Relevant bibliographies by topics / Voltage regulator

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

Academic literature on the topic 'Voltage regulator'

Author: Grafiati
Published: 4 June 2021
Last updated: 12 February 2022

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Journal articles on the topic "Voltage regulator"

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McCue, B. M., R. L. Greenwell, M. I. Laurence, B. J. Blalock, S. K. Islam, and L. M. Tolbert. "SOI Based Voltage Regulator for High-Temperature Applications." Additional Conferences (Device Packaging, HiTEC, HiTEN, and CICMT) 2012, HITEC (January 1, 2012): 000207–13. http://dx.doi.org/10.4071/hitec-2012-wp12.

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Developments in automotive (particularly hybrid-electric vehicles), aerospace, and energy production industries have led to expanding research interest in integrated circuit (IC) design toward high-temperature applications. A high-voltage, high-temperature silicon-on-insulator (SOI) process allows for circuit design to expand into these extreme environment applications. Nearly all electronic devices require a reliable supply voltage capable of operating under various supply voltages and load currents. These supply voltages and load currents can be either DC or time-varying signals. In this work, a stable supply voltage for embedded circuits is generated on chip via a voltage regulator producing a stable 5-V output voltage. Although applications of this voltage regulator are not limited to gate driver circuits, this regulator has been developed to meet the demands of a gate driver IC. The voltage regulator must be able to provide reliable output voltage over an input range from 10 V to 30 V, a temperature range of −25°C to 200°C, and output loads from 0 mA to 200 mA. Additionally, low power stand-by operation is provided to help reduce heat generation resulting in lower operating junction temperature. The designed voltage regulator has been successfully tested from −50°C to 200°C while demonstrating an output voltage variation of less than 10 mV under the full range of input voltage. Additionally, line regulation tests from 10 V to 30 V show a 12-ppm/V supply sensitivity. Full temperature and input voltage range tests reveal that the no-load supply current draw is within 17 mA while still providing in excess of 200-mA load current upon demand. Modifications to the existing design or off-chip biasing can widen the range of attainable output voltages and drive capabilities.
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Wang, San-Fu. "A 5 V-to-3.3 V CMOS Linear Regulator with Three-Output Temperature-Independent Reference Voltages." Journal of Sensors 2016 (2016): 1–7. http://dx.doi.org/10.1155/2016/1436371.

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This paper presents a 5 V-to-3.3 V linear regulator circuit, which uses 3.3 V CMOS transistors to replace the 5 V CMOS transistors. Thus, the complexity of the manufacturing semiconductor process can be improved. The proposed linear regulator is implemented by cascode architecture, which requires three different reference voltages as the bias voltages of its circuit. Thus, the three-output temperature-independent reference voltage circuit is proposed, which provides three accurate reference voltages simultaneously. The three-output temperature-independent reference voltages also can be used in other circuits of the chip. By using the proposed temperature-independent reference voltages, the proposed linear regulator can provide an accurate output voltage, and it is suitable for low cost, small size, and highly integrated system-on-chip (SoC) applications. Moreover, the proposed linear regulator uses the cascode technique, which improves both the gain performance and the isolation performance. Therefore, the proposed linear regulator has a good performance in reference voltage to output voltage isolation. The voltage variation of the linear regulator is less than 2.153% in the temperature range of −40°C–120°C, and the power supply rejection ratio (PSRR) is less than −42.8 dB at 60 Hz. The regulator can support 0~200 mA output current. The core area is less than 0.16 mm2.
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Diego Maffezzolli, Allan, Rubens Tadeu Hock Júnior, and Alessandro Luiz Batschauer. "CURRENT LIMITATION OF A VOLTAGE-CONTROLLED VOLTAGE REGULATOR." Eletrônica de Potência 25, no. 4 (November 17, 2020): 1–9. http://dx.doi.org/10.18618/rep.2020.4.0028.

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Hietpas, S. M., and M. Naden. "Automatic voltage regulator using an AC voltage-voltage converter." IEEE Transactions on Industry Applications 36, no. 1 (2000): 33–38. http://dx.doi.org/10.1109/28.821793.

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Pashmineh, S., and D. Killat. "High-voltage circuits for power management on 65 nm CMOS." Advances in Radio Science 13 (November 3, 2015): 109–20. http://dx.doi.org/10.5194/ars-13-109-2015.

