implemented in the system. The output voltage can be maintained constant via the introduction of the notion of the energy modification in passive components. In the controller design, the energy of the system is made non-conservative by adding damping factor. That makes the system become passive against disturbances. This paper develops a polynomial function for the damping injection to keep the desired output voltage constant against the variation of load current and input supply. The proposed controller offers several features such as ease of implementation, no tuning of parameters like proportion integral controller, robustness against disturbances as well. A Simulink model with the proposed controller is developed using MATLAB/Simulink block and its performances are investigated under various operating conditions. Further, real-time implementation, the stability analysis for the proposed controller is also carried out.
Keywords: Mathematical Modelling; the Euler-Lagrange; Boost Converter; Interleaved Control techniques; Passivity based Control.
Design and Implementation of Constant Flux Controller for VSI Assisted SEIG Feeding Induction Motor Pump
by Sachin Angadi, Udaykumar R. Yaragatti, Yellasiri Suresh, A.B. Raju
Abstract: In small scale, stand-alone, wind-power generation employing self-excited induction generator (SEIG), water pumping using an induction motor is a typical application. In this paper, a simple voltage regulation scheme for the constant flux operation of the inverter assisted SEIG feeding three-phase induction motor pump is presented. The behaviour of DC-link voltage, frequency, amplitude modulation index (ma) and the shaft speed for load and speed perturbations are discussed in detail. Also, the overall active and reactive power flow for constant flux operation at the point of common coupling (PCC) is analysed. The proposed work presents a simple and reliable controller for SEIG based stand-alone system for frequency-dependent loads using only a DC-link voltage sensor. Detailed system simulations are performed using Matlab/Simulink and the results of a laboratory prototype are presented to validate the theoretical analysis and practical operability of the proposed system.
Keywords: active power; constant flux; induction motor; induction generator; reactive power; SEIG; stand alone SEIG; voltage regulation; water pumping.
Finite Element and Analytic Equivalent Circuit Models for MSIM feeded by MPI controled by SVPWM Strategy to minimize circulation harmonic current
by Thouraya Guenenna, Khaled Smida, Adel Khedher
Abstract: This article deals with the determination of the Multi Stars Induction Machine (MSIM) equivalent circuit parameters based on the geometrical and electrical data using two methods namely analytic and Finite Element Method (FEM). Additionally, this paper proposes a general dynamic study of MSIM. This latter is fed by a Multi-Phase Inverter (MPI) controlled by a Space Vector Pulse Width Modulation (SVPWM) and a Sinusoidal Pulse Width Modulation (SPWM). However, when this machine is fed by the voltage inverter for the case of 30
Keywords: multi-stars induction machine (MSIM); analytic method; finite element method (FEM); space vector PWM; sinusoidal PWM; multi-phase inverter (MPI).
Rooftop based Magnetically Levitated VAWT with Specially Designed Guide Vanes for Enhanced Efficiency in Distributed Generation
by Nitin Gupta, Sandeep Banerjee
Abstract: This work proposes a practically feasible and distinct method of harvesting wind energy for urban and rural rooftops. This technique is especially useful for distributed generation. A one-fourth scaled version of a new type of wind energy conversion system (WECS) has been presented. The novelty of the reported WECS lies in the usage of a magnetically levitated vertical axis wind turbine (VAWT) along with dynamic guide vanes system. The usage of magnetic levitation results in loss minimization and efficiency maximization. To tap maximum wind energy, the guide vanes are programmed to dynamically change their angle according to the wind speed. This paper also presents the utility of an axial flux permanent magnet (AFPM) generator for VAWT systems. An experimental model has been developed and its results have been presented. The experimental results have been put to use for developing a model of the VAWT system using Fuzzy Inference System (FIS).
Keywords: distributed generation; guide vanes; magnetic levitation; vertical axis wind turbine; Venturi effect.
Comparative Analysis Between Different Approaches for Single-Phase PLLs
by Luis Monteiro, J.G. Pinto, Vitor Monteiro, Carlos Couto, Joao Afonso
Abstract: This paper presents a comparative analysis between two distinct synchronizing circuits, which are usually applied as the core of control algorithms for single-phase power quality applications. One of these synchronizing circuits corresponds to a single-phase Phase-Locked Loop (PLL), implemented in ?-? coordinates (??-PLL), whereas the other one corresponds to the Enhanced PLL (E-PLL). The major contribution of this paper is to present a single-phase PLL oriented to power quality applications, with a very simple structure, capable to be synchronized with the fundamental component of an input signal (voltage or current), even considering substantial disturbances, such as, frequency deviations, phase shifts, harmonic components and amplitude variations. Simulation and experimental results, involving these two synchronizing circuits submitted to three different test cases, are provided in order to compare their transient and steady-state performance. Moreover, it is also presented a comparison involving the processing speed and memory requirements of these synchronizing circuits in the DSP TMS320F28335.
Keywords: Phase-Locked Loop (PLL); alpha-beta-PLL; Enhanced PLL (E-PLL); Digital Signal Processor (DSP); Power Quality.
Investigations on Variable and Constant Switching Frequency Hysteresis Controller for VSI fed IM drive
by Joseph Peter, Rijil Ramchand
Abstract: In various Current Controlled-Pulse Width Modulated(CC-PWM) techniques which are extensively employed in high performance drives, Hysteresis Current Controllers (HCC) offer significant simple implementation and good dynamic response. However, conventional HCC have drawbacks, such as, limit cycle oscillations ,overshoot in current error, generation of sub-harmonic components in the current, and non-optimum switching of inverter voltage vectors which can create variable switching frequency. This work proposes a new constant switching Current Error Space Phasor (CESP) based hysteresis controller with a simple online computation of the boundary and phase voltage harmonic spectrum similar to Voltage Controlled Bus Clamping PWM (VC-BCPWM) based VSI fed Induction Motor drive. The error boundary computed using voltage and current errors in the present sampling interval is used for identifying next vector to be switched. The current controller using CESP approach is simulated using MATLAB SIMULINK and experimentally verified on 2.2 kW I.M drive.
Keywords: hysteresis; switching frequency; current error space vector; bus clamping PWM.
Control of single phase photovoltaic H6 inverter in grid-connected and stand-alone modes of operation
by Majid Abadi Marzoni, Seyed Mohammad Sadeghzadeh
Abstract: this paper proposes a control strategy for single phase transformerless photovoltaic H6 inverter with capability of operation in both grid connected and stand-alone modes. This control strategy enables seamless transition between two modes without any reconfiguration of control structure and need of any external communication. A multi loop control structure including an inner voltage and current control with PR controller and outer power control with droop controller is utilized to make the inverter operate in both modes. In grid-connected mode, the power control loop regulates reference voltage and frequency for voltage control loop, to adjust power flow of inverter to the main grid while in islanded mode, reference voltage and frequency are determined according to droop characteristic of inverter to supply local load demand. The simulation and experimental result are used to verify the performance of the proposed control.
Keywords: single phase H6 inverter; grid connected; stand alone; seamless transition.
Design and simulation of a voltage mode controlled boost converter for low power RF energy harvesting system
by Tapashi Thakuria, Tulshi Bezboruah
Abstract: In this work, a voltage mode feedback controlled DC to DC boost converter is designed and simulated for a medium wave based radio frequency (RF) energy harvesting system. The RF signal with an input power of 4 mW is converted to a DC signal which is stepped up and regulated by the boost converter. The DC to DC boost converter is controlled by a pulse width modulated circuit which generates a switching signal of frequency 100 kHz. A type-III compensator circuit is designed to regulate the output voltage at 3.3 V and 5 V which is suitable for low power applications.
