Relevant bibliographies by topics / Rectifier

Contents

  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers
  6. Reports

Academic literature on the topic 'Rectifier'

Author: Grafiati
Published: 4 June 2021
Last updated: 11 June 2025

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Journal articles on the topic "Rectifier"

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Shokrani, Mohammad Reza, Mojtaba Khoddam, Mohd Nizar B. Hamidon, Noor Ain Kamsani, Fakhrul Zaman Rokhani, and Suhaidi Bin Shafie. "An RF Energy Harvester System Using UHF Micropower CMOS Rectifier Based on a Diode Connected CMOS Transistor." Scientific World Journal 2014 (2014): 1–11. http://dx.doi.org/10.1155/2014/963709.

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This paper presents a new type diode connected MOS transistor to improve CMOS conventional rectifier's performance in RF energy harvester systems for wireless sensor networks in which the circuits are designed in 0.18 μm TSMC CMOS technology. The proposed diode connected MOS transistor uses a new bulk connection which leads to reduction in the threshold voltage and leakage current; therefore, it contributes to increment of the rectifier’s output voltage, output current, and efficiency when it is well important in the conventional CMOS rectifiers. The design technique for the rectifiers is explained and a matching network has been proposed to increase the sensitivity of the proposed rectifier. Five-stage rectifier with a matching network is proposed based on the optimization. The simulation results shows 18.2% improvement in the efficiency of the rectifier circuit and increase in sensitivity of RF energy harvester circuit. All circuits are designed in 0.18 μm TSMC CMOS technology.
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Safonov, Valery, and Mikhail Dziuba. "Voltage regulation and phase quantity increase of two high-power 12-phase rectifiers." International Journal of Power Electronics and Drive Systems (IJPEDS) 10, no. 3 (2019): 1454. http://dx.doi.org/10.11591/ijpeds.v10.i3.pp1454-1460.

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In this article, we present a new method of simultaneously increasing the phase quantity and regulating the rectified voltage for two 12-phase high-power rectifiers operating at a common load. Self-excited voltage inverters separately form the necessary voltages for voltage regulation and for increasing the phase quantity. The formed voltage is input with the help of a common booster transformer. Separating the inverters functions and using the common booster transformer makes it possible to reduce the installed power of the equipment significantly compared to similar circuits when the regulation range of the rectified voltage is up to 5%. Calculations show that the inverter power for increasing the phase quantity is about 3% of the rectifier power. The circuit was modeled in MatLab/Simulink and the electromagnetic processes in the rectifier were studied. The proposed method makes it possible to reduce the total harmonic distortion of the network current and the pulsation coefficient of the rectified voltage to the values typical for 24-phase rectifiers.
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Chien, Hung-Chun. "Switch-Controllable Full-Phase Operation Precision Half-Wave Rectifier Using a Single OTRA." Journal of Circuits, Systems and Computers 25, no. 07 (2016): 1650070. http://dx.doi.org/10.1142/s0218126616500705.

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This paper proposes designing a precision rectification circuit by using a single operational transresistance amplifier (OTRA). The proposed circuit is a switch-controllable OTRA-based full-phase operation precision half-wave rectifier, which can rectify an input signal to yield four-phase half-wave rectified output signals. Compared with existing designs, the advantage of the proposed circuit is that all of the possible rectified outputs of a half-wave rectifier can be obtained in one configuration. This paper first reviews previously reported half-wave precision rectifiers consisting of various active devices and the proposed OTRA-based precision half-wave rectifier; subsequently, an analysis of non-ideal effects and design considerations are presented. Computer simulations of the proposed circuit were conducted for verifying the feasibility of the circuit by using the Taiwan Semiconductor Manufacturing Company (TSMC) 0.35-[Formula: see text]m CMOS process technology. For practical circuit measurements, a prototype circuit was implemented, and commercially integrated circuits (AD844ANs) and discrete passive components were used to conduct experimental tests. The simulation and experimental results exhibited satisfactory agreement with those of theoretical analyses.
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Et. al., Evseev Alexei Mikhailovich,. "Rectifilter for electric arc plasma plant." Turkish Journal of Computer and Mathematics Education (TURCOMAT) 12, no. 2 (2021): 3130–36. http://dx.doi.org/10.17762/turcomat.v12i2.2358.