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Abstract. This paper presents two high-voltage circuits used in power management, a switching driver for buck converter with optimized on-resistance and a low dropout (LDO) voltage regulator with 2-stacked pMOS pass devices. The circuit design is based on stacked MOSFETs, thus the circuits are technology independent. High-voltage drivers with stacked devices suffer from slow switching characteristics. In this paper, a new concept to adjust gate voltages of stacked transistors is introduced for reduction of on-resistance. According to the theory, a circuit is proposed that drives 2 stacked transistors of a driver. Simulation results show a reduction of the on-resistance between 27 and 86 % and a reduction of rise and fall times between 16 and 83 % with a load capacitance of 150 pF at various supply voltages, compared to previous work. The concept can be applied to each high-voltage driver that is based on a number (N) of stacked transistors. The high voltage compatibility of the low drop-out voltage regulator (LDO) is established by a 2-stacked pMOS transistors as pass device controlled by two regulators: an error amplifier and a 2nd amplifier adjusting the division of the voltages between the two pass transistors. A high GBW and good DC accuracy in line and load regulation is achieved by using 3-stage error amplifiers. To improve stability, two feedback loops are utilized. In this paper, the 2.5 V I/O transistors of the TSMC 65 nm CMOS technology are used for the circuit design.
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권승탁, 이계철, and 문하영. "Design of Voltage Regulator for Voltage Monitoring." Journal of the Korean Society of Mechanical Technology 15, no. 6 (December 2013): 981–86. http://dx.doi.org/10.17958/ksmt.15.6.201312.981.

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Zhang, Zonglu. "Design of alternating current voltage–regulating circuit based on thyristor: Comparison of single phase and three phase." Measurement and Control 53, no. 5-6 (March 19, 2020): 884–91. http://dx.doi.org/10.1177/0020294020909123.

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The voltage sag problem in a power grid can be solved by a voltage regulator. In this study, the voltage regulator based on thyristor was used to compensate the single-phase and three-phase voltage of voltage sag fault, so as to recover the normal level of voltage. The simulation analysis was carried out on MATLAB. The results showed that voltage sag faults mainly affected the amplitude of voltage, but not the frequency of voltage. After voltage regulation, the single-phase and three-phase voltage waveforms in the fault period had a certain recovery, but the voltage regulator had a certain hysteresis effect.
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Zong, Yong, Xia Xiao, and Rui Zhu. "The Test Investigation and Design Improvements of Voltage Regulator Performance." Applied Mechanics and Materials 701-702 (December 2014): 1181–86. http://dx.doi.org/10.4028/www.scientific.net/amm.701-702.1181.

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Voltage regulator is designed to automatically maintain the constant of regular voltage level. Every automotive IC has its own regulator module for analog and logic circuit power supply. The output load regulation and current consumption are directly related to the IC’s performance, or even the whole application module. The performance of regulator is not only related with the output parameters, but also the protection character. The over voltage protection feature guarantees the IC’s working environment within specific voltage input range. This article use one IDC’s (Intelligent Distribution Controller) regulator module to describe the design theory for regulator over voltage performance improvement. The test investigation and verification on ATE (Automatic Test Equipment) are demonstrated. The parameter of over voltage threshold is optimized obviously by 2% yield increasing.
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PUSHAN, KUMAR DATTA, and PATTNAIK BIRAJASHIS. "SIMULATION DESIGN OF AUTOMATIC VOLTAGE REGULATOR OVER UNAVAILABILITY OF ANALOG AUTOMATIC VOLTAGE REGULATOR." i-manager's Journal on Circuits and Systems 7, no. 2 (2019): 21. http://dx.doi.org/10.26634/jcir.7.2.16454.

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Dai, Wei Li, Yang Guang Yan, and Jun Tao Fei. "Dynamical Modeling, Simulation and Analysis for Voltage Regulation System of Hybrid Excitation Doubly Salient Generator." Advanced Materials Research 317-319 (August 2011): 2314–19. http://dx.doi.org/10.4028/www.scientific.net/amr.317-319.2314.