Keywords: Radio Frequency(RF); Energy Harvesting; Boost Converter; Compensator; Voltage Mode Control.
Evaluation and Minimization of Total Harmonic Distortion in Three-Phase Two-Level Voltage Source Inverter with Low Switching Frequency
by Neerparaj Rai, Sandeep Chakravorty
Abstract: In this paper, an optimal Pulse Width Modulated (PWM) waveform over complete modulation index range in terms of least total harmonic distortion (THD%) is determined for two-level three-phase inverter. Two types of pole voltage PWM
waveforms specifically typeA and typeB have been considered at low pulse number (P = 5) owing to switching loss limitation. The different types of waveform can be distinguished by the positive or negative voltage transition at the point where the fundamental voltage has maximum positive slope. The cost function is formulated for each PWM waveform and a combination of Genetic Algorithm (GA) and Newton-Raphson (NR) method is used to obtain a total of two solution sets corresponding to typeA and typeB namely solution set-A and solution set-B. Based on the four solution sets, an optimal PWM waveform is proposed to minimize the low order harmonics for the inverter output. The optimal PWM waveform is evaluated and compared with conventional Selective Harmonic Elimination (SHE-PWM) and Sine-Triangle (ST-PWM) methods. The optimal PWM results in notably improved performance over ST-PWM and SHE-PWM for complete modulation index (M) range and above M = 0.6 respectively. The theoretical analysis and results are validated by MATLAB simulation and experimental studies for a two-level inverter.
Keywords: Selective harmonic elimination; PWM formulations; multilevel inverter; iterative techniques; optimization algorithms.
Superior Transient and Stability Performance of Voltage Regulation by Battery-fed Bidirectional Converter for Supporting Various Operational Modes of PMDC Machine
by Satyajit Saha, Pritam Gayen
Abstract: This paper presents systematic procedure to design voltage controller for achieving superior dynamic performance of battery-fed bidirectional converter for supporting operation of permanent magnet direct current (PMDC) machine. Nowadays, this system is extensively used in electric vehicle. Here, either motoring or regenerating mode of operation of the electrical machine is required. Therefore, voltage control action by bidirectional DC-DC converter plays an important role for supporting various operational modes of PMDC. In this respect, derivation of small signal model of overall system is given. At next, condition for absolute stability is calculated from the model on basis of Routh-Hurwitz criterion. Then, gains of proportional-integral (PI) controller have been tuned using Ziegler-Nichols tuning chart from derived values of ultimate gain and critical frequency as per conventional approach. But, the calculated gains from Ziegler-Nichols tuning chart do not provide satisfactory dynamic performance and sound stability margin under variable voltage conditions. Thus, performance of voltage regulation is deeply investigated and redesign of voltage controller is emphasized for achieving both superior dynamic performance and significantly stronger stability margin. Superior transient and stability performances of voltage control loop in proposed case are compared with that of conventional case. Proposed approach is verified in MATLAB-SIMULINK software based modelling of physical system and also, in experimental platform.
Keywords: Battery; bidirectional DC-DC converter; voltage controller; PMDC machine; motoring and regenerative mode; transient performance; relative stability.
Robust Control of Multi-phase Interleaved Boost Converters in the Presence of Perturbations and Open Phase Fault
by Sajjad Shoja-Majidabad, Sajed Derakhshani Pour
Abstract: In this paper, robust control of interleaved boost converters is studied under load and supply voltage perturbations and open phase fault. First, a new decentralized proportional-integral adaptive sliding mode control strategy is developed for the interleaved boost converters. In this status, each phase of the converter operates separately and the proportional-integral controller generates needed reference current from the voltage tracking error. Second, a novel proportional-integral adaptive sliding mode control method based on master-slave strategy is proposed. In this strategy, one phase of the converter acts as the master and the other phases act as the slaves. The master phase controls the voltage and others are responsible for their currents separately. However, the reference current is provided by average value of the converter phase currents. The adaptive gains of the proposed control methods are able to estimate the related perturbations without any prior knowledge. Comparative MATLAB/ Simpower simulations are carried out on a three-phase IBC to show the effectiveness of the proposed control strategies in the presence of load and supply voltage perturbations and open phase fault. Moreover, the tracking capability of both methods is verified by the simulations.
Keywords: Multi-phase interleaved boost converter; adaptive sliding mode control; decentralized control; master-slave control; open phase fault; load and supply voltage perturbations; equal current distribution.
Intelligent Adjustable-Speed Drive on an FPGA
by Azzouz Benzekri
Abstract: This paper addresses the design, simulation and implementation of a PI-like fuzzy controller to adjust the velocity of an armature-controlled DC motor using hardware/software co-design. Fuzzy control and digital pulse width modulation (PWM) techniques are used as computational solution, while the implementation is carried on a reconfigurable hardware platform. This controller is designed with four considerations in mind: design integration, robustness, reduced complexity and flexibility. Computationally intensive tasks are implemented as hardware accelerators using VHDL, data flow and control are implemented in software using system-on-programmable-chip (SoPC) approach. With this paradigm, we get the robustness of fuzzy control, the best of software programmability of Nios®-II and the hardware reconfigurability of the FPGA. The model was synthesised using Quartus®II and targeted at a Cyclone-II FPGA. Computer simulation results show the effectiveness and merit of this process. The real-time applicability of this controller is exemplified on a motor provided with a tachogenerator mounted on its shaft.
Keywords: FPGA; SoPC; Nios® II; VHDL; Hardware/Software Co-Design; Adjustable-speed drive; PWM; PI-like Fuzzy Controller; Armature-controlled; Quartus II.
Second order Sliding Mode Controller interlinked with DSTATCOM
For Mitigation of Total Harmonic Distortion
by Swetha K, Sivachidambaranathan V
Abstract: Power Quality (PQ) is demonstrated as any power crisis that consequence in the
misdirection of user devices. Electrical PQ is turning out to be widely concerned with both
electric appliances and customers. Voltage fluctuation remains as the most important PQ
crisis as it has a major effect on both the equipment and production environment.
DSTATSCOM is a significant device, which enhances the power factor and sustains stable
distribution voltage and alleviates harmonics in the distribution network. D-STATCOM
minimizes the voltage fluctuations and voltage instability of the power system that results in the speedy revival of system voltage after contingency occurrence. However, the THD
problem remains a major issue in D-STATCOM devices that affects system performance.
Hence, in this paper, efforts are made to minimize the THD problem in D-STATCOM
devices by connecting the Second-order Sliding Mode Controller (SoSMC) to D-STATCOM
linked system. The main objective of the proposed controlled model is to minimize the THD
so that the enhanced power quality can be attained. Moreover, the performance of the SoSMC
controller is evaluated over the traditional PI controllers, and the results are analyzed.
Keywords: Power Quality;D-STATCOM; Total Harmonic Distortion; Second Order Sliding Mode Controller.