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This article presents the results of the development and research of a new type of AC-DC converter - a filter-rectifier (or rectifilter). The object of application of the proposed device is an industrial plant of electric arc plasma processing, the operation of which requires maintaining a constant value of the arc current and is accompanied by a high level of harmonic distortion and consumed reactive energy. From the point of view of the reactive power compensation and harmonic filtering strategy, the rectifilter can be attributed to active electric power filters and FACTS, however, from the position of the main function performed, it is a direct current source, an AC to DC converter, an active rectifier. This work describes in detail the principles of operation of the control system and the hardware architecture of the device. Mathematical modeling of the rectifilter and analysis of the graphs of the consumed alternating current, rectified current, analysis of the harmonic composition and power factor in comparison with the thyristor rectifier of an electric arc plasmatron were carried out.
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Gonçalves, José Teixeira, Stanimir Valtchev, Rui Melicio, Alcides Gonçalves, and Frede Blaabjerg. "Hybrid Three-Phase Rectifiers with Active Power Factor Correction: A Systematic Review." Electronics 10, no. 13 (2021): 1520. http://dx.doi.org/10.3390/electronics10131520.

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The hybrid three-phase rectifiers (HTR) consist of parallel associations of two rectifiers (rectifier 1 and rectifier 2), each one of them with a distinct operation, while the sum of their input currents forms a sinusoidal or multilevel waveform. In general, rectifier 1 is a GRAETZ (full bridge) (can be combined with a BOOST converter) and rectifier 2 is combined with a DC-DC converter. In this HTR contest, this paper is intended to answer some important questions about those hybrid rectifiers. To obtain the correct answers, the study is conducted as an analysis of a systematic literature review. Thus, a search was carried out in the databases, mostly IEEE and IET, and 34 papers were selected as the best corresponding to the HTR theme. It is observed that the preferred form of power distribution in unidirectional hybrid three-phase rectifiers (UHTR) is 55%Po (rectifier 1) and 45%Po (rectifier 2). For the bidirectional hybrid three-phase rectifiers (BHTR), rectifier 1 preferably takes 90% of Po and 10% of Po is processed by rectifier 2. It is also observed that the UHTR that employ the single-ended primary-inductor converter (SEPIC) or VIENNA converter topologies in rectifier 2 can present sinusoidal input currents with low total harmonic distortion (THD) and high Power Factor (PF), even successfully complying with the international standards. The same can be said about the rectifier that employs a pulse-width (PWM) converter of BOOST topology in rectifier 2. In short, the HTR are interesting because they allow using the GRAETZ full bridge topology in rectifier 1, thus taking advantage of its characteristics, being simple, robust, and reliable. At the same time, the advantages of rectifier 2, i.e., high PF and low THD, are well used. In addition, this article also points out the future direction of research that is still unexplored in the literature, thus giving opportunities for future innovation.
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S. Dhayabarasivam, S., K. Jayanthi, and Gouthame Pragatheeswaran. "Design and Analysis of Modified Diode Rectifier Circuit Suitable for Piezoelectric Energy Harvester for Biomedical Applications." International Journal of Engineering & Technology 7, no. 3.16 (2018): 67. http://dx.doi.org/10.14419/ijet.v7i3.16.16185.

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Nowadays renewable energy sources play a significant role in the energy harvesting. For the past decade various energy harvesting methods have been discussed by researchers for capturing the energy from different sources. From the survey, one of the most prominent methods is the use of piezoelectric transducers for harvesting the energy. It is known that piezoelectric energy harvesting is the easiest method of energy harvesting from the various sources available such as human walking, dancing etc. Therefore this method can be implemented in system for wide variety of applications. The piezoelectric transducer AC output is of very low voltage and power and hence insufficient to drive any electrical application. Most of the small scale electrical application generally runs on the DC voltage, therefore the AC voltage obtained from the piezo transducer vibration is rectified using rectifiers to generate DC voltage. Thus in this paper, a modified rectifier AC/DC converter with the combination of an inductor is placed in the rectifier, which enhances the voltage and power from the rectifier output. In order to enhance the voltage rating, a DC/DC converter has been added at the end of a rectifier circuit. From the simulation results the proposed circuit modified rectifier has improved the output voltage as well as output current by 10.19 volts and 0.1019 amps respectively for input voltage of 5V. When compared with conventional rectifier circuit.
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Nizov, Anatoly S., Andrey N. Shtin, Konstantin G. Shumakov, and Dmitry V. Lesnikov. "Operation modes of a semiconductor voltage-boosting device for voltage regulation at traction substations." Innotrans, no. 4 (2022): 58–64. http://dx.doi.org/10.20291/2311-164x-2022-4-58-64.

