Reference Source Currents Research Articles

Power Quality Improvement of PV fed Grid Connected System using ANN Controlled Shunt Active Power Filter

Harmonics are common in integrated power systems, especially with the increasing use of nonlinear loads (NLL), such as those found in photo voltaic (PV) systems connected to the grid. Traditional LC filters Shunt active power filters (SAPF) have been developed to effectively correct harmonics and improve power quality performance. This study presents a three-phase voltage-fed SAPF implementation to mitigate harmonics using an artificial neural network (ANN) controller. The SAPF control system focuses on generating reference source currents to counterbalance the harmonic effects caused by NLL. The model's effectiveness is validated using experimental data gathered from a nonlinear load through MATLAB/Simulink simulations.

Design of Voltage–Current Reference Source in CMOS Technology

A design methodology for a resistorless low-power two-in-one voltage and current reference source working in subthreshold and moderate regions is described. The presented novel universal reference voltage–current source was implemented in ten different designs for seven different CMOS technologies. Six versions of these designs were silicon-proven using four different CMOS technologies. The example of implementation in 130 nm technology provides a reference current of 5 µA and reference voltage of 800 mV at supply voltages ranging from 0.9 V to 2.0 V with a total current consumption of 15 µA. The proposed circuit occupies a 1200 µm2 chip area and achieves 280 and 118 ppm/°C for all process corners and temperature variation from −40 °C to 125 °C. The power supply rejection ratio of output IREF without any filtering capacitor at 100 Hz and 10 MHz is 128 dB and 100 dB, respectively. The equivalent output current noise in the bandwidth from 1 Hz to 10 MHz reaches 9.1 nARMS.

Optimization and improvement of voltage mode band-gap reference circuit and current mode band-gap reference circuit based on comparative analysis method

Voltage mode band-gap reference source and current mode band-gap reference source is the basic unit of integrated circuit, which plays an important role in some circuit systems such as low-voltage linear regulator, power control chip and analog-to-digital/analog-to-digital converter. Band-gap reference circuit is divided into voltage mode band-gap reference circuit and current mode band-gap reference circuit, and their basic principles and optimization methods are different. The voltage mode bandgap reference voltage is generated by superimposing voltages with positive and negative temperature coefficients, thereby producing a low-temperature related factor. In contrast, the current mode bandgap reference generates a reference voltage by superimposing currents with positive and negative temperature coefficients, requiring appropriate resistance matching and compensation. This paper analyzes the basic principles of the above two band-gap reference circuits, analyzes the temperature characteristics and mismatch sources of them, compares the research results including the implementation mode, temperature characteristics, application range and optimization scheme of the two, and looks forward to the future development prospect of both types of circuits.

Compensation of the material temperature influence on specific electrical conductivity during eddy current structurescopy

The importance of eddy current measurements of specific electrical conductivity (SEC) of materials in non-destructive testing for solving problems of structuroscopy is discussed. In particular, their significant role is shown for estimation of the degree of changes in the mechanical characteristics of structural materials due to degradation processes in their structure. The influence of the temperature of metallic structural materials on the results of eddy current measuring of SEC has been studied. An analytical expression for the output signal of the SEC measuring channel of an electrical eddy current conductivity meter for real temperature of material is obtained. It depends on the value of the material SEC at a nominal temperature value (usually 20 C), temperature coefficient of electrical resistance of the material and the deviation of the material real temperature from the nominal value. It is shown that in order to tune out this effect and bring the measurement results to the nominal temperature, it is necessary to use eddy current meters with an additional channel for measuring the material temperature in the testing zone. The output signal of this channel is used to correct the SEC measurement results. This is carried out by multiplying the output signal of the SEC measurement channel and some auxiliary signal. This auxiliary signal is generated from the output signal of the temperature measurement channel by it scaling and summation with the signal of the direct current voltage reference source. A functional diagram of the eddy current SEC meter with temperature correction is proposed. A detailed description of it operation is given. In the absence of preliminary information about the grade of material and the value of its temperature coefficient of electrical resistance, is proposed to suppress the influence of temperature by test changes in the temperature of the material in the testing zone. At the same time, it is necessary to adjust the gain of the scale converter. This is done until the readings of the eddy current SEC meter do not depend on the material temperature in the testing zone.