Experimental Implementation of SEIG Based Wind Energy System Using Neural Network Controller
by Giribabu Dyanamina
Abstract: The paper presents a standalone self excited induction generator (SASEIG) based wind energy system (WES) connected with back to back power converter. It consists of a generator side converter (GSC) used to regulate variation of torque and flux, and load side converter (LSC) used to adjust variation of DC voltage. The indirect vector control (IVC) technique is employed to regulate the GSC and LSC separately. When a SASEIG operated at variable speed the voltage variation of controller is very critical. Therefore to enhance the voltage variation the proportional integral (PI) controller is replaced with NNC in indirect vector control of GSC. The proposed WES is simulated using MATLAB/SIMULINK software and is operated at variable speeds, to validate the proposed method experimentally the prototype model is developed and it is digitally implemented using DS-1104 R&D controller.
Keywords: Self Excited Induction Generator; Indirect Vector Control; Wind Energy System; Neural Network Controller.
Comparative Analysis of Unit Template, SRF and the Modified SRF Technique for DSTATCOM Based Distribution System
by Aaqib Ahmad Qureshi, Abdul Hamid Bhat
Abstract: This paper introduces a new hybrid control strategy called the Modified SRF theory which makes use of both SRF as well as unit template technique to generate the reference supply currents which are then compared with the sensed supply currents and fed to the hysteresis/PWM current controller to generate the necessary switching signals for switches of the VSC of the DSTATCOM for a three-phase three-wire system.. This proposed control algorithm is compared with the unit template or PI controller-based algorithm and the SRF theory to mitigate a variety of problems such as low power factor, voltage regulation, current unbalance and harmonics in the system. The proposed algorithm is proved better than conventional algorithms reported in the literature.
Keywords: DSTATCOM; control technique; power quality; unit template; SRF; Modified SRF; custom power device.
Short-Time Wind Power Prediction using Hybrid Kernel Extreme Learning Machine
by Sthita Prajna Mishra, Jyotirmayee Naik
Abstract: A hybrid short-time wind power forecasting technique based on Variational Mode Decomposition (VMD) and Kernel Extreme Learning Machine (KELM) is proposed in this paper. The non-stationary historical wind data is initially decomposed into various modes using VMD technique, which is subsequently passed through the proposed KELM (Gaussian and wavelet based) and conventional ELM (without weight optimization and with optimization (Chaotic firefly optimization algorithm(CFA)), respectively, in order to predict the thirty minutes and one hour ahead wind power, respectively. It is observed that, rather than optimizing the arbitrary input layer weights of VMD-ELM technique, the proposed Gaussian based EMD- KELM technique illustrates the most effective and accurate short-time wind power predictions for some diverse seasons. The overall results presented in the simulation (through MATLAB Simulation Platform) and result section are satisfactory and indicates the proposed Gaussian based EMD- KELM technique as a highly potential prediction technique for real time applications in power systems. The proposed model can be tested in the industry having wind generation or wind power plant where this can be applied in order to predict the future wind power to schedule the load profile in efficient manner. This can be also validated through wind test bench system.
Keywords: Variational Mode Decomposition; Kernel Extreme Learning Machine (KELM); Chaotic firefly optimization algorithm; wind power prediction.
An improved grid integration technique for SPV based CHB-MLI in distribution network
by Prabir Ranjan Kasari, Subhadeep Bhattacharjee
Abstract: The growing power electronics based nonlinear load increases harmonic contribution in the power system that leads to deterioration in the quality of power. The unbalance loading in three phase four wire (3P4W) system allows a neutral current flow which is an escalating concern for the utility. In this paper, the instantaneous power balance method is employed for Solar Photovoltaic (SPV) based nine-level Cascaded H-Bridge Multilevel Inverter (CHB-MLI). A modified instantaneous Power Balance Method (PBT) is proposed for integrating this SPV based CHB-MLI. The average and oscillating zero sequence power are incorporated in the proposed instantaneous power balance method to generate an appropriate reference for interfaced CHB-MLI. It is evident from the study that, the zero sequence components have a significant effect on an unbalance three phase four wire system, considered as a utility in this paper. The proposed controller provides CHB-MLI that feeds the average power of SPV and also supports the utility by supplying nonlinear, oscillating power. This SPV based CHB-MLI is called Solar Photovoltaic Shunt Active Power Filter (SPV-SAPF). Further, the modular structure of this CHB-MLI facilitates the integration of large energy using low rated converter components. FFT analysis done for different voltage levels of CHB-MLI shows that Total Harmonic Distortion (THD) is within a permissible limit. Besides, simulation, experimental results are also provided to validate the performance of the proposed scheme.
Keywords: Active and reactive power; cascaded H-bridge multilevel inverter (CHB-MLI); harmonics compensation; instantaneous power balance theory.
Versatile Current Controller Suitable for Two-Level As Well As Three-Level Converters of Shunt Active Power Filters: Part-I
by Siddharthsingh K. Chauhan, Dr. P. N. Tekwani
Abstract: Current control strategy adopted, dominantly governs performance of shunt active power filter (SAPF). A versatile current error space phasor based hysteresis controller for SAPF is presented. The controller keeps the current error space phasor within prescribed hexagon shaped boundary by selecting appropriate voltage vector of SAPF. Switching of optimal voltage vector is ensured unlike non-optomum selection in conventional hysteresis controllers used for SAPFs. Proposed SAPF generates compensating currents effectively by cocordinaing sector change overs and supply frequency. Two different schemes for sector change detection are presented. The concept is simulated, and digital signal processor (DSP) TMS320LF2407A is used to implement the proposed controller. Experimental results depicting steady state as well as transient performance of the controller are presented. Effect of variation in hysteresis band on performance of SAPF is also reported. Adequate compensation provided by the SAPF for harmonic mitigation is evident from simulation and experimental results. However, complex voltage space phasor structure of multi-level converter puts limitation on proposed controller to detect sector changes. Application of proposed controller to multi-level converter based SAPF requires development of a versatile controller. Such a controller having capability to identify sector change in multi-level converters using outer hysteresis band is described in Part-II of this paper.
Keywords: Current Error Space Phasor; Hexagonal Boundary; Multi-Level Converter; Sector Change Detection; Shunt Active Power Filters; Versatile Hysteresis Current Controller.
Model Reference Adaptive System Based Precise Online Inertia Identification of Induction Motor with Error Utilization Technique
by Jay D. Mistry, Dr. P. N. Tekwani, Chirag Raval, Vinod Patel
Abstract: Time varying parameters can be estimated using either adaptive control or robust control. Robust control can be used only when the control law is fixed and varying parameters are bounded. Adaptive control is concerned with control law changing itself. Model Reference Adaptive System (MRAS) is an adaptive control method that can be used to identify initially unknown parameters. Variation in load and machine vibrations affect the control system performance of any motor drive system when it is in operating condition. Estimation of moment of inertia becomes essential to improve the dynamic response characteristics of any high-performance Asynchronous Machine (ASM) drive system. A novel method using Model Reference Adaptive System (MRAS) with Error Utilization Technique (EUT) for precise identification of online varying inertia is presented in this article. The proposed method uses an interesting relation between the estimation error and actual inertia, to compensate for the error and provide high precision online inertia identification.
Keywords: Asynchronous Machine (ASM); Model Reference Adaptive System (MRAS); Error Utilization Technique (EUT); Inertia Identification.