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Hybrid Excitation Doubly Salient Generator (HEDSG) with parallel magnetic circuits is performed in this paper, and the main flux in the machine is determined by the permanent magnet and the field coils. The structure and working principle of the generator are described in detail. In order to build the voltage regulation system of HEDSG, a bidirectional excitation voltage regulator is proposed, which could keep the output voltage of the generator stable by adjusting the field current. The two control loops including excitation current feed-forward and output voltage feedback loops are applied in the voltage regulator. Subsequently, the mathematical model of the voltage regulation system is constructed after the transfer function of the generator is obtained by using system identification method. Moreover, in order to realize the field current bidirectional flow, bipolar pulse width modulation is also applied in the regulator, and the control parameters influencing on the output voltage are analyzed. Lastly, the prototype of bidirectional excitation voltage regulator is designed and theoretical analysis and simulation results are verified by the stable and dynamic experiments.
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Dissertations / Theses on the topic "Voltage regulator"

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Zhou, Xunwei. "Low-voltage High-efficiency Fast-transient Voltage regulator Module." Diss., Virginia Tech, 1999. http://hdl.handle.net/10919/28832.

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In order to meet demands for faster and more efficient data processing, modern microprocessors are being designed with lower voltage implementations. The processor voltage supply in future generation processors will decrease to 1.1 V ~ 1.8V. More devices will be packed on a single processor chip, and processors will operate at higher frequencies, beyond 1GHz. Therefore, microprocessors need aggressive power management. Future generation processors will draw current up to 50 A ~ 100 A [2]. These demands, in turn, will require special power supplies and Voltage Regulator Modules (VRMs) to provide lower voltages with higher currents and fast transient capabilities for microprocessors. This work presents several low-voltage high-current VRM technologies for future generation data processing, communication, and portable applications. The developed advanced VRMs with these new technologies have advantages over conventional ones in power density, efficiency, transient response, reliability, and cost. The multi-module interleaved quasi-square-wave VRM topology achieves a very fast transient response and a very high power density. This topology significantly reduces the filter inductance and capacitance, while having small output and input ripples. The analysis, design, and experimental verification for this new topology are presented in this work. The current sensing and current sharing techniques are developed with simple and cost-effective implementations. With this technique, traditional current transformers and sensing resistors are not required, and the inductance value, MOSFET on resistance and other parasitics have no effect on current sharing results. The design principles are developed and experimentally verified. A generalized approach and an extension of the novel current sharing control are presented in this work. The techniques for improving VRM light load efficiency are developed in this work. By utilizing the duty cycle signal, VRMs can be implemented with advanced power management functions to reduce further the power consumption at light loads to extend the battery-operation time in portable systems or to facilitate the compliance with various "energy star" ("green" power) requirements in office systems. Four improved approaches are presented and verified with experimental results. The high-input-voltage VRM topology, push-pull forward converter, can be used in high-bus-voltage distributed power systems. This converter has a high efficiency, a high power density, a fast transient response, and can be easily packaged as a standard module. The circuit design and experimental evaluation are addressed to demonstrate the operation principles and advantages of this topology.
Ph. D.
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Park, Yongwan. "Fully Integrated Hybrid Voltage Regulator for Low Voltage Applications." Thesis, State University of New York at Stony Brook, 2016. http://pqdtopen.proquest.com/#viewpdf?dispub=10132969.

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A novel hybrid regulator topology is proposed to alleviate the weaknesses of existing hybrid topologies. Contrary to the dominant existing practice, a switched-capacitor converter and a resistorless LDO operate in a parallel fashion to supply current and regulate the output voltage. The proposed topology targets a fully integrated regulator without using any inductors and resistors. The primary emphasis is on maximizing power efficiency while maintaining sufficient regulation capability (with ripple voltage less than 10% of the output voltage) and power density. The first implementation of the proposed topology operates in a single frequency mode. Simulation results in 45 nm technology demonstrate a power efficiency of approximately 85% at 100 mA load current with an input and output voltage of, respectively, 1.15 V and 0.5 V. The worst case transient response time is under 20ns when the load current varies from 65 mA to 130 mA. The worst case ripple is 22 mV while achieving a power density of 0.5 W/mm2. This single-frequency hybrid voltage regulator is useful (due to its fast and continuous response and high power efficiency) when the output load current is relatively constant at a certain nominal value. However, the performance is degraded when the load current varies significantly beyond the nominal current since the current provided by switched-capacitor converter is constant. The second implementation of the proposed hybrid regulator topology partially alleviates this issue by employing two different frequencies depending on the load current. This design is also implemented in 45 nm technology. It is demonstrated that the power efficiency is maintained within 60% to 80% even though the load current varies by more than 100 mA. The power density remains the same (0.5 W/mm2). The simulation results of the proposed topology are highly competitive with recent work on integrated voltage regulators.