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One of the ways to strengthen the DC power supply system of the main railways of Russia is the use of semiconductor voltage-boosting devices for voltage regulation at traction substations. The work of diode and thyristor bridge rectifiers connected in series with it is considered in the article. The analysis is performed under the condition that active and reactive resistances of the supply network and the converter transformer are zero. It was found out that, depending on the magnitude of the control angle, such a converter can have two modes of operation. For these modes, time diagrams of the rectified voltages of both the thyristor bridge and the entire converter are constructed. Expressions are obtained for determining the average values of the rectified voltages of a 12-pulse diode rectifier of a serial type and a 12-pulse thyristor rectifier of a parallel type connected in series with it. The calculation of the adjustment characteristics of this adjustable converter is performed.
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Cheng, Hong, Xin Li, Cong Wang, Zhihao Zhao, Yucheng Shen, and Wei Yuan. "SEPIC-Boost-Based Unidirectional PFC Rectifier with Wide Output Voltage Range." Electronics 13, no. 2 (2024): 357. http://dx.doi.org/10.3390/electronics13020357.

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A novel unidirectional hybrid PFC rectifier topology based on SEPIC and boost converters is proposed, which is applicable to various industrial applications such as electric vehicle charging stations, variable speed AC drives, and energy storage systems. Compared to other rectifiers, the proposed SEPIC-boost-based rectifier exhibits continuous current on the AC side, lower voltage stress on the active switches, a wider range of DC output voltage, no auxiliary DC-DC converters, and a high step-up static voltage gain operating with low input voltage and a low step-up static gain for the high-input-voltage operation. These traits allow the SEPIC-boost-based rectifier to utilize smaller input-side harmonic filtering inductors and adopt active switches with lower voltage ratings, resulting in reduced conduction losses. Additionally, the proposed rectifier features power factor correction and high boost/buck voltage-gain capabilities, simplifying control for electric vehicle charging and expanding its range of applications. In this paper, the operating principle of the novel topology is presented first, and then the mathematical model of the proposed rectifier is built. Based on this, the comparison between the proposed topology and conventional boost and SEPIC converters is given. Furthermore, the control strategy, including the high-power-factor control and the balancing control to the DC capacitor voltages, is discussed. Finally, to validate the accuracy of the proposed rectifier’s theoretical research, a 500-W SEPIC-boost rectifier system has been constructed in the laboratory, generating a 200/120 Vdc output voltage from a 155 Vpk/50 Hz power source.
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Jeon, Hyeonmin, Jongsu Kim, and Kyoungkuk Yoon. "Large-Scale Electric Propulsion Systems in Ships Using an Active Front-End Rectifier." Journal of Marine Science and Engineering 7, no. 6 (2019): 168. http://dx.doi.org/10.3390/jmse7060168.

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In the case of the electric propulsion system on the vessel, Diode Front End (DFE) rectifiers have been applied for large-sized ships and Active Front End (AFE) rectifiers have been utilized for small and medium-sized ships as a part of the system. In this paper, we design a large electric propulsion ship system using AFE rectifier with the proposed phase angle detector and verify the feasibility of the system by simulation. The phase angle derived from the proposed phase angle detection method is applied to the control of the AFE rectifier instead of the zero-crossing method used to detect the phase angle in the control of the conventional AFE rectifier. We compare and analyze the speed control, Direct Current (DC)-link voltage, harmonic content and measurement data of heat loss by inverter switch obtained from the simulation of the electric propulsion system with the 24-pulse DFE rectifier, the conventional AFE rectifier, and the proposed AFE rectifier. As a result of the simulation, it was confirmed that the proposed AFE rectifier derives a satisfactory result similar to that of a 24-pulse DFE rectifier with a phase shifting transformer installed according to the speed load of the ship, and it can be designed and applied as a rectifier of a large-sized vessel.
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Shi, Liwei, Bing Yan, Xiaoyu Zhou, and Xueyi Zhang. "Open-Circuit Fault-Tolerant Characteristics of a New Four-Phase Doubly Salient Electro-Magnetic Generator." Sustainability 10, no. 11 (2018): 4136. http://dx.doi.org/10.3390/su10114136.