Versatile Current Controller Suitable for Two-Level As Well As Three-Level Converters of Shunt Active Power Filters: Part-II
by Siddharthsingh K. Chauhan, Dr. P. N. Tekwani
Abstract: Current controller presented in Part-I of this paper suffers from limitation in sector change detection for multi-level converter based power filters because of inherent complex voltage space phasor structure. A self-adaptive current error space phasor based hysteresis controller is presented that does not require calculation of voltage vector at point of common coupling for identifying sector changes. It requires one more hysteresis band placed little outside the main hysteresis band used for selection of voltage vectors. Sector change detection is executed only from the movement of current error space phasor and state of comparators on outer band. This versatile technique of sector change detection is equally applicable for two-level as well as three-level converter based power filter. Feature of adjacent voltage vectors switching is retained in the presented controller. Inherent problem of capacitor voltage imbalance is eliminated by effective use of switching state redundancy of three-level flying capacitor converter employed for power filter. Performance of controller is verified for two-level and three-level filter through thorough simulation studies. The controller is then implemented using DSP TMS320LF2407A for two-level filter. Adequate compensation provided by the controller in steady state, during transients and for variation in hysteresis band is evident through presented results.
Keywords: Current Error Space Phasor; Flying Capacitor Type Three-Level Converter; Self-Adaptive Sector Change Detection Technique; Shunt Active Power Filters; Two Hexagonal Boundaries; Versatile Hysteresis Current Controller.
An MRAS based Smoothed Kalman Observer for Speed Sensorless Indirect Vector Controlled Induction Motor Drives
by Uma Syamkumar, Jayanand B.
Abstract: This paper proposes a modified Kalman filter algorithm based on fixed-lag smoothing which can be used to estimate the rotor speed and flux of three phase induction motor. The behavior of a typical extended Kalman filter(EKF) algorithm is influenced by the process and measurement error covariance matrices. In EKF, these matrices are chosen by trial and error method and have to be varied according to the varying operating conditions of the motor. In this paper a smoothing based extended Kalman filter(SKF) algorithm which uses additional data points for estimation is proposed. Since additional data is used, the algorithm is able to give a better estimate, for same values of covariance matrices. The performance of the proposed algorithm is explored for sensorless indirect vector control application of three-phase induction motor. Finally, in order to validate the superiority of this algorithm, it is compared with the performance of EKF algorithm for various reference speeds in real-time. rnrnrn
Keywords: Sensorless Control; Smoothing; Observer; Extended Kalman filter; Three-phase induction motor.
Exploration of Bifurcation and Inherent Oscillation in a Current
Mode Controlled Cuk Converter - Effects of Turn-On and
Turn-Off Switching Delays
by Sukanya Parui, B. Basak
Abstract: The nonlinear phenomena in a dc-dc current mode controlled C'uk converter circuit has been explored. In reality, as any switching process is associated with turn-on and turn- off delays, the simulation has been extended considering these delays. The circuit exhibits a LC oscillation which may make the switch current oscillatory and in some cases the conclusion obtained from the bifurcation diagram regarding the dynamics of the system becomes incorrect. A mathematical expression for the oscillation frequency has been presented. A prototype ofrnthe converter has been developed. The simulated results have been verified experimentally.
Keywords: Bifurcation; Chaos; C'uk Converter; Oscillation.
SVM based Current Ripple Reduction with Two Parallel Interleaved Inverters for Induction Motor Drive
by RANVIR KAUR, Gursewak Singh Brar, Maninder Kaur
Abstract: Extensive research has been ongoing in the field of inverter fed induction motor drives. The main challenge in designing Pulse Width Modulation (PWM) fed induction motor drives is to reduce Total Harmonic Distortion (THD) and ripple content in ac output of inverter. The PWM method ensures the voltage balancing between two Parallel Interleaved Inverter (PII) inverters for each switching cycle. The PII includes two parallel units of two level three-phase PWM full bridge having multiple carrier waves with phase rotation analysed as single unit of three level inverter. PII improves the performance of drive while employing Space Vector Modulation (SVM) by reducing THD content by 14% for low modulation indices and improves up to 40% at high modulation indices. Ripple content is significantly reduced in line current for PII. Simulation and experimental results for PII for 5 hp induction motor are presented in this paper to validate low ripple current at output.
Keywords: PWM; three phase full bridge; SVM; parallel inverters; ripple content; induction motor.
New Approach of SOC Estimation Method for lithium-ion battery/Ultra-capacity Hybrid system Based on Multi-Model Strategy
by Qiuting Wang, We Qi
Abstract: The model precision of the lithium-ion battery and the computational complexity of state estimation procedure will not be satisfied at the same time. A new State of Charge(SOC) estimation method based on multi-model strategy (MMS) is proposed to ensure both the estimation accuracy and the real-time performance. Meanwhile, new modelling method and SOC estimation method for the battery energy storage system are presented. The main efforts of our work are, firstly, the hybrid system model is established based on multi-model strategy. Secondly, the model parameters are updated using extended Kalman filter(EKF) algorithm. Thirdly, the electric quantity of lithium-ion battery is estimated using Unscented Kalman filter(UKF) algorithm. The experiments were conducted under dynamic working condition and the NEDC working condition. The results indicate that the SOC estimation accuracy based on MMS is better than that without the strategy.
Keywords: lithium-ion battery; SOC estimation; multi-model strategy; Joint Kalman filtering algorithm; NEDC.
Phase locked loop Parameterization in AC/DC Interconnected System for a multi-source AGC system under Open market Environment
by Debdeep Saha, Lalit Chandra Saikia
Abstract: This article emphasizes on deregulated AGC of a realistic multi-machine gas thermal plant with dish-Stirling solar-thermal (DSTS) as additional power generation sources in each control Area by taking into accounts of AC/DC with phase locked loop dynamics (PLL). Eigenvalue analysis confirms the steadiness of the reasonable power system with various interconnections such as AC, AC/DC link and AC/DC with PLL dynamics. A series form of proportional-integral-derivative (PID) namely proportional gain cascaded with integral and double-derivative (PI+DD+) controller is employed as secondary controller in each control areas for robust AGC to carry out market transactions under deregulated environment. Exploring the system with different type of interconnections infer that proper tuning of PLL function parameters may synchronize the grid better than without employing PLL. The performance of PI+DD+ controller along with optimum PLL gains commensurate with wide variations in governor, turbine, fuel and compressor discharge time constant of gas turbine plant.
Keywords: Automatic generation control ; dish-Stirling solar thermal ; deregulated ; Eigen value; phase locked loop; series controller.
Development and Implementation of a Voltage Harmonic Elimination Method for the Single-Phase Inverter Operating with Nonlinear Load
by Bogdan Proca, Mihai Comanescu
Abstract: Single-phase inverters are widely used in power conversion systems. When operating with linear loads, these inverters produce regulated output voltages that are quasi-sinusoidal. However, when feeding nonlinear loads, these absorb currents that are non-sinusoidal (distorted) and the inverters output voltage deteriorates it contains high levels of harmonics. This paper presents a control method that reduces the harmonic content of the output voltage and improves the total harmonic distortion (THD). The control strategy is based on selective harmonic elimination the method eliminates some of the low order harmonics of the output voltage using feedback. The proposed method reduces the distortion in the output voltage and improves the voltage THD. The method uses a voltage controller followed by a current controller both are implemented in the stationary reference frame. The voltage controller regulates the fundamental and eliminates certain harmonics using a modulation-demodulation technique. In the paper, the 3rd, 5th and 7th harmonics are eliminated. However, the scheme can be expanded to eliminate more higher-order harmonics. It is shown that the control proposed significantly reduces the Total Harmonic Distortion (THD) of the inverters output voltage, from 5.8% (at full load, uncompensated) to 1.64% (at full load, with compensation). The method proposed is directly applicable for industrial single-phase inverters and is validated by simulations and experimental tests.