An experimental investigation of variable-step-size Affine Projection Sign based algorithm for power quality enhanced grid-interactive solar PV system

This article proposes a variable-step-size Affine Projection Sign algorithm that improves power quality ancillary services in a grid-interactive solar photovoltaic system. VSS-APS algorithm features decreased steady-state fluctuation, faster convergence, and robustness to disturbances. The VSS-APS algorithm efficiently extracts contaminated source current active and non-active fundamental weight components to estimate source current reference signals. The solar grid-integrated voltage source inverter manages solar PV unit active power and provides free multipurpose PQ-ancillary services. Harmonic current, active power, load, neutral current, reactive power, and power factor correction are the PQ indices that improved significantly with the proposed VSS-APS control. VSS-APS improves GISVSI's steady-state and dynamic performance. MATLAB®/SIMULINK and a scaled laboratory prototype developed to test the VSS-APS control approach. The DSP-dSPACE 1104 controller implements the suggested controller in real time. The proposed VSS-APS control algorithm is compared with the conventional algorithms, and test results from a laboratory experiment demonstrate its feasibility and benefits. The experimental results show that the proposed VSS-APS algorithm is effective in improving power quality while complying to IEEE 519-2014 and IEEE 1547-2003 standards for grid connections.

Alleviation of Power Quality Issues in MVF-DEANF-PLL Based Solar PV Systems under Polluted Grid Conditions

Solar energy is a sustainable and environmentally safe power source due to its widespread availability and cleanliness. Nowadays, the grid-integrated solar photovoltaic system (SPVS) has to work with a polluted grid, an imbalanced load, and changing solar irradiation. When the grid is polluted, it is also crucial to enhance power quality (PQ) at a common coupling point (CCP) while supplying significantly distorted and unreliable loads. For effective synchronization and the production of unit templates, it is necessary to retrieve positive sequence components (PSCs) from distorted/imbalanced grid voltages. In this study, a control algorithm for a grid-integrated SPVS is developed using a multi-variable filter dual-enhanced adaptive notch filter phase-locked loop (MVF-DEANF-PLL) which offers seamless grid synchronization and PQ issue alleviation. In a polluted grid environment, the proposed control approach aids in the reduction in current/voltage harmonics, DC offset, unity power factor (UPF) operation, and rapid estimation of sequence components. Even in unbalanced grid conditions, the proposed control approach efficiently extracts PSCs of both unbalanced load current and polluted CCP grid voltages. These PSCs are utilized to generate unit templates and reference source currents. By using a flexible step-size incremental conductance (FSSINC) maximum power point tracking (MPPT) technique, the highest available power of SPVS is gathered. MATLAB/Simulink is utilized for modelling a 7.22 kW SPV system, and results from simulations which depict that the proposed algorithm efficiently resolves PQ concerns in distribution networks with a polluted grid. Test observations of a 1 kW laboratory-developed SPVS prototype were recorded in compliance with the IEEE-519 standard. The suggested control technique complies with the aforementioned standards by providing a sinusoidal balanced source current that has a THD of 2.5%. Comparisons between the proposed control’s performance and that of a conventional SRF-PLL-based control technique were also performed.