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Nghe, Brandon K. "Cascaded Linear Regulator with Positive Voltage Tracking Switching Regulator." DigitalCommons@CalPoly, 2020. https://digitalcommons.calpoly.edu/theses/2173.

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This thesis presents the design, simulation, and hardware implementation of a proposed method for improving efficiency of voltage regulator. Typically, voltage regulator used for noise-sensitive and low-power applications involves the use of a linear regulator due to its high power-supply rejection ratio properties. However, the efficiency of a linear regulator depends heavily on the difference between its input voltage and output voltage. A larger voltage difference across the linear regulator results in higher losses. Therefore, reducing the voltage difference is the key in increasing regulator’s efficiency. In this thesis, a pre switching regulator stage with positive voltage tracking cascaded to a linear regulator is proposed to provide an input voltage to a linear regulator that is slightly above the output of the linear regulator. The tracking capability is needed to provide the flexibility in having different positive output voltage levels while maintaining high overall regulator’s efficiency. Results from simulation and hardware implementation of the proposed system showed efficiency improvement of up to 23% in cases where an adjustable output voltage is necessary. Load regulation performance of the proposed method was also overall better compared to the case without the output voltage tracking method.
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Lei, Ernest. "Cascaded Linear Regulator with Negative Voltage Tracking Switching Regulator." DigitalCommons@CalPoly, 2020. https://digitalcommons.calpoly.edu/theses/2176.

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DC-DC converters can be separated into two main groups: switching converters and linear regulators. Linear regulators such as Low Dropout Regulators (LDOs) are straightforward to implement and have a very stable output with low voltage ripple. However, the efficiency of an LDO can fluctuate greatly, as the power dissipation is a function of the device’s input and output. On the other hand, a switching regulator uses a switch to regulate energy levels. These types of regulators are more versatile when a larger change of voltage is needed, as efficiency is relatively stable across larger steps of voltages. However, switching regulators tend to have a larger output voltage ripple, which can be an issue for sensitive systems. An approach to utilize both in cascaded configuration while providing a negative output voltage will be presented in this paper. The proposed two-stage conversion system consists of a switching pre-regulator that can track the negative output voltage of the second stage (LDO) such that the difference between input and output voltages is always kept small under varying output voltage while maintaining the high overall conversion efficiency. Computer simulation and hardware results demonstrate that the proposed system can track the negative output voltage well. Additionally, the results show that the proposed system can provide and maintain good overall efficiency, load regulation, and output voltage ripple across a wide range of outputs.
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Komark, Stina. "Design of an integrated voltage regulator." Thesis, Linköping University, Department of Electrical Engineering, 2003. http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-1711.

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Many analog systems need a stable power supply voltage that does not vary with temperature and time in order to operate properly. In a battery operated system the battery voltage is not stable, e.g. it decreases with decreasing temperature and with ageing. In that case a voltage regulator must be used, that regulates the battery voltage and generates a stable supply voltage to power other circuitry.

In this thesis a voltage regulator to be used in a battery operated system has been designed which meets the given specification of stability and power capabilities. A voltage reference, which is a commonly used devise in analog circuits, was also designed. The role of a reference voltage in an electrical system is the same as for a tuning fork in a musical ensemble; to set a standard to which other voltages are compared.

A functionality to detect when the lifetime of the battery is about to run out was also developed.

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Serdyn, J. J. "Electronic voltage regulator technology for rural electrification." Thesis, Link to the online version, 2008. http://hdl.handle.net/10019/903.

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Quintero, Francisco Javier 1955. "Analysis of an integrated voltage regulator amplifier and design alternatives." Thesis, The University of Arizona, 1988. http://hdl.handle.net/10150/276753.

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This Thesis Research involves the analysis, simulation and design alternatives for an industrially-relevant voltage regulator. An initial prototype circuit, designed by Texas Instruments Inc., is simulated and analysed in detail. Then an alternative circuit is derived which improves the circuit performance by implementing different compensation techniques and some transistors modifications. The final circuit has excellent phase margin, transient response and load regulation.
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Low, Aichen. "A floating-gate low dropout voltage regulator." Thesis, Georgia Institute of Technology, 2000. http://hdl.handle.net/1853/14886.

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Westlund, Arvid, and Oskar Bernberg. "Efficient Energy Transfer for Wireless Devices." Thesis, Uppsala universitet, Fasta tillståndets elektronik, 2012. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-177255.