Keywords: single-phase inverter; total harmonic distortion; harmonic elimination; sliding mode current control.
Performance Investigation of a Transistor Clamped H-Bridge Inverter Based Dynamic Voltage Restorer for Mitigating Various Power Quality Problems.
by Humeera Altaf, Abdul Hamid Bhat
Abstract: This paper presents design and analysis of dynamic voltage restorer (DVR) employing five-level Transistor Clamped H-Bridge (TCHB) inverter that increases the applicability of DVR to medium voltage networks. TCHB inverter is a newly developed topology of multilevel inverters (MLIs) which uses lesser number of components as compared to other topologies. Synchronous Reference Frame Theory (SRFT) based control algorithm is used for implementation of proposed DVR. The compensation capability of proposed DVR is tested for various voltage related power quality problems like sag, swell, harmonics, imbalance and their combinations through MATLAB/Simulink software and the simulation results are verified experimentally by using Digital Real Time Simulator.
Keywords: Dynamic Voltage Restorer (DVR); Multilevel inverter (MLI);Transistor Clamped H-Bridge inverter (TCHB); Medium voltage application; Power quality problems.
A Novel Hybrid Discontinuous PWM Algorithm for 3L-NPC Inverter
by Li-ping ZHONG
Abstract: Wider linear modulation range, less switching loss and simplicity are the goals pursued by various modulation methods of multilevel inverters. This paper proposes a new hybrid discontinuous pulsewidth modulation (HDPWM) strategy for 3L-NPC inverter that can achieve the above goals to a certain extent. According to the position of the reference voltage vector and the actual situation of the neutral point voltage, different control modes and clamping types are selected. The neutral point voltage is controlled by DPWM strategy, which can not only greatly reduce the switch loss, but also maintain the balance of the neutral point voltage and expand the linear modulation range. The implementation of the algorithm combines the advantages of carrier-based PWM (CBPWM) and space vector PWM (SVPWM). There is no need to select the nearest three vectors (NTV) and calculate their dwell time. Only the reference voltage needs to be modified according to the control requirements, and then by comparing the modified reference voltage with the carrier, the driver pulse required by the switching devices can be generated. Compared with the existing PWM methods, it is more simple and easy to implement. Experimental results results verify the validity of the method.
Keywords: Hybrid discontinuous pulsewidth modulation; space vector pulsewidth modulation; clamping type; neutral point voltage balancing; output level sequency type.
Optimum Regulation of THD Profile in Multilevel Inverter Using Parameter-less AI Technique for Electrical Vehicle Application
by KAUSHAL BHATT, Sandeep Chakravorty
Abstract: This article proposes investigation on harmonic profile improvement using a novel fitness function in the multi phase multilevel inverter. For the proposed study in this paper, three-phase, seven-level cascaded H-bridge (CHB) multilevel inverter (MLI) is considered. Modulation of the stepped waveform output of the MLI is done using selective harmonic elimination (SHE) method. Many algorithms are proposed for solving the set of nonlinear transcendental trigonometric equations for SHE methods. Teaching learning based optimization (TLBO) algorithm is a parameter less optimization technique. Due to the lack of controlling parameters, the proposed algorithm is most robust among the family of artificial intelligence (AI) techniques. In this paper, an investigation is carried out on a novel fitness function proposed for controlling total harmonic distortion (THD) for the proposed inverter. It is observed that the proposed fitness function improves THD profile below IEEE standards. It is also observed that THD profile obtained through this method is far better than THD profile obtained through various proposed methods so far. The results of THD profile from the MATLAB Simulink simulations are verified experimentally using 7-level 3-phase hardware controlled by Arduino MEGA 2560 low cost controller.
Keywords: Multilevel inverter; artificial intelligent algorithm; teaching learning based optimization technique; selective harmonic elimination; total harmonic distortion.
BSA Based Analysis of Three-Phase Standalone Asynchronous Generator Using Two-Port Network
by Sambaran Ray, Himadri S. Chatterjee, Dipanjan Samajpati, Sankar N. Mahato, Nirmal K. Roy
Abstract: This paper presents the analysis of steady-state behavior of a three-phase standalone asynchronous generator (SAG) supplying three-phase load based on binary search algorithm (BSA). The concept of two-port network is used to model the generator system along with the load. Two model equations developed from the modeling of SAG are solved by BSA to get the frequency (a) and magnetizing reactance (Xm). The performance equations are formed with the help of frequency, magnetizing reactance and magnetizing characteristics of the machine to understand the steady-state behavior of SAG. The waveforms of generated voltages and currents in the generator are also investigated and their corresponding harmonic contents are recorded. The simulated results are verified through the experimentation and it shows that the experimental results closely agree with the simulated results. The BSA based analysis of three-phase SAG is easier, more efficient and accurate.
Keywords: Binary search algorithm; self-excited induction generator; standalone asynchronous generator; steady-state performance; two-port network; waveform.
Advanced Predictive Flux Control For B6 Inverter Fed Induction Motor Drives
by Wiem ZOUARI, Imen NOUIRA, Bassem EL BADSI
Abstract: Predictive torque control (PTC) strategy has already been introduced to cope with the problem of the torque and flux ripples of AC machines. However, the simultaneous control of the electromagnetic torque and the stator flux magnitude in conventional PTC scheme is not very trivial. Alternatively, the predictive flux control (PFC) strategy has been suggested based on removing the weighting factor from the implementation scheme. This paper proposes the development of two new phase-clamping (PC) PFC schemes, founded on the basis of modulating two legs of the two-level inverter fed induction motor (IM). Both PC-PFC strategies allow the clamping of one stator phase to the positive or negative terminals of the dc-bus voltage during each 60
Keywords: Predictive Flux Control; Induction Motor; Phase-Clamping; Duty-Cycle Optimization; Switching Frequency; Harmonic Distortion; flux and Torque ripple.
Design, Implementation and Performance Evaluation of Different Digital Control Techniques for Current Controlled DC-DC Buck Converter
by Dipen M. Vachhani, Rajesh Arya, Uma Rathore Bhatt
Abstract: The paper presents modelling, control architecture, analysis and design of digital compensators for single feedback-loop voltage mode control as well as two feedback-loop average current mode control and peak current mode control of current controlled DC-DC Buck converter operating in continuous conduction mode with output current as control variable. The compensators are derived using digital redesign approach, simulated on MATLAB, implemented as control algorithms on Texas Instruments 32-bit TMS320F28069M microcontroller platform, and experimentally validated by testing with a laboratory prototype of current controlled Buck converter. Simulation and experimental results are discussed, compared and evaluated for converter output current performance in tracking reference current signal as well as in regulation against input voltage and load disturbances. Salient features of each control technique are identified and described to determine its suitability in applications of DC-DC converters requiring controlled output current.
Keywords: Digital control techniques; digital voltage mode control; digital average current mode control; digital peak current mode control; current controlled DC-DC Buck converter; continuous conduction mode; digital redesign; digital compensators; type-2 compensator; 2p2z compensator.