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In order to improve the reliability of a more sustainable mobility generator, a four-phase Doubly Salient Electro-Magnetic Generator (DSEG) and its phase-isolated rectifier are proposed in this paper. The mathematical model of the machine and fault-tolerant rectifiers is proposed, which indicates that the four-phase fault-tolerant DSEG should have symmetric phases. With the asymmetry analysis of the traditional 8/6-pole DSEG, a new 12/9-pole DSEG with symmetric phases is proposed. The four-phase full bridge rectifier, positive half-wave rectifier and four-phase H bridge rectifier are presented. The voltage waveforms, no-load characteristics and loading characteristics with different rectifiers will be given based on the simulation and the experiment on a prototype of DSEG, and the results show that the four-phase H bridge rectifier has the best fault tolerant no-load characteristic and external characteristic, except that it needs more diodes.
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Dissertations / Theses on the topic "Rectifier"

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Zwermann, Ludwig. "Kardiale "Delayed Rectifier" Kaliumkanäle." Diss., lmu, 2005. http://nbn-resolving.de/urn:nbn:de:bvb:19-38213.

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Phipps, William. "New generation three-phase rectifier." Thesis, University of Canterbury. Electrical and Computer Engineering, 2009. http://hdl.handle.net/10092/2371.

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This thesis describes the development of a new generation of three-phase rectifier, used to power telecommunications equipment. The traditional topology for such power converters is a single-phase two-stage design, with a boost converter providing power factor correction at the input to the first stage and an isolated dc-dc converter making up the second stage. A two-stage design results in the output power being processed twice and this cascade effect results in an overall reduction in efficiency. A rectifier solution is sought that meets with all the requirements of the telecommunications industry, while not displaying the inherent weaknesses associated with a boost-derived topology, and which can be realised in a single-stage design. A number of common three-phase topologies exist that could be realised as telecommunication power supplies, however, they do not completely satisfy all the industry requirements. A new three-phase rectifier, which is a single-stage buck-derived topology, is proposed. As a consequence of incorporating a buck-derived topology, the three-phase rectifier does not exhibit any issues resulting from startup inrush currents, or high currents due to an output short circuit condition, as would result in a boost-derived topology. The new proposed rectifier is modular in nature, which has the added benefit of redundancy. As a result of the new three-phase rectifier having a single-stage topology, it is expected that the overall efficiency would able to reach close to 95%. This is due to the traditional two-stage designs having efficiencies around the 90% mark, and therefore by removing a stage, out of the power conversion process the overall losses would also be halved, resulting in the 5% gain in efficiency. The rectifier system requires only one controller as a result of being a single-stage design, thus also reducing the overall system cost. Simulations show that if this topology is combined with a three-phase phase-locked loop controller it can meet the industry compliance standards. The thesis follows the development of the three-phase power converter from the simulation stage to the realisation of the control hardware and stability modelling. It also provides a detailed report of an investigation into the power converter system’s performance. The thesis concludes with discussions concerning the viability of the new topology as a commercial product and indicates areas of possible future research and development.
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Suri, Ramaa Saket. "Design of Voltage Boosting Rectifiers for Wireless Power Transfer Systems." Thesis, University of North Texas, 2019. https://digital.library.unt.edu/ark:/67531/metadc1505212/.

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This thesis presents a multi-stage rectifier for wireless power transfer in biomedical implant systems. The rectifier is built using Schottky diodes. The design has been simulated in 0.5µm and 130nm CMOS processes. The challenges for a rectifier in a wireless power transfer systems are observed to be the efficiency, output voltage yield, operating frequency range and the minimum input voltage the rectifier can convert. The rectifier outperformed the contemporary works in the mentioned criteria.
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Yu, Oscar Nando. "High Voltage Synchronous Rectifier Design Considerations." Diss., Virginia Tech, 2021. http://hdl.handle.net/10919/103384.