Control and Implementation of an Energy Management Strategy for a PV–Wind–Battery Microgrid Based on an Intelligent Prediction Algorithm of Energy Production

This paper describes an energy management strategy for a DC microgrid that utilizes a hybrid renewable energy system (HRES) composed of a photovoltaic (PV) module, a wind turbine based on a permanent magnetic synchronous generator (PMSG), and a battery energy storage system (BESS). The strategy is designed to provide a flexible and reliable system architecture that ensures continuous power supply to loads under all conditions. The control scheme is based on the generation of reference source currents and the management of power flux. To optimize the supply–demand balance and ensure optimal power sharing, the strategy employs artificial intelligence algorithms that use previous data, constantly updated forecasts (such as weather forecasts and local production data), and other factors to control all system components in an optimal manner. A double-input single-output DC–DC converter is used to extract the maximum power point tracking (MPPT) from each source. This allows the converter to still transfer power from one source to another even if one of the sources is unable to generate power. In this HRES configuration, all the sources are connected in parallel through the common DC–DC converter. The strategy also includes a long short-term memory (LSTM) network-based forecasting approach to predict the available energy production and the battery state of charge (SOC). The system is tested using Matlab/Simulink and validated experimentally in a laboratory setting.

Digital Control of DSTATCOM using TI-C2000 Processor and MATLAB/ Simulink for Sustainable Power System Network

This paper describes the detailed digital control of a Distribution Static Synchronous shunt Compensator (DSTATCOM) using a MATLAB embedded coder for compensation to be in command of Voltage Source Converter (VSC) input voltage, reactive power compensation and the power factor improvement of a secondary radial distribution system with a voltage rating of 11kV/415V and with a capacity of 750 kW. The model has been simulated and tested in MATLAB/Simulink using the Simscape tool block set version of MATLAB R2019a. The same is achieved using a 32-bit DSP TMS320F2812 controller programmed with CCS V 6.1 software and tested with MATLAB embedded coder generation using Texas Instrument C2000 processors. Using this embedded code is developed and dumped into the CCS V 6.1. Real and Reactive power control (PQ) and Back Propagation Control Algorithm (BPCA) are the control methods. BPCA controller is based on the elementary extracted biased value of Reactive Power (Q) and Active Power (P) components of load currents. These current values are necessary for the reference source's current estimation. The reference source currents are estimated from the available source currents to generate firing pulses for the PQ and BPCA controllers. The real and reactive power controller is based on the transformation of synchronously rotating load currents in alpha and beta frames. The BPCA-based DSTATCOM is simulated for linear and non-linear load circumstances and that helps in restoring the power system networks sustainability.

SOGI-FLL-WDCRC Filter for Seamless Control of Microgrid for Optimal Coordination of Conventional and Renewable Energy Resources

An efficient control strategy is presented in this paper to obtain seamless synchronization and improved power quality (PQ) for an AC microgrid feeding highly distorted and unpredictable loads. This paper proposes an improved second-order generalized integrator-frequency locked loop with DC-offset rejection capacity (SOGI-FLL-WDCRC) filter in an AC microgrid to mitigate the grid pollution and the PQ issues caused by the nonlinear loads. The SOGI-FLL-WDCRC filter accurately estimates the positive sequence components (PSCs), phase angle and frequency from the abnormal grid voltages. Thereby, high-quality grid currents and seamless synchronization are realized even at abnormal grid voltages. Moreover, it accurately extracts the fundamental active weight component of the nonlinear load currents, even during dynamic conditions. This results in the generation of accurate reference source currents, thus allowing efficient functioning of the voltage source converter (VSC) and delivering high-quality power to the system by mitigating the load's harmonics, reactive power and unbalanced components. The proposed control is designed in MATLAB/Simulink platform and its performance is studied. A 3.2kW solar PV array integrated to a 220V (line), 50Hz three-phase utility grid/DEG set is designed and developed as a laboratory prototype to validate the simulated responses. Furthermore, the effectiveness of the proposed control is verified and compared with conventional controls using dSPACE-1202 MicroLabBox on a laboratory test bed. The results obtained from the simulation software and laboratory test bed confirm the effectiveness of the proposed control in estimating the accurate PSCs of grid voltages and oscillations free weight components with higher convergence and better stability under abnormal grid and load conditions.