Advanced sensorless nonlinear control strategy for grid-connected photovoltaic systems via the two-time scale singular perturbation technique
by Youssef MCHAOUAR, Abdelmajid ABOULOIFA, Aicha EL ALLALI, Ibtissam Lachkar, Josep M. Guerrero, Chaimaa Taghzaoui
Abstract: This paper presents a new control strategy for grid connected photovoltaic (PV) system. The system consists of a solar panel, a boost power converter, and a full-bridge inverter with filter inductor connected to the grid. The control objectives are threefold: i) tracking the maximum power point (MPPT) of the PV panel; ii) regulating the DC-link voltage to a given reference to ensure the power transferring from the PV panel to the grid; iii) ensuring a unity power factor in the grid such as the currents injected must be sinusoidal with the same frequency and the same phase as the grid voltage. To achieve these control objectives, a multi-loop controller is synthesised using a high-gain output feedback controller and the two-time- scales singular perturbation technique. The addressed control problem involves several difficulties including the nonlinear characteristic of the PV, the nonlinear dynamics of the converters, and the existence of a number of state variables that are inaccessible to measurement. To address this problem, two-time-scale sliding mode observers are added which allow estimating, simultaneously, the solar panel current and the grid voltage. To show that all control objectives are asymptotically accomplished, a formal analysis based on the singular perturbation method and the average theory is carried out. This theoretical result is confirmed by simulations under MATLAB Simulink illustrating the performances and the strong robustness with respect to climate changes.
Keywords: Photovoltaic system; singular perturbation technique; two-time scales sliding mode observer; nonlinear control; averaging theory.
Performance Investigation of Transformer-less DSTATCOM in Grid-connected Solar-PV Distributed Generation System with Insolation Variation
by Meenakshi Rastogi, Aijaz Ahmad, Abdul Hamid Bhat
Abstract: This paper addresses the application of DSTATCOM in a grid-connected solar PV distributed generation system when the insolation variation takes place. The solar-PV panel is connected to the grid at a point of common coupling to supply real power to the load and surplus real power to the grid at light loading conditions. When DSTATCOM is integrated with a grid-connected solar-PV system, it injects reactive power with real power simultaneously and contributes to the mitigation of power quality problems which is created by the solar-PV system or different loading conditions. DSTATCOM also results in power factor correction and zero voltage regulation of the distribution system. The solar-PV output power has fluctuations and its waveform carries harmonics with it. DSTATCOM also contributes to maintaining the power system stability, which may get deteriorated by the solar system as the solar-PV system is unstable. DSTATCOM maintains the DC-link voltage constant and helps the solar-PV system to work smoothly. In this paper, the simulation model of a 3-phase 3-wire Distributed Generation System based on Synchronous Reference Frame (SRF) control strategy has been designed to demonstrate the performance evaluation of DSTATCOM in a solar-PV distributed generation system with variation in solar insolation. The simulation model has been designed in MATLAB/Simulink and SimPowerSystems software. Various simulation results have been presented. The digital real-time simulator has also been used and the real-time experimental results have been presented to validate the correctness and effectiveness of the proposed system and its control.
Keywords: Digital Real-time simulation; Distribution Static Synchronous Compensator (DSTATCOM); Sinusoidal Pulse Width Modulation (SPWM); Synchronous Reference Frame (SRF) theory; Solar-PV panel; Distributed Generation System; Power Factor Correction (PFC); Zero voltage Regulation (ZVR); Solar Insolation.
New High Voltage Gain Using D-C Cell Suitable for PV Applications
by Arezu Azizi, Arash Kalami
Abstract: In this paper, a non-isolated DC-DC boost converter with high voltage gain and low voltage stress across semiconductors is presented suitable for PV applications. The proposed converter used voltage multiplier techniques Diode/Capacitor (D-C) for increasing the output voltage level. The main advantages of the proposed converter include low input current ripples, low voltage stress across semiconductor (power switch and power diodes), high overall efficiency and low conduction losses. Moreover, the proposed converter capable to achieve the maximum power by controlling the duty cycle values. The laboratory prototype of the proposed converter is built and tested at 33kHz with about 155W power level. Both simulation and experimental results confirm the validity theoretical of the proposed converter.
Keywords: DC-DC non-isolated converter; high voltage gain; voltage stress; Renewable applications; maximum power point tracking.
Modulation Technique Based on Low Computational SVPWM for Reduced Switch Multilevel Inverter Hardware Implementation
by Jose Jacob, Sarin MV, Chitra A., RaziaSultana W
Abstract: This work envisages promoting an experimental analysis of a reduced switch asymmetrical multilevel topology when controlled with different modulation schemes. For Investigation, two modulation schemes are used, i.e (a) SPWM Sinusoidal Pulse Width Modulation and (b) SVPWM- Space Vector Pulse Width Modulation techniques. The algorithm proposed here is a general one, which can be applied to any N- level inverters without much complexity as compared with standard space vector techniques. The output of Multilevel Inverter (MLI) is evaluated by the presence of Total Harmonic Distortion (THD) for available modulation techniques. A seven-level output voltage has been generated by the proposed topology. Complete modeling by the numerical equation is done with MATLAB/Simulink tool. To give proof of the numerical results, an experimental setup has been implemented using dSPACE 1104. The effectiveness of the proposed space vector algorithm over SPWM technique is shown experimentally. The experimental verification reveals that the low computational SVPWM outperforms the conventional schemes.
Keywords: Power converters (DC-AC);PWM inverters;SVPWM;power MOSFET;inverters;.
A H?-based approach for sensorless control of BLDC motors fed with four-switch inverters
by Nouha Triki, Mohamed Abbes, Souad Chebbi
Abstract: BLDC motors are fast and robust synchronous machines and, therefore, they can be suitable for many high-end applications. This paper presents the design and the implementation of a cost-effective sensorless control strategy for brushless DC motors fed with a four-switch inverter. The proposed control technique simplifies the hardware implementation of such drive system since only two current sensors are used to achieve accurate estimation of the rotor position. It can be used whether the neutral point of the stator is accessible or not. In this method, a H?-controller was designed to control phase currents. A disturbance observer is used to estimate the back-EMFs of the rotor. These variables was used as the inputs of a phase locked loop to estimate the rotor position. The performances of this system were validated through simulation results. It was shown that the rotor speed remains close to the desired reference and the estimated angle is synchronized with the actual back-EMF. Compared with existing solutions, the proposed method allows the limitation of switching losses by the removal of the hysteresis controllers and the possibility to use standard driver circuits with internally set deadtime. Finally, an experimental prototype was built to verify the correctness of the presented control method.
Keywords: BLDC motor; four-Switch inverter; H? control; disturbance observer; Sensorless control.
Harmonic/Inter-harmonics Detection using Modified Exact Model Order based ESPRIT
by Ankit Srivastava, A.N. Tiwari, S.N. Singh, Praveen P. Singh
Abstract: Problems related to harmonics/interharmonics are growing in power system rapidly with the increasing use of power electronic devices. This paper focuses on estimating harmonics/interharmonics using MEMO-ESPRIT (Modified Exact Model Order Estimation of Signal Parameters via Rotational Invariance Technique). The modified EMO method is used to reduce the computational burden in detecting the harmonics/interharmonics components. The EMO estimation performs the calculation of the relative difference of every eigenvalue while modified-EMO utilizes the fact that two consecutive eigenvalues belong to the same frequency components and therefore, it removes those points and takes their average for RD calculation. Comparison has been made between EMO (Exact Model Order) and MEMO to demonstrate the effectiveness of MEMO. Moreover, various parameters values like noise, size of autocorrelation matrix, etc. are varied to see their effect on the computational burden and accuracy of the MEMO method. Performance of the MEMO-ESPRIT algorithm is analyzed with synthetic signals, single-phase PWM inverter and 250- kW grid-connected PV arrays using MATLAB/Simulink. The root-mean-square relative error has been obtained to validate the accuracy of the algorithm.