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The advent of wide band-gap semiconductors in power electronics has led to the scope of efficient power conversion being pushed further than ever before. This development has allowed for systems to operate at higher and higher voltages than previously achieved. One area of consideration during this high voltage transition is the synchronous rectifier, which is traditionally designed as an afterthought. Prior research in synchronous rectifiers have been limited to low voltage, high current converters. There is practically no research in high voltage synchronous rectification. Therefore, this dissertation focuses on discovering the unknown nuances behind high voltage synchronous rectifier design, and ultimately developing a practical, scalable solution. There are three main issues that must be addressed when designing a high voltage synchronous rectifier: (1) high voltage sensing; (2) light load effects; (3) accuracy. The first hurdle to designing a high voltage SR system is the high voltage itself. Traditional methods of synchronous rectification (SR) attempt to directly sense voltage or current, which is not possible with high voltage. Therefore, a solution must be designed to limit the voltage seen by the sensing mechanism without sacrificing accuracy. In this dissertation, a novel blocking solution is proposed, analyzed, and tested to over 1-kV. The solution is practical enough to be implemented on practically any commercial drain-source SR controller. The second hurdle is the light load effect of the SR system on the converter. A large amount of high voltage systems utilize a LLC-based DC transformers (DCX) to provide an efficient means of energy conversion. The LLC-DCX's attractive attributes of soft-switching and high efficiency allure many architects to combine it with an SR system. However, direct implementation of SR on a LLC-DCX will result in a variety of light load oscillation issues, since the rectifier circuitry can excite the resonant tank through a false load transient phenomena. A universal limiting solution is proposed and analyzed, and is validated with a commercial SR controller. The final hurdle is in optimizing the SR system itself. There is an inherent flaw with drain-source sensing, namely parasitic inductance in the drain-source sense loop. This parasitic inductance causes an error in the sensed voltage, resulting in early SR turn-off and increased losses through the parallel diode. The parasitic will always be present in the circuit, and current solutions are too complex to be implemented. Two solutions are proposed depending on the rectifier architecture: (1) multilevel gate driving for single switch rectifiers; (2) sequential parallel switching for parallel switch rectifiers. In summary, this dissertation focuses on developing a practical and reliable high voltage SR solution for LLC-DCX converters. Three main issues are addressed: (1) high voltage sensing; (2) light load effects; (3) accuracy. Novel solutions are proposed for all three issues, and validated with commercial controllers.<br>Doctor of Philosophy<br>High voltage power electronics are becoming increasing popular in the electronics industry with the help of wide band-gap semiconductors. While high voltage power electronics research is prevalent, a key component of high voltage power converters, the synchronous rectifier, remains unexplored. Conventional synchronous rectifiers are implemented on high current circuits where diode losses are high. However, high voltage power electronics operate at much lower current levels, necessitating changes in current synchronous rectifier methods. This research aims to identify and tackle issues that will be faced by both systems and IC designers when attempting to implement high voltage synchronous rectifiers on LLC-DCXs. While development takes planes on a LLC-DCX, the research is applicable to most resonant converters and applications utilizing drain-source synchronous rectifier technology. This dissertation focuses primarily on three areas of synchronous rectifier developments: (1) high voltage compatibility; (2) light load effects; (3) accuracy. The first issue opens the gate to high voltage synchronous rectifier research, by allowing high voltage sensing. The second issue explores issues that high voltage synchronous rectifiers can inadvertently influence on the LLC-DCX itself - a light load oscillation issue. The third issue explores novel methods of improving the sensing accuracy to further reduce losses for a single and parallel switch rectifier. In each of these areas, the underlying problem is root-caused, analyzed, and a solution proposed. The overarching goal of this dissertation is to develop a practical, low-cost, universal synchronous rectifier system that can be scaled for commercial use.
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Lin, Feng-Hsu. "An Integrated Rectifier/Regulator for a Wireless Battery Charging System." Cleveland, Ohio : Case Western Reserve University, 2009. http://rave.ohiolink.edu/etdc/view?acc_num=case1240273573.

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Dhoopati, Swathi. "Evaluation of dynamic and static electrical characteristics for the DY8 and YI8 process gallium diodes in comparison to the DI8 process boron diodes." Thesis, University of North Texas, 2006. https://digital.library.unt.edu/ark:/67531/metadc5614/.

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A rectifier is an electrical device, comprising one or more semiconductor devices arranged for converting alternating current to direct current by blocking the negative or positive portion of the waveform. The purpose of this study would be to evaluate dynamic and static electrical characteristics of rectifier chips fabricated with (a) DY8 process and (b) YI8 process and compare them with the existing DI8 process rectifiers. These new rectifiers were tested to compare their performance to meet or exceed requirements of lower forward voltages, leakage currents, reverse recovery time, and greater sustainability at higher temperatures compared to diodes manufactured using boron as base (DI8 process diodes) for similar input variables.
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Tunc, Murat. "A Single Transistor Unity Power Factor Rectifier." Master's thesis, METU, 2007. http://etd.lib.metu.edu.tr/upload/12608114/index.pdf.

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This thesis analyzes unity power factor rectifiers since this type of rectifiers use energy as efficient as possible. Throughout the thesis, some unity power factor rectifier topologies are investigated and some of them selected to investigate in detail. Afterwards, a new single transistor unity power factor rectifier topology is proposed, simulated, implemented and compared with one of the selected unity power factor rectifier topology on the basis of efficiency, total harmonic distortion, input current ripple and output voltage ripple.
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Zadek, Brittany. "Inward Rectifier K+ Channel Structure and Function." Thesis, University of Oxford, 2009. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.531660.