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This project is intended to findsuitable circuit architecture forefficient power transmission where thepower supply is low.Two circuits will be built. The firstwill receive high AC which correspondsto the voltage created in a piezoelement once subjected to stress fromfoot steps It will deliver 3.3DC.The second circuit will receive low ACwhich will represent voltage receivedfrom a wireless transfer.Due to a failing high voltage powersupply the second circuit was never putto practice. The idea was to send a wavefile through an OP-amplifier to simulatethe voltage from the piezo element. Thevoltage was then rectified and convertedto 3.3DC.Circuit 2 was tested with a frequencygenerator as power supply. The voltagewas transformed, rectified and at lastconverted to 3.3DC through a voltageregulator. Due to lack of deliveredpower from the frequency generator itwas necessary to duty cycle the load tolimit the power dissipation.The power dissipation in the voltageregulator was limited as well byswitching it on and off. When switchedoff a capacitor was charged. When in onmode the capacitor was emptied into thevoltage regulator.
Det här projektet är ämnat att hittalämpliga kretsarkitetkturer för braeffektöverföring där energikällorna ärmycket begränsade.Två kretsar ska byggas. Den första skata emot hög växelspänning motsvarandespänningen som uppkommer i ettpiezoelement vilket utsätts för växlandetryck. I det här fallet trycket från enmänniskas fotsteg. Kretsen ska leverera3.3V likspänning.Den andra kretsen ska ta emot en lågväxelspänning, vilken motsvarar spänningfrån en trådlös överföring, och leverera3.3V.Krets 1 blev aldrig testad på grund avett fallerande högspänningsaggregat.Genom att skicka en wav-fil genom en OPförstärkareskulle en simulerad spänningfrån piezoelementet användas. Därefterskulle spänningen likriktas ochkonverteras ner till 3.3V.Krets 2 testades med en signalgeneratorsom spänningskälla. Spänningentransformerades först upp innan denlikriktades och skickades in i enspänningsreglator för att därefter ge ut3.3V. Med en liten levererad effekt frånsignalgeneratorn var det nödvändigt attbegränsa effektåtgången i lasten genompulsbreddmodulering. Effektåtgången ispänningsreglatorn begränsades ocksågenom att stänga av och på IC:n(spänningsregulatorn). När IC:n varavstängd laddades en kondensator upp somsedan tömdes i IC:n då den aktiveradesigen.
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Xiao, Shangyang. "TRANSIENT RESPONSE IMPROVEMENT FOR MULTI-PHASE VOLTAGE REGULATORS." Doctoral diss., University of Central Florida, 2008. http://digital.library.ucf.edu/cdm/ref/collection/ETD/id/3909.