Keywords: Harmonics/interharmonics estimation; MEMO; FFT; ESPRIT.
Modelling, Analysis & Control of Bidirectional SEPIC Converter for Energy Storage Applications
by Arnab Ghosh, Jayadev Meher, Subrata Banerjee
Abstract: Energy storage system appears to be very promising field of research for rapidly increased requirements of applications renewable sources in daily life. The DC-DC bidirectional converters (BDCs) are globally known for its versatile applications in battery chargers, electric vehicles (EVs), solar PV modules with energy storage systems, smart/ microgrid, telecommunication systems etc. Such demanding applications are mostly essential for suitable bidirectional converters for delivering the energy both the directions. In this work, the closed-loop analysis, modelling and control of a DC-DC bidirectional SEPIC converter with classical controllers (like as proportional integral derivative (PID) controller, Type-II controller & Type-III controller) and advanced controller (such as Internal Model Controller (IMC)) are demonstrated. The bidirectional SEPIC converter has been modelled here by using state-space averaging (SSA) method. It is noticed that bidirectional converter with IMC shows better controlling action compared to other classical control algorithms for its better steady-state and transient responses. Finally, experimental verification of proposed closed-loop converter control is performed.
Keywords: Bidirectional SEPIC Converter; Small Signal Analysis; Classical Controllers; Advanced Controller; Energy Storage System;.
Single Phase Cross Connected Sources Asymmetric T-Type Multilevel Inverter with Fault Tolerant Capabilities
by Vinay Kumar, Sanjeev Singh, Shailendra Jain
Abstract: This work presents a cross connected sources asymmetric T-type multilevel inverter (CCSATT-MLI) for single phase operation with fault tolerant (FT) capabilities. The presented topology uses only one extra power semiconductor switch in the CCSATT thirteen-level (13L) inverter for fully FT operation. The paper uses two control schemes namely phase opposition disposition sinusoidal pulse width modulation (POD-SPWM) and nearest level control (NLC) for achievement of desired results under single switch open circuit (SSOC) fault. The obtained simulation results of proposed topology using MATLAB/Simulink are presented to show FT operation of the MLI under any SSOC fault. The simulation validation are validated under each switch fault using OpalRT hardware in loop (HIL) platform. The presented topology is also compared with recently reported MLI topologies for reduced number of count claim and effective FT operation in symmetric as well as asymmetric configurations.
Keywords: Asymmetric T-type; cross connected source; fault tolerant; multilevel inverter; Nearest level Control; Pulse width Modulation; Single switch open circuit; Total Harmonic Distortion.
Coordinated control of wind farm and supercapacitor energy storage system for dynamic performance reinforcement of multi-area power systems
by Asima Syed, Mairaj Ud-Din Mufti
Abstract: In this paper, a simple and effective control approach to exploit the primary frequency support competency of doubly fed induction generator (DFIG)-based wind turbines (WT) is presented. Furthermore, a small rating supercapacitor energy storage system (SCESS) is also integrated to reinforce the frequency regulation in the studied multi-area power system. A control-oriented strategy is employed to develop a discrete-time predictive control (DPC) for SCESS. The dynamic energy level thresholds are generated by representing the SCESS primary control by a first-order lag block for obtaining a discrete-time state-space model which yields the modified power constraints. Furthermore, the power thresholds of the power conditioning system (PCS) are chosen meticulously. The uprightness of the proposed scheme is manifested by the time-domain simulation results exhibiting considerable damping of the power system oscillations along with substantial curtailment in frequency nadir, with all the power and energy constraints of SCESS accounted for. The eigenvalue analysis is also carried out to validate the MATLAB/Simulink-based simulation results.
Keywords: doubly fed induction generator; frequency support; discrete-time predictive control; supercapacitor energy storage.
Performance evaluation of a standalone hybrid microgrid for a rural community using various dispatch strategies
by Vijay Garg, Sudhir Sharma
Abstract: Distributed energy sources prove to be a viable alternative for electricity in rural/remote areas. In this paper, the performance of a standalone hybrid microgrid comprising of solar photovoltaic (PV), diesel generator (DG), and battery energy storage system (BESS) has been evaluated for a small rural community. The overall aim is to propose sustainable, economical and reliable electricity supply in rural/remote areas. The optimum sizing of various units has been evaluated using hybrid optimisations multiple energy resources (HOMER) simulations with four dispatch strategies, i.e., load following, cycle charging, combine dispatch, and predictive dispatch. The outcomes show that the PV-DG-BESS system is an optimal solution based on net present cost (NPC) and cost of energy (COE) parameters under a predictive dispatch strategy. The sustainability of the optimum hybrid microgrid has been evaluated using sensitivity analysis using various input parameters.
Keywords: hybrid microgrid; solar photovoltaic; hybrid renewable energy sources; dispatch strategies; sensitivity analysis; cost of energy; COE; battery energy storage system; BESS.
Special Issue on: Smart Computational Intelligence-based Intelligent Control of Power Electronics Devices and its Application in Smartgrids
A Modified Type-2 Neuro-fuzzy SVM based inverter fed IM drive
by G. Srinivas, G. Durga Sukumar
Abstract: In indirect vector control, the conventional speed and current controllers operate satisfactorily when the operating point is constant. But the operating point is always dynamic, the reference voltages obtained in a closed-loop system feeding to the inverter contains more harmonics. Due to this, the pulses which are going to produce are uneven. Which intern produces the inverter output voltages which are more harmonics contained. In order to produce a better output voltage from the inverter, this paper presents the neuro-fuzzy type-2 space vector modulation (NFT2) technique. Performance comparison of the inverter is done with conventional space vector modulation(SVM) and neuro-fuzzy type- 1(NFT1) system using MatLab simulation & experimental validation. The performance parameters of the induction motor based on current, torque, and speed with neuro-fuzzy type-2 space vector modulation is compared with conventional and type-1neuro fuzzy SVM. The % THD of inverter output voltages are also compared. The experimental validation of a DSpace-1104 is used to analyze the performance of the induction motor which is obtained by the simulation. The experimental validations are carried out considering 2HP Induction motor in the lab.
Keywords: indirect vector control; Neuro-Fuzzy type-2 controller (NFT2); Neuro-Fuzzy type-1 Controller (NFT1); Space vector modulation (SVM); Induction motor (IM); Third harmonic distortion (THD).