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Tsang, D. M. C. "Improvements in integrated high-quality rectifier-regulators." Thesis, Virginia Tech, 1993. http://hdl.handle.net/10919/41945.

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Mokhtari, Hossein. "High speed silicon controlled rectifier static transfer switch." Thesis, National Library of Canada = Bibliothèque nationale du Canada, 1999. http://www.collectionscanada.ca/obj/s4/f2/dsk1/tape8/PQDD_0002/NQ41246.pdf.

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Books on the topic "Rectifier"

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Motorola. Rectifier device data. 2nd ed. Motorola, 1995.

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Baliga, B. Jayant. Advanced Power Rectifier Concepts. Springer US, 2009. http://dx.doi.org/10.1007/978-0-387-75589-2.

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Rectifier, International. Rectifier fast recovery types. International Rectifier, 1993.

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SGS-Thomson. Schottky & rectifier diodes databook. 2nd ed. SGS-Thomson, 1994.

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24 silicon-controlled rectifier projects. Tab Books, 1986.

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Harry, Ashe, Peters John W, and Lewis Research Center, eds. High reliability megawatt transformer/rectifier. National Aeronautics and Space Administration, Lewis Research Center, 1991.

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SGS-Thomson. Zener Schottky and rectifier diodes databook. SGS-Thomson, 1990.

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Aggrey, Albert. Comment faire rectifier un acte de l'état civil? Juris-éditions, 1999.

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Pejovic, Predrag. Three-Phase Diode Bridge Rectifier With Low Harmonics. Springer US, 2007. http://dx.doi.org/10.1007/978-0-387-32936-9.

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Singh, Tejinder. analysis and control of high power synchronous rectifier. National Library of Canada, 1993.

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Book chapters on the topic "Rectifier"

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Melkebeek, Jan A. "Rectifier." In Electrical Machines and Drives. Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-72730-1_7.

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Weik, Martin H. "rectifier." In Computer Science and Communications Dictionary. Springer US, 2000. http://dx.doi.org/10.1007/1-4020-0613-6_15746.

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Gao, Hao, Marion Matters-Kammerer, Dusan Milosevic, and Peter G. M. Baltus. "Rectifier Analysis." In Analog Circuits and Signal Processing. Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-72980-0_4.

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Patil, Mahesh, and Pankaj Rodey. "Uncontrolled Rectifier." In Control Systems for Power Electronics. Springer India, 2015. http://dx.doi.org/10.1007/978-81-322-2328-3_1.

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Patil, Mahesh, and Pankaj Rodey. "Controlled Rectifier." In Control Systems for Power Electronics. Springer India, 2015. http://dx.doi.org/10.1007/978-81-322-2328-3_2.

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Radin, Rafael Luciano, Marcio Bender Machado, Mohamad Sawan, Carlos Galup-Montoro, and Marcio Cherem Schneider. "Rectifier Design." In Analog Circuits and Signal Processing. Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-031-04492-2_4.

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Garg, Ankur, Neelu Jain, Sanjeev Kumar, and Arun K. Singh. "Nano-Rectifier." In Nanoelectronic Devices for Hardware and Software Security. CRC Press, 2021. http://dx.doi.org/10.1201/9781003126645-15.

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Yoon, Uooyeol. "Pickup and Rectifier." In The On-line Electric Vehicle. Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-51183-2_12.

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Erickson, Robert W. "The Ideal Rectifier." In Fundamentals of Power Electronics. Springer US, 1997. http://dx.doi.org/10.1007/978-1-4615-7646-4_17.

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Baliga, B. Jayant. "Introduction." In Advanced Power Rectifier Concepts. Springer US, 2009. http://dx.doi.org/10.1007/978-0-387-75589-2_1.

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Conference papers on the topic "Rectifier"

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Черемухин, Дмитрий Андреевич. "EXPERIMENTAL CHECK OF OPERATION OF A SINGLE-PHASE TWO-SEMI-PERIOD RECTIFIER." In Сборник избранных статей по материалам научных конференций ГНИИ “Нацразвитие” (Санкт-Петербург, Апрель 2020). Crossref, 2020. http://dx.doi.org/10.37539/apr290.2020.14.63.006.

