• Refine Query
  • Source
  • Publication year
  • to
  • Language
  • 8
  • 2
  • 2
  • 1
  • Tagged with
  • 16
  • 16
  • 16
  • 14
  • 12
  • 11
  • 7
  • 7
  • 7
  • 5
  • 5
  • 4
  • 4
  • 4
  • 4
  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
11

Estudo do Conversor Bosst CC-CC de Alto Ganho de TensÃo Baseado na CÃlula de ComutaÃÃo de TrÃs Estados e nas CÃlulas Multiplicadoras de TensÃo (mc). / Study of the High Voltage Gain Boost Converter Based on Three-State Switching Cell and Voltage Multipliers Cells (mc).

Yblin Janeth Acosta Alcazar 14 December 2010 (has links)
nÃo hà / O presente trabalho propÃe o estudo do conversor boost CC-CC de alto ganho de tensÃo baseado na cÃlula de comutaÃÃo de trÃs estados e nas cÃlulas multiplicadoras de tensÃo (mc). Este trabalho investiga um modelo matemÃtico para o citado conversor. A anÃlise proposta à baseada na ferramenta âmodelagem do interruptor PWM para conversores CC-CCâ. O modelo deve ser encontrado por uma simples inspeÃÃo do circuito do conversor. Deve ser possÃvel aplicÃ-lo para realizar diversas anÃlises, como em regime permanente, regime transitÃria e anÃlise de pequenos sinais por meio de um uma abordagem unificada. Considerando um dado nÃmero de cÃlulas multiplicadoras de tensÃo, duas situaÃÃes sÃo analisadas com esta ferramenta: operaÃÃo com uma Ãnica cÃlula multiplicadora de tensÃo (mc=1) e vÃrias cÃlulas multiplicadoras de tensÃo (mc> 1). O mÃtodo proposto à validado por simulaÃÃes e à verificada sua efetividade. AlÃm disso, à analisado neste trabalho o controle modo corrente mÃdia convencional, o qual à aplicado em uma das configuraÃÃes em estudo. O rendimento do conversor e a efetividade do controlador proposto sÃo demonstrados por resultados experimentais para um protÃtipo do laboratÃrio de 1 kW. / The present work proposes the study of the boost converter based on three-state switching cell and voltage multipliers cells (mc). A mathematical model of the aforementioned converter is investigated here. The proposed analysis is based on the tool named âPWM-Switch Modeling of DC-DC Convertersâ. The model must be found by a simple inspection of the converterâs circuit. It is possible to apply such model in order to realize various analyses such as steady-state, transient, and small-signal analysis in a single and same model. Considering the number of voltage multipliers cells (mc), two situations are analyzed: operation with a single multiplier cell (mc=1) and operation with multiple voltage multiplier cells (mc>1).The proposed method was validated through simulations and its effectiveness was verified. In addition to this, conventional average current mode control is also applied to one of the studied configurations. The performance of the converter and the effectiveness of the proposed controller are demonstrated by experimental results obtained from a 1-kW laboratory prototype.
12

Average Current-Mode Control

Chadha, Ankit January 2015 (has links)
No description available.
13

True-Average Current-Mode Control of DC-DC Power Converters: Analysis, Design, andCharacterization

Saini, Dalvir K. 02 August 2018 (has links)
No description available.
14

Characterization and Design of Voltage-Mode Controlled Full-Bridge DC/DC Converter with Current Limit

Smith, Nathaniel R. 08 June 2018 (has links)
No description available.
15

Design and Practical Implementation of Advanced Reconfigurable Digital Controllers for Low-power Multi-phase DC-DC Converters

Lukic, Zdravko 06 December 2012 (has links)
The main goal of this thesis is to develop practical digital controller architectures for multi-phase dc-dc converters utilized in low power (up to few hundred watts) and cost-sensitive applications. The proposed controllers are suitable for on-chip integration while being capable of providing advanced features, such as dynamic efficiency optimization, inductor current estimation, converter component identification, as well as combined dynamic current sharing and fast transient response. The first part of this thesis addresses challenges related to the practical implementation of digital controllers for low-power multi-phase dc-dc converters. As a possible solution, a multi-use high-frequency digital PWM controller IC that can regulate up to four switching converters (either interleaved or standalone) is presented. Due to its configurability, low current consumption (90.25 μA/MHz per phase), fault-tolerant work, and ability to operate at high switching frequencies (programmable, up to 10 MHz), the IC is suitable to control various dc-dc converters. The applications range from dc-dc converters used in miniature battery-powered electronic devices consuming a fraction of watt to multi-phase dedicated supplies for communication systems, consuming hundreds of watts. A controller for multi-phase converters with unequal current sharing is introduced and an efficiency optimization method based on logarithmic current sharing is proposed in the second part. By forcing converters to operate at their peak efficiencies and dynamically adjusting the number of active converter phases based on the output load current, a significant improvement in efficiency over the full range of operation is obtained (up to 25%). The stability and inductor current transition problems related to this mode of operation are also resolved. At last, two reconfigurable digital controller architectures with multi-parameter estimation are introduced. Both controllers eliminate the need for external analog current/temperature sensing circuits by accurately estimating phase inductor currents and identifying critical phase parameters such as equivalent resistances, inductances and output capacitance. A sensorless non-linear, average current-mode controller is introduced to provide fast transient response (under 5 μs), small voltage deviation and dynamic current sharing with multi-phase converters. To equalize the thermal stress of phase components, a conduction loss-based current sharing scheme is proposed and implemented.
16

Design and Practical Implementation of Advanced Reconfigurable Digital Controllers for Low-power Multi-phase DC-DC Converters

Lukic, Zdravko 06 December 2012 (has links)
The main goal of this thesis is to develop practical digital controller architectures for multi-phase dc-dc converters utilized in low power (up to few hundred watts) and cost-sensitive applications. The proposed controllers are suitable for on-chip integration while being capable of providing advanced features, such as dynamic efficiency optimization, inductor current estimation, converter component identification, as well as combined dynamic current sharing and fast transient response. The first part of this thesis addresses challenges related to the practical implementation of digital controllers for low-power multi-phase dc-dc converters. As a possible solution, a multi-use high-frequency digital PWM controller IC that can regulate up to four switching converters (either interleaved or standalone) is presented. Due to its configurability, low current consumption (90.25 μA/MHz per phase), fault-tolerant work, and ability to operate at high switching frequencies (programmable, up to 10 MHz), the IC is suitable to control various dc-dc converters. The applications range from dc-dc converters used in miniature battery-powered electronic devices consuming a fraction of watt to multi-phase dedicated supplies for communication systems, consuming hundreds of watts. A controller for multi-phase converters with unequal current sharing is introduced and an efficiency optimization method based on logarithmic current sharing is proposed in the second part. By forcing converters to operate at their peak efficiencies and dynamically