Genetic Algorithm and Anti-predatory Swarm Optimization-based Solutions for Selective Harmonic Elimination in Multilevel Inverters
by YATINDRA GOPAL, Kaibalya Panda, Dinesh Birla
Abstract: The elimination of harmonics and need of a large number of switches in multilevel inverters (MLIs) have been the focus of research from the last few decades. In this paper work using genetic algorithm (GA) and anti-predatory particle swarm optimization (APSO) is described to minimize harmonics in MLIs, which is a complex optimization problem involving non-linear transcendental equation. Switching angles are calculated for different modulation indices by proposed algorithms considering minimum THD and best optimum results are taken for controlling the operation of MLIs. MATLAB/SIMULINK software is used for simulation of two topology i.e. 7-level cascaded H- cascaded H-bridge multilevel inverter (CHB MLI) and a 7-level reduced switch multilevel inverter (RS MLI) with an equal number of DC sources. Theoretical results are verified by developing a prototype of both the MLIs and are compared. FFT analysis shows that used structure effectively eliminates specific lower order harmonics and obtained output voltage contains low THD with reduced number of switches thereby reducing the switching loss to a great extent.
Keywords: Anti-predatory PSO; Multilevel inverter; Cascaded H-bridge multilevel inverter; Genetic algorithm; Reduced switch multilevel inverter; Selected harmonic elimination; Total harmonic distortion; Modulation index.
Battery and Super Capacitor Powered Energy Management Scheme for EV/HEV using Fuzzy Logic Controller and PID Controller
by Nitesh Tiwari, Shekhar Yadav, Sabha Raj Arya
Abstract: The main aim of this paper is to propose a scheme for the internal and external energy management of the EV/HEV and try to analyse the performance of the EV/HEV in terms of speed tracking and output power. This paper is focused on to achieve the maximum efficiency with the minimum cost so their proposed different types of the DC-DC converter with their different controlled technique. Due to the analysis purpose, there are using PID and FLC controlled technique for designing the motor driver. Here a parallel connection of supercapacitor (followed by BBBC) and battery bank (followed by UBBC) is proposed for reducing the stress on the battery bank and getting the optimized energy at every point. Now Simulink software named MATLAB and Simulink is used for verifying our results.
Keywords: Electric vehicle (EV); hybrid electric vehicle (HEV); unidirectional buck-boost converter (UBBC); bidirectional buck-boost converter (BBBC); proportional integral derivative (PID); the fuzzy logic controller (FLC); battery; supercapacitor (SC).
Application of Artificial Intelligence techniques in the operation of Neutral-Point Clamped Rectifier under Perturbed Conditions
by Deepak Sharma
Abstract: This paper will demonstrate the viability of Neural Network algorithm for solving power quality rnproblems in three- phase Neutral-Point Clamped Converter. A neural network algorithm is proposed here for the better performance of the Converter under perturbed conditions. The neural network algorithm modifies conventional space vector pulse width modulation algorithm. The proposed algorithm generates ideal switching sequences for the converter by developing best path for the reference vector in the hexagon of the space vector. The data set required to train the neural network was collected from well tuned PI controlled model. In this work, the implementation of neural network is described and simulation results are presented using MATLAB/Simulink software. Simulation results proves fast minimizing the potential difference at the clamped bus of the converter with minimum switching losses and excellent performance of converter in terms of unity power factor, better total harmonic distortion at the source side.
Keywords: Neural Network (NN); Back Propagation Neural Network (BPN); Modified Space Vector Pulse Width Modulation; Neutral-Point Clamped Converter (NPC); Minimizing Potential Difference ; Harmonics eliminations.
Performance assessment of PV integrated Model Predictive Controller based hybrid filter for Power Quality Improvement
by Soumya Ranjan Das, Prakash K. Ray, Debani P. Mishra, Himansu Das
Abstract: The role of predictive controller in recent days is found to be vital in controlling the voltage source inverter (VSI) of the active power filters (APF). It is realized that, the improvement of power quality (PQ) in the utility network using non-linear loads, with integration of renewable sources, has become an open challenge to the researchers. This paper proposes an integration of Photovoltaic (PV) system with three phase power distribution system using series hybrid filter (SEHF). The objective of the paper is to reduce the harmonic components and dc link control of VSI for improving the PQ and simultaneously provide uninterrupted supply to the load by compensating the reactive power. In this work, the Fuzzy Logic Controller (FLC) is employed for maximum power point tracking (MPPT) in PV system and a model predictive controller with robust extended complex Kalman filter (MPC-RECKF) technique is applied for calculating the fundamental components from distorted value in SEHF. The results obtained using the proposed MPC-RECKF is compared and analysed with traditional controllers in MATLAB/SIMULINK environment.
Keywords: Model predictive control; Photovoltaic array; robust extended complex Kalman filter; Series hybrid filters.
Virtual Inertia Support in the microgrid, its research challenges and its technology potentials in recent years
by Neethu Elizabeth Michael, Shazia Hasan
Abstract: This paper epitomizes the various aspects of virtual inertia using energy storage systems for satisfactory regulation against uncertain frequency and voltage fluctuations. Since the power system switches from a generator-dominated system to an inverter-dominated system it results in the culmination of lack of inertia due to the massive penetration of renewable energy resources. This eventually leads to problems of frequency stability and power quality. The principle of virtual inertia, which emulates the operation of the synchronous generator by providing the power system with inertia remotely, was a topic of research from 2007 and is now gaining recognition. Software simulations and hardware implementation will open the way for a thorough investigation of the technology in the future. Furthermore, it also addresses the different types of virtual inertia topologies, application with renewable energy sources, evaluation for ancillary services, potential opportunities, risks posed, and future research directions.
Keywords: virtual inertia; renewable energy sources; frequency stability; microgrid; energy storage systems; power quality.
Implementation of Energy Management in Hybrid Renewable Energy Island Systems using Soft Computing Techniques
by Srishti , Prerna Gaur
Abstract: Microgrid based EMS (Energy Management System) is designed and implemented in this paper to manage the energy balance between renewable resources and the load i.e. supply-demand balance of energy. Wind energy generation is done through PMSG using the method of vector control of synchronous generator. Further, the investigation of modelling and control of SOC (State of Charge)-Based BMS (Battery Management System) in microgrid for autonomous/islanding mode is presented in the form of aggregated battery model. Since BMS is critical in maintaining the optimum performance of battery and hence, a battery system has been designed in present work. The results of the comparative study of the proposed MPPT techniques i.e. CSA, ANN, FLC with conventional P&O using MATLAB/SIMULINK in terms of accuracy, electric power efficiency, duty cycle, D.C. link voltages, load power of proposed techniques are presented in the present work. The working of the proposed EMS for hybrid PV-Wind-Battery system is verified through simulation results using various control algorithms.
Keywords: MPPT; PES; WECS; BMS; EMS.
Analysis of Tilt Integral Derivative Controller Based Automatic Load Frequency Control of Multi-Area Multi-Source System
by Manmadha Kumar Boddepalli, Prema Kumar Navuri
Abstract: In this paper, a new tilt integral derivative (TID) controller is implemented for a multi-area multi-source power system. The parameters of the TID controller are optimized using a firefly algorithm (FA) and it is employed with integral time multiplied absolute error (ITAE) as an objective function. Initially, three area nine-unit power system is designed in MATLAB/SIMULINK environment. The superiority of the proposed controller is established by comparing simulation results ZieglerNichols (ZN) based PID and FA based PID controllers for the same designed model. The simulation results reveal that frequency responses and tie-line power deviations are enhanced with FA based TID when compared to ZN and FA based PID controller. Finally, the effectiveness of the proposed controller is examined by doing robust analysis under varied system parameters.
Keywords: Ziegler–Nichols (ZN) method; Firefly Algorithm (FA); Tilt Integral Derivative (TID) controller; Integral Time multiplied Absolute Error (ITAE).