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В данной статье будут проанализированы процессы в однофазной мостовой выпрямительной цепи с активной нагрузкой; определено среднее значение выпрямленного напряжения (тока) в цепи. Также будет рассчитана частота пульсации выпрямленного напряжения, коэффициент пульсации. Электрическая схема выпрямителя будет смоделирована в программном комплексе Multisim, который позволяет производить необходимые измерения. This article will analyze processes in a single-phase bridge rectifier circuit with an active load; the average value of the rectified voltage (current) in the circuit is determined. It will also determine the frequency of the ripple of the rectified voltage, the ripple coefficient. The electric circuit of the rectifier will be modeled in the Multisim software package, which allows monitoring the necessary measurements.
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2

Gelman, Vitaly. "Thyristor Controlled Rectifier Testing Using Scaling Theory." In 2018 Joint Rail Conference. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/jrc2018-6133.

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Thyristor Controlled Rectifiers offer numerous advantages for the traction applications: capital cost savings, increased system throughput, reduced maintenance and additional energy and cost savings for reversible controlled rectifiers. Yet the controlled rectifier usage has been limited, partially because of testing difficulties. The multi-megawatt power level makes testing at the test laboratory at full power impractical. Further exasperating the issue is a presence of control systems that can’t be tested completely while running with a shorted output. The paper proposes a way out of this conundrum through the testing at reduced voltage and current (scaling). The scaling allows reducing power requirements 50 to 400 times, making it practical to test both regulating system and power circuit performance with simulated train load current. The scaled voltage/current test verifies a dynamic response under realistic train behavior, voltage regulation curve, AC and DC harmonics. The paper proposes the scaling tests to verify both forward and reverse operation of controlled rectifier.
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Gelman, Vitaly. "Energy Savings With Reversible Thyristor Controlled Rectifier." In 2009 Joint Rail Conference. ASMEDC, 2009. http://dx.doi.org/10.1115/jrc2009-63013.

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The paper deals with energy savings in Traction Systems available with Thyristor Controlled Rectifiers (TCR) and Reversible TCR (RTCR). TCR provides active voltage control, RTCR in addition has power recuperation into AC line. The energy balance of the TCR and diode rectifier systems are calculated, including losses in the rails, car’s power train and friction losses. The TCR advantages over diode rectifiers: better voltage regulation and fault current limiting allow us to reduce the number of substations and increase their service life. Major energy savings are through recuperation back to AC line using RTCR, with additional savings through increased DC bus voltage. The estimated energy savings depending on the system parameters, train speed profile, etc. can be as high as 50%.
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Wu, Wei, Andy G. Lozowski, and Fengxia Wang. "Improved Rectifier Circuit With Backward Diodes for Low Power Source Harvesting." In ASME 2014 Dynamic Systems and Control Conference. American Society of Mechanical Engineers, 2014. http://dx.doi.org/10.1115/dscc2014-6018.

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Most energy harvesting circuits use a Schottky diode rectifier as the first stage in the power conversion system. Schottky diodes are chosen for their low forward-voltage drop which can be as low as 0.15V. Further improvements toward enabling lower voltage sources may be accomplished by using active rectifiers with MOSFET transistors. However such circuits still require an initial start-up phase in which the source voltage needs to exceed the Schottky barrier voltage. As an alternative we propose using backward diodes to build a rectifier with much smaller barrier voltage compared to the Schottky solution. In the past, backward diodes were used in low-voltage diode detectors and are essentially a variation of tunnel diodes. This paper provides both simulation results and an experimental comparative study of the performance of Schottky and backward diodes. The relationship between optimal load, frequency and internal impedance of the voltage source will be discussed as well.
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Yin, Xiuxing, Xiaofan Li, Vicky Boontanom, and Lei Zuo. "Mechanical Motion Rectifier Based Efficient Power Takeoff for Ocean Wave Energy Harvesting." In ASME 2017 Dynamic Systems and Control Conference. American Society of Mechanical Engineers, 2017. http://dx.doi.org/10.1115/dscc2017-5198.

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This paper proposes a novel mechanical-motion-rectifier (MMR) based power-takeoff (PTO) for ocean wave energy harvesting. The proposed PTO directly converts irregular oscillatory wave motion into regular unidirectional rotation of the generator. It is mainly composed of two ball screws, three bevel gears, two one-way clutches, and a generator. The two one-way clutches and the bevel gears change the bi-directional rotation of the two ball screws into unidirectional ration of the generator. The MMR rectifies the irregular reciprocating motion into unidirectional rotation; similar to the way the electric voltage rectifier regulates an AC voltage. The proposed PTO can be integrated into a heaving point wave energy converter (WEC). The dynamics and modelling of the PTO are presented. The frequency-domain dynamics of the WEC are then formulated for operating condition and control. The power generation capability of the proposed WEC has been evaluated in MATLAB and WAMIT. The simulation results demonstrate that the power generation capability can be improved by using the MMR method.
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Tieck, R. M., G. P. Carman, and D. G. Enoch Lee. "Electrical Energy Harvesting Using a Mechanical Rectification Approach." In ASME 2006 International Mechanical Engineering Congress and Exposition. ASMEDC, 2006. http://dx.doi.org/10.1115/imece2006-15712.