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Next generation microprocessor (Vcore) requirements for high current slew rates and fast transient response together with low output voltage have posed great challenges on voltage regulator (VR) design . Since the debut of Intel 80X86 series, CPUs have greatly improved in performance with a dramatic increase on power consumption. According to the latest Intel VR11 design guidelines , the operational current may ramp up to 140A with typical voltages in the 1.1V to 1.4V range, while the slew rate of the transient current can be as high as 1.9A/ns [1, 2]. Meanwhile, the transient-response requirements are becoming stringer and stringer. This dissertation presents several topics on how to improve transient response for multi-phase voltage regulators. The Adaptive Modulation Control (AMC) is a type of non-linear control method which has proven to be effective in achieving high bandwidth designs as well as stabilizing the control loop during large load transients. It adaptively adjusts control bandwidth by changing the modulation gain, depending on different load conditions. With the AMC, a multiphase voltage regulator can be designed with an aggressively high bandwidth. When in heavy load transients where the loop could be potentially unstable, the bandwidth is lowered. Therefore, the AMC provides an optimal means for robust high-bandwidth design with excellent transient performance. The Error Amplifier Voltage Positioning (EAVP) is proposed to improve transient response by removing undesired spikes and dips after initial transient response. The EAVP works only in a short period of time during transient events without modifying the power stage and changing the control loop gain. It facilitates the error amplifier voltage recovering during transient events, achieving a fast settling time without impact on the whole control loop. Coupled inductors are an emerging topology for computing power supplies as VRs with coupled inductors show dynamic and steady-state advantages over traditional VRs. This dissertation first covers the coupling mechanism in terms of both electrical and reluctance modeling. Since the magnetizing inductance plays an important role in the coupled-inductor operation, a unified State-Space Averaging model is then built for a two-phase coupled-inductor voltage regulator. The DC solutions of the phase currents are derived in order to show the impact of the magnetizing inductance on phase current balancing. A small signal model is obtained based on the state-space-averaging model. The effects of magnetizing inductance on dynamic performance are presented. The limitations of conventional DCR current-sensing for coupled inductors are addressed. Traditional inductor DCR current sensing topology and prior arts fail to extract phase currents for coupled inductors. Two new DCR current sensing topologies for coupled inductors are presented in this dissertation. By implementation of simple RC networks, the proposed topologies can preserve the coupling effect between phases. As a result, accurate phase inductor currents and total current can be sensed, resulting in excellent current and voltage regulation. While coupled-inductor topologies are showing advantages in transient response and are becoming industry practices, they are suffering from low steady-state operating efficiency. Motivated by the challenging transient and efficiency requirements, this dissertation proposes a Full Bridge Coupled Inductor (FBCI) scheme which is able to improve transient response as well as savor high efficiency at (a) steady state. The FBCI can change the circuit configuration under different operational conditions. Its "flexible" topology is able to optimize both transient response and steady-state efficiency. The flexible core configuration makes implementation easy and clear of IP issues. A novel design methodology for planar magnetics based on numerical analysis of electromagnetic fields is offered and successfully applied to the design of low-voltage high power density dc-dc converters. The design methodology features intense use of FEM simulation. The design issues of planar magnetics, including loss mechanism in copper and core, winding design on PCB, core selections, winding arrangements and so on are first reviewed. After that, FEM simulators are introduced to numerically compute the core loss and winding loss. Consequently, a software platform for magnetics design is established, and optimized magnetics can then be achieved. Dynamic voltage scaling (DVS) technology is a common industry practice in optimizing power consumption of microprocessors by dynamically altering the supply voltage under different operational modes, while maintaining the performance requirements. During DVS operation, it is desirable to position the output voltage to a new level commanded by the microprocessor (CPU) with minimum delay. However, voltage deviation and slow settling time usually exist due to large output capacitance and compensation delay in voltage regulators. Although optimal DVS can be achieved by modifying the output capacitance and compensation, this method is limited by constraints from stringent static and dynamic requirements. In this dissertation, the effects of output capacitance and compensation network on DVS operation are discussed in detail. An active compensator scheme is then proposed to ensure smooth transition of the output voltage without change of power stage and compensation during DVS. Simulation and experimental results are included to demonstrate the effectiveness of the proposed scheme.
Ph.D.
School of Electrical Engineering and Computer Science
Engineering and Computer Science
Electrical Engineering PhD
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Books on the topic "Voltage regulator"

1

Toshiba. Voltage Regulator. [Japan]: Toshiba, 1994.

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Voltage regulator circuit manual. San Diego: Academic Press, 1989.

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Shusterman, Dmitry. Keswick Powerplant voltage regulator commissioning. Denver, Colo: U.S. Bureau of Reclamation, 1992.

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Agee, J. C. Keswick Powerplant Unit 1 excitation system commissioning. Denver, Colo: Electric Power Branch, Research and Laboratory Services Division, Denver Office, U.S. Dept. of the Interior, Bureau of Reclamation, 1990.

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Venikov, V. A. Regulirovanie napri͡a︡zhenii͡a︡ v ėlektroėnergeticheskikh sistemakh. Moskva: Ėnergoatomizdat, 1985.

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Borisov, V. P. Stabilizatory napri͡a︡zhenii͡a︡ s perekli͡u︡chaemymi regulirui͡u︡shchimi ėlementami. Moskva: Ėnergoatomizdat, 1985.

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Sarv, V. V. Ventilʹnye t͡s︡epi regulirovanii͡a︡ napri͡a︡zhenii͡a︡ s upravli͡a︡emym mezhfaznym ėnergoobmenom. Tallinn: "Valgus", 1986.

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Milovzorov, V. P. Diskretnye stabilizatory i formirovateli napri͡a︡zhenii͡a︡. Moskva: Ėnergoatomizdat, 1986.

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K, Shakhov Ė. Integrirui͡u︡shchie razvertyvai͡u︡shchie preobrazovateli napri͡a︡zhenii͡a︡. Moskva: Ėnergoatomizdat, 1986.

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López, Toni. Voltage regulators for next generation microprocessors. New York: Springer, 2011.