AN ACCURACY IMPROVEMENT TECHNIQUE FOR ON-CHIP CURRENT SOURCES

A new design technique for accuracy improvement of on-chip reference current sources is proposed. A mathematical model has been developed describing the operation of the proposed technique. Based on the obtained equations, the variation of the reference current caused by the changes in operating conditions and process inaccuracies of the technological should not exceed 1…2%. The proposed technique has been implemented in the design of on-chip reference current source circuit in 14 nm FinFet technology. Spice simulations performed for the developed circuit show less than ± 5% variation of the reference current in the -40...1250C temperature range considering the process variations in ±3 sigma range. The circuit keeps that accuracy for the supply voltage drop up to 0.66 V.

Control algorithm for coordinated operation of wind-solar microgrid standalone generation system

ABSTRACT In this paper, a wind-driven self-excited induction generator (SEIG) combining solar photovoltaic (SPV) and battery storage has been successfully demonstrated. A second-order sequence filter-based frequency locked loop (SOSF-FLL) control is implemented for operating the voltage source converter (VSC). The SOSF-FLL method is designed by replacing two second-order low pass filter (LPF) pure integrators with two reduced order generalized integrators (ROGIs). The SOSF-FLL has a nonlinear control feedback system. The major contributions in this study include: 1. Implementation of SOSF-FLL control to generate reference source currents for VSC and evaluate the amplitude of load current component under intermittent condition of renewable energy sources (RESs) and nonlinear load, 2) The control algorithm with VSC performs numerous functions such as voltage/frequency regulation, load leveling, harmonic reduction, active/reactive power compensation and reduces the overall power quality problems, 3) Through DC-link voltage management, a bidirectional converter (BDC) with battery storage optimizes the best power flow to provide power balancing between the sources and the unbalanced load, 4) Under diverse operating situations, an incremental conductance (INC)-based maximum power point tracking approach with BDC control provides quick system convergence and support frequency. Moreover, a comparison is carried out between SOSF-FLL control and conventional control algorithms. The settling time of the proposed control is very less than one cycle (20 ms) within 2% described limit, whereas the conventional control algorithms show oscillations of more than 5% during the load dynamics. Despite the load current THD 24.41%, the proposed control is able to obtain supply current THD at 4.23%, which is less than 5% as per IEEE-519 standard. The proposed microgrid (MG) is constructed in MATLAB/Simulink and experimental prototype environment, and its dynamic response is investigated under dynamic conditions of RESs and nonlinear load conditions.

THERMOSTABLE REFERENCE CURRENT AND VOLTAGE SOURCES FOR HIGH-LINEAR ANALOGUE-CODE-ANALOGUE SYSTEM

DC sources and reference voltage sources are widely used in various electronic devices: analog-to-digital and digital-to-analog converters, DC amplifiers, sample-and-hold devices, stabilized voltage sources, and others. At the same time, the accuracy and temperature characteristics of the latter largely depend on the same characteristics of direct current and voltage sources, which are subject to stringent requirements. There are quite a lot of different approaches to the construction of reference voltage and current source circuits with thermal compensation. The most famous of them – with the use of thermally compensated zener diodes operating in reverse breakdown mode. However, devices based on them have a high power consumption and low efficiency and a high level of noise, and it is difficult to implement temperature drift compensation due to a wide spread of temperature characteristics. The so-called bandgap circuits are also widely used – transistor reference voltage sources, the value of the reference voltage of which is determined by the band gap of the semiconductor. The most famous of them are Vidlar’s bandgaps and Brokau’s bandgaps. The specificity of all bandgap circuits is the rigid binding of the output voltage to the band gap of the semiconductor. The article proposes an alternative approach to the construction of direct current and voltage sources, which consists in the use of circuits of two-pole direct current sources. A new approach to the construction of thermally stable reference current sources based on bipolar transistors using the band gap voltage of a semiconductor and current mirrors is proposed. The principles of operation of the circuits are described and the possibility of achieving thermal compensation is proved. Computer modelling of the static characteristics of the proposed reference current sources, in particular, the temperature drift of the currents, has been carried out. A new approach to the construction of thermally stable reference voltage sources based on bipolar transistors with the use of thermally stable reference current generators is proposed. Analytical expressions are obtained that describe operation of circuits of reference voltage sources according to the proposed approach. A method for increasing the loading capacity of these reference voltage sources is proposed.