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This paper presents a new approach using frequency rectification to harvest electrical energy from mechanical energy using piezoelectric devices. The rectification approach utilizes a linearly traveling Rectifier to impart vibrational motion to a cantilever piezoelectric bimorph. A conventional cantilever-type energy harvester is tested aside the rectified beam. The Standard beam generated 0.11 W of power, a power density of 15.63 kW/m3, and an energy density of 130.7 J/m3. The Rectified beam generated 580 mW of power, a power density of 871.92 kW/m3, and an energy density of 313.15 J/m3, a factor 2.4 greater than conventional energy harvesting methods. These results confirm the original thesis that a mechanically rectified piezoelectric Energy Harvester would generate larger Energy and Power Densities as well as Specific Powers, compared to conventional technologies.
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Kim, G. H., J. H. Jeong, H. Cho, and C. H. Ahn. "Comparison of new rectifier with old rectifiers in Korea Telecom." In 21st International Telecommunications Energy Conference. INTELEC '99 (Cat. No.99CH37007). IEEE, 1999. http://dx.doi.org/10.1109/intlec.1999.794074.

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Chen, Jianfei, and Caisheng Wang. "Detroit Rectifier." In IECON 2018 - 44th Annual Conference of the IEEE Industrial Electronics Society. IEEE, 2018. http://dx.doi.org/10.1109/iecon.2018.8592858.

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Prasad, P. H. K., and M. Venu Gopal Rao. "Synchronous rectifier." In 2010 India International Conference on Power Electronics (IICPE). IEEE, 2011. http://dx.doi.org/10.1109/iicpe.2011.5728068.

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Zhang, Zekun. "Comparison between bridge diode rectifier and other rectifier modes." In ADVANCES IN MATERIALS, MACHINERY, ELECTRONICS III: 3rd International Conference on Advances in Materials, Machinery, Electronics (AMME 2019). Author(s), 2019. http://dx.doi.org/10.1063/1.5090721.

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Reports on the topic "Rectifier"

1

Symons, G. A. Cathodic protection - rectifier 47. Office of Scientific and Technical Information (OSTI), 1997. http://dx.doi.org/10.2172/330715.

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Lane, W. M. Cathodic protection -- Rectifier 47. Office of Scientific and Technical Information (OSTI), 1995. http://dx.doi.org/10.2172/95246.

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Lane, W. M. Cathodic protection -- Rectifier 46. Office of Scientific and Technical Information (OSTI), 1995. http://dx.doi.org/10.2172/95247.

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4

Bellomy, J. R. Cathodic protection-rectifier 46. Office of Scientific and Technical Information (OSTI), 1997. http://dx.doi.org/10.2172/16915.

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Atcitty, Stanley. SiC-Based Transistor-Rectifier Semiconductor Switch. Office of Scientific and Technical Information (OSTI), 2019. http://dx.doi.org/10.2172/1762605.

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Clifton, F. T. Acceptance test procedure for cathodic protection, rectifier 41. Office of Scientific and Technical Information (OSTI), 1995. http://dx.doi.org/10.2172/61738.

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Clifton, F. T. Acceptance test procedure for cathodic protection, rectifier 31. Office of Scientific and Technical Information (OSTI), 1995. http://dx.doi.org/10.2172/61739.

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Clifton, F. T. Acceptance Test Procedure for Cathodic Protection, Rectifier 11. Office of Scientific and Technical Information (OSTI), 1995. http://dx.doi.org/10.2172/69127.

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9

Metzger, Robert M. Ultra Thin Film Characterization of the Organic Rectifier Project. Defense Technical Information Center, 1991. http://dx.doi.org/10.21236/ada236360.

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10

Mark A. Johnson. Recovery Act: High-Efficiency, Wideband Three-Phase Rectifiers and Adaptive Rectifier Management for Telecomm Central Office and Large Data Center Applications. Office of Scientific and Technical Information (OSTI), 2012. http://dx.doi.org/10.2172/1044600.

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