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Book chapters on the topic "Voltage regulator"

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P.-Vaisband, Inna, Renatas Jakushokas, Mikhail Popovich, Andrey V. Mezhiba, Selçuk Köse, and Eby G. Friedman. "Hybrid Voltage Regulator." In On-Chip Power Delivery and Management, 277–92. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-29395-0_17.

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Snell, E. J. "Voltage regulator performance." In Applied Statistics, 115–20. Dordrecht: Springer Netherlands, 1987. http://dx.doi.org/10.1007/978-94-011-6946-2_22.

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Kilani, Dima, Baker Mohammad, Mohammad Alhawari, Hani Saleh, and Mohammed Ismail. "Dual-Outputs Switched Capacitor Voltage Regulator." In Analog Circuits and Signal Processing, 47–71. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-37884-4_4.

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Pota, Hemanshu Roy. "Design of the Automatic Voltage Regulator." In The Essentials of Power System Dynamics and Control, 155–72. Singapore: Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-10-8914-5_4.

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Bianchi, Andrea, and Davide Martini. "Voltage Regulator for Single-Phase Asynchronous Motor." In Energy Efficiency in Household Appliances and Lighting, 247–55. Berlin, Heidelberg: Springer Berlin Heidelberg, 2001. http://dx.doi.org/10.1007/978-3-642-56531-1_30.

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Agarwal, Gopal, and Ved Vyas Dwivedi. "Low Power, Low Voltage, Low Drop-Out On-chip Voltage Regulator." In Advances in Intelligent Systems and Computing, 335–44. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-4851-2_35.

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Tomar, G. S., and Ashish Bagwari. "OP-AMP Applications, Timer, Voltage Regulator, and Converter." In Algorithms for Intelligent Systems, 157–90. Singapore: Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-15-0267-5_6.

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Vinayramsatish, Garapati, K. R. M. Vijaya Chandrakala, and S. Sampath Kumar. "Standalone Solar Photovoltaic Fed Automatic Voltage Regulator for Voltage Control of Synchronous Generator." In Advances in Intelligent Systems and Computing, 991–1001. Singapore: Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-15-0035-0_79.

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Chaniyara, Piyushkumar M. "Design of Low Voltage LDO Voltage Regulator for Battery Operated Wireless Sensor Nodes." In Communications in Computer and Information Science, 242–54. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-16-5048-2_19.

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Kiran, Hotha Uday, and Sharad Kumar Tiwari. "Hybrid BF-PSO Algorithm for Automatic Voltage Regulator System." In Advances in Intelligent Systems and Computing, 145–53. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-5148-2_13.

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Conference papers on the topic "Voltage regulator"

1

Bose, Manisha M., and Shafeeque K. Muhammedali. "Series Voltage Regulator to Regulate Voltage at Distribution Side." In 2018 International Conference on Inventive Research in Computing Applications (ICIRCA). IEEE, 2018. http://dx.doi.org/10.1109/icirca.2018.8597207.

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Patil, Priyanka Madanrao, and Dr S. K. Patil. "Automatic Voltage Regulator." In 2020 International Conference on Emerging Trends in Information Technology and Engineering (ic-ETITE). IEEE, 2020. http://dx.doi.org/10.1109/ic-etite47903.2020.476.

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Prasad, Hanuman, Vipin Kumar Singh, and Tanmoy Maity. "Transformer less voltage regulator." In 2014 International Conference on Green Computing Communication and Electrical Engineering (ICGCCEE). IEEE, 2014. http://dx.doi.org/10.1109/icgccee.2014.6922384.

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Sosnina, Elena, Alexey Kralin, Evgeny Kryukov, and Rustam Bedretdinov. "Research of Thyristor Voltage Regulator Characteristics in Transverse Output Voltage Regulation Mode." In 2020 IEEE PES Innovative Smart Grid Technologies Europe (ISGT-Europe). IEEE, 2020. http://dx.doi.org/10.1109/isgt-europe47291.2020.9248854.

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Tomlinson, Males, Dewald Abrie, and Toit Mouton. "Series-stacked medium voltage electronic voltage regulator." In 2011 IEEE Energy Conversion Congress and Exposition (ECCE). IEEE, 2011. http://dx.doi.org/10.1109/ecce.2011.6063895.