Modified CCF Based Shunt Active Power Filter Operation With Dead-Band Elimination for Effective Harmonic and Unbalance Compensation in 3-Phase 3-Wire System

The effect of reduction in the terminal voltage of a grid-tied inverter together with minimization in total harmonic distortion (THD) of terminal voltage and current, in the presence of dead-band in the switching remains always challenging for the researchers. With high switching frequency, this issue increases by many folds. The grid-tied inverter used for harmonic compensation acts as a shunt active power filter (SAPF). The implementation of the dead-band elimination technique is based on output current polarity detection, suffers from multiple zero-crossing due to the generation of high frequency switching harmonics during SAPF operation. This paper deals with a dead band elimination methodology together with harmonic compensation using SAPF under non-linear and unbalanced loading conditions. Here, SAPF uses a dual fundamental component extraction (DFCE) scheme with modified complex coefficient filter (MCCF) to extract fundamental components for reference current generation to implement an indirect current control PWM scheme. MCCF extracts fundamental components even in the presence of dc offset and unbalancing at the input. For incorporating dead-band elimination in control, exact polarity detection is done separately through SAPF output current estimation using sensed load current, and modified CCF computed reference source current. Since the estimated SAPF output current contains no high-frequency switching harmonics, the dead-band elimination technique can be correctly implemented. To synchronize the zero-crossing of the estimated and actual SAPF current, an adaptive delay control is used. The proposed MCCF based control logic’s performance together with the dead-band elimination technique is validated for SAPF operating under non-linear, unbalance, and dynamic load conditions. The proposed dead-band elimination scheme based SAPF model is developed and simulated using MATLAB/ SIMULINK. The simulation results show a significant reduction in source current harmonics due to the elimination of odd harmonic injection into the system by incorporating dead-band elimination in SAPF operation. The real-time simulation of the proposed method is also validated using OPAL-RT OP4510 real-time platform.

The novel frontal alpha asymmetry factor and its association with depression, anxiety, and personality traits.

Frontal alpha asymmetry (FAA) is widely examined in EEG research, yet a procedural consensus on its assessment is lacking. In this study, we tested a latent factorial approach to measure FAA. We assessed resting-state FAA at broad, low, and high alpha bands (8-13; 8-10.5; and 11-13 Hz) using mastoids as reference electrodes and Current Source Density (CSD) transformation (N = 139 non-clinical participants). From mastoid-referenced data, we extracted a frontal alpha asymmetry factor (FAAf) and a parietal factor (PAAf) subjecting all asymmetry indices to a varimax-rotated, principal component analysis. We explored split-half reliability and discriminant validity of the mastoid factors and the mastoid and CSD raw asymmetry indices (F3/4, F7/8, P3/4, and P7/8). Both factor and raw scores reached an excellent split-half reliability (>.99), but only the FAAf reached the maximum discriminant validity from parietal scores. Next, we explored the correlations of latent factor and raw FAA scores with symptoms of depression, anxiety, and personality traits to determine which associations were driven by FAA after variance from parietal activity was removed. After correcting for false discovery rate, only FAAf at the low alpha band was negatively associated with depression symptoms (a latent CES-D factor) and significantly diverged from PAAf's association with depression symptoms. With respect to personality traits, only CSD-transformed F7/8 was positively correlated with Conscientiousness and significantly diverged from the correlations between Conscientiousness and P3/4 and P7/8. Overall, the latent factor approach shows promise for isolating functionally distinct resting-state EEG signatures, although further research is needed to examine construct validity.

Coordinated control of DSTATCOM with switchable capacitor bank in a secondary radial distribution system for power factor improvement

This paper exhibits the coordinated control of 30 kVAr Distribution STATic synchronous COMpensator (DSTATCOM) with 125 kVAr Switchable Capacitor Banks for compensation of reactive power in a 750 kVA secondary radial distribution system. With the control of reactive power in a radial distribution system, the power factor can be improved near to unity. The selected radial distribution system mainly feeding power to vital loads of an Educational Institution. In this paper, the study of 750 kVA secondary radial distribution system is analyzed in terms of electrical power system of institute, power consumption pattern and tariff related issues. Some conclusions to improve the system performance in terms of power factor and reduction in tariff were drawn. The coordinated control of switchable capacitor bank and DSTATCOM performance depends on the calculation of the reference source currents that generates the gating pulses of the voltage source converter-based DSTATCOM. For this purpose, the control strategy adopted is Real and Reactive power (PQ) control, Synchronous Reference Frame theory, Back Propagation Control algorithm and Adaptive Linear (ADALINE) control is implemented in this system using MATLAB/SIMULINK software. Generation of the PWM pulses triggers the IGBT of the VSI-based DSTATCOM. This is achieved using DSP TMS 320 F 2812, a 32-bit processor that is programmed with CCS V3.3 and C2000 embedded code generation tool using MATLAB/Simulink, and the same is being executed with code composer studio V 6.0.1. The performance of the selected secondary radial distribution system is analyzed experimentally in a hardware prototype to evaluate the effect of DSTATCOM and switchable capacitor bank.

Principles of Empirical and Therapeutic Antimicrobial Therapy

The goal of this review is to discuss basic principles for the appropriate use of antibiotics in the surgical patient, largely focusing on the treatment of intra-abdominal infections. Limited pharmacologic data on common antibiotics are provided. Current reference sources and institutional guidelines should be used for specifics on dosing and administration. This review covers general principles, including treatment of surgical infections, laboratory tests, pharmacokinetics and pharmacodynamics, adverse reactions, antimicrobial resistance, and antibiotic prophylaxis in surgical patients. In addition, specific considerations of appropriate antimicrobial therapy, such as acute cholecystitis/cholangitis, pancreatitis, appendicitis, diverticulitis, Clostridium difficile, and skin and soft tissue infections are presented. Tables list high-risk factors in intra-abdominal infections, empirical antibiotic based on risk stratification for the treatment of community-acquired intra-abdominal infections, dose adjustments for obese patients, most common isolated pathogens from intra-abdominal infections, 2005–2010, with resistance trends, adaptation of Tokyo guidelines on severity scoring and recommended antimicrobial therapy, and recommended antibiotics for necrotizing soft tissue infections. This review contains 6 tables and 56 references

Principles of Empirical and Therapeutic Antimicrobial Therapy

The goal of this review is to discuss basic principles for the appropriate use of antibiotics in the surgical patient, largely focusing on the treatment of intra-abdominal infections. Limited pharmacologic data on common antibiotics are provided. Current reference sources and institutional guidelines should be used for specifics on dosing and administration. This review covers general principles, including treatment of surgical infections, laboratory tests, pharmacokinetics and pharmacodynamics, adverse reactions, antimicrobial resistance, and antibiotic prophylaxis in surgical patients. In addition, specific considerations of appropriate antimicrobial therapy, such as acute cholecystitis/cholangitis, pancreatitis, appendicitis, diverticulitis, Clostridium difficile, and skin and soft tissue infections are presented. Tables list high-risk factors in intra-abdominal infections, empirical antibiotic based on risk stratification for the treatment of community-acquired intra-abdominal infections, dose adjustments for obese patients, most common isolated pathogens from intra-abdominal infections, 2005–2010, with resistance trends, adaptation of Tokyo guidelines on severity scoring and recommended antimicrobial therapy, and recommended antibiotics for necrotizing soft tissue infections. This review contains 6 tables and 56 references