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Sidorov, Andrey V., and Gennady S. Zinoviev. "AC voltage regulator on the basis of the consecutive voltage regulator with PWM." In 2013 International Conference of Young Specialists on Micro/Nanotechnologies and Electron Devices (EDM). IEEE, 2013. http://dx.doi.org/10.1109/edm.2013.6642016.

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Vazquez, N., A. Velazquez, C. Hernandez, E. Rodriguez, and R. Oroso. "A fast ac voltage regulator." In 2008 IEEE International Power Electronics Congress - CIEP. IEEE, 2008. http://dx.doi.org/10.1109/ciep.2008.4653834.

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Crepaldi, Paulo, Tales Pimenta, Robson Moreno, and Edgard Charry Rodriguez. "An unconditionally stable Voltage Regulator." In APCCAS 2010-2010 IEEE Asia Pacific Conference on Circuits and Systems. IEEE, 2010. http://dx.doi.org/10.1109/apccas.2010.5774858.

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Hasler, P., and Ai Chen Low. "Programmable low dropout voltage regulator." In Fifth International Workshop on System-on-Chip for Real-Time Applications (IWSOC'05). IEEE, 2005. http://dx.doi.org/10.1109/iwsoc.2005.95.

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Wang, Hsi-Jui, and Le-Ren Chang-Chien. "Low cross regulation voltage-mode controlled single-inductor dual-outputs (SIDO) voltage regulator." In 2013 1st International Future Energy Electronics Conference (IFEEC). IEEE, 2013. http://dx.doi.org/10.1109/ifeec.2013.6687495.

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Reports on the topic "Voltage regulator"

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Divan, Deepak, Rohit Moghe, and Damien Tholomier. Fast Responding Voltage Regulator and Dynamic VAR Compensator. Office of Scientific and Technical Information (OSTI), December 2014. http://dx.doi.org/10.2172/1253158.

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Nagarajan, Adarsh, Michael H. Coddington, David Brown, Sheikh Hassan, Leonardo Franciosa, and Elaine Sison-Lebrilla. Studies on the Effects of High Renewable Penetrations on Driving Point Impedance and Voltage Regulator Performance: National Renewable Energy Laboratory/Sacramento Municipal Utility District Load Tap Changer Driving Point Impedance Project. Office of Scientific and Technical Information (OSTI), January 2018. http://dx.doi.org/10.2172/1417730.

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Treistman, Steven N. Regulation of Voltage-Dependent Channel Function. Fort Belvoir, VA: Defense Technical Information Center, August 1988. http://dx.doi.org/10.21236/ada200375.

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Zhang S. Y. and A. Soukas. BOOSTER DIPOLE and QUADRUPOLE VOLTAGE REGULATION LOOP. Office of Scientific and Technical Information (OSTI), May 1989. http://dx.doi.org/10.2172/1150518.

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Davis, M. W., R. Broadwater, and J. Hambrick. Modeling and Testing of Unbalanced Loading and Voltage Regulation. Office of Scientific and Technical Information (OSTI), July 2007. http://dx.doi.org/10.2172/912489.

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Garrett, D., T. Sims, R. Jones, and S. Jeter. PVREG - A photovoltaic voltage regulation investigation tool: Program reference manual. Office of Scientific and Technical Information (OSTI), June 1989. http://dx.doi.org/10.2172/6014064.

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Garrett, D., T. Sims, S. Jeter, and R. Jones. PVREG -- a photovoltaic voltage regulation investigation tool: PVREG user's manual. Office of Scientific and Technical Information (OSTI), June 1989. http://dx.doi.org/10.2172/6265002.

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Johnson, Jay Tillay, Adam Summers, Rachid Darbali-Zamora, Clifford Hansen, Matthew J. Reno, Anya Castillo, Sigifredo Gonzalez, et al. Optimal Distribution System Voltage Regulation using State Estimation and DER Grid-Support Functions. Office of Scientific and Technical Information (OSTI), February 2020. http://dx.doi.org/10.2172/1638511.

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Sereno, N. S. APS linac klystron and accelerating structure gain measurements and klystron PFN voltage regulation requirements. Office of Scientific and Technical Information (OSTI), July 1997. http://dx.doi.org/10.2172/501502.

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Bernardin, J. D., and E. Bosze. An experimental investigation of a liquid cooling scheme for the low dropout voltage regulators of the multiplicity and vertex detector. Office of Scientific and Technical Information (OSTI), October 1997. http://dx.doi.org/10.2172/563290.

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