Principles of Empirical and Therapeutic Antimicrobial Therapy

The goal of this review is to discuss basic principles for the appropriate use of antibiotics in the surgical patient, largely focusing on the treatment of intra-abdominal infections. Limited pharmacologic data on common antibiotics are provided. Current reference sources and institutional guidelines should be used for specifics on dosing and administration. This review covers general principles, including treatment of surgical infections, laboratory tests, pharmacokinetics and pharmacodynamics, adverse reactions, antimicrobial resistance, and antibiotic prophylaxis in surgical patients. In addition, specific considerations of appropriate antimicrobial therapy, such as acute cholecystitis/cholangitis, pancreatitis, appendicitis, diverticulitis, Clostridium difficile, and skin and soft tissue infections are presented. Tables list high-risk factors in intra-abdominal infections, empirical antibiotic based on risk stratification for the treatment of community-acquired intra-abdominal infections, dose adjustments for obese patients, most common isolated pathogens from intra-abdominal infections, 2005–2010, with resistance trends, adaptation of Tokyo guidelines on severity scoring and recommended antimicrobial therapy, and recommended antibiotics for necrotizing soft tissue infections. This review contains 6 tables and 56 references

EPLL Control Technique Optimum Controller Gains to Control Voltage and Frequency in Standalone Wind Energy Conversion System

This study describes how to regulate the frequency and terminal voltage of a freestanding wind energy conversion system using an Enhanced Phase Locked Loop (EPLL)-based strategy to supply power to varied loads regardless of wind speed. In a standalone wind turbine energy conversion system, the EPLL control scheme extracts the reference source currents (SWECS). The control algorithm employs two proportional-integral (PI) controllers to create the active and reactive power components of the consumers' load currents, estimate reference source currents, and connect the zigzag transformer to PCC with VSC for neutral current compensation. To obtain optimal PI controller gains and most-suited settings to apply to SWECS, optimization approaches are used. The control algorithm is the most significant aspect of the system, and the speed with which it calculates, evaluates, and guesstimates determines the generation of source currents based on the algorithm's ideal controller PI gains. By properly estimating source currents, the EPLL control method improves dynamics and power quality issues, and the optimization technique is employed to acquire the gains of PI controllers. The proposed system employs the EPLL algorithm on a three-phase, four-wire system with changing loads to achieve ideal total harmonic distortion of source currents and voltages on the PCC, as defined by IEEE-519 standards. A battery energy storage device coupled to the VSC dc link keeps the load's necessary power constant. If the generator output exceeds the consumer demand, the excess power is delivered to BESS for temporary storage. When consumer demand exceeds generated power, a BESS delivers deficit power to the load, which adjusts and the frequency under various load conditions. The suggested system simulated results were tested with 3-phase 4-wire for harmonics reduction, load balancing, neutral wire current compensation, frequency and voltage control using MATLAB / Simulink.

Experimental validation of advanced SP-SAF based on intelligent controllers for power quality enhancement

In this paper, an intelligent control of the single-phase shunt active filter (SP-SAF) for power quality improvement is proposed. The developed approach is essentially composed of two controllers based on the fuzzy logic theory. The first fuzzy proportional derivative (PD) controller with integral (I) action replacing the standard PI regulator, intervenes in the DC voltage regulation loop of the depollution device. In addition, it effectively participates in the delivery of the reference source current. The second controller represented by a fuzzy hysteresis regulator ensures better control of the filter current. Moreover, it acts as an intelligent governance decision maker of the (DC/AC) converter constituting the filtering system. The strategy offers a source current of sinusoidal shape respecting the imposed international standards and the operation of the treated system under a power factor very close to unity. The effectiveness of the new proposed control strategy has been tested through MATLAB/Simulink software and practically validated via the dSPACE 1104 card under various operating conditions. Finally, the experimental results show that the proposed control paradigm outperformed the existing control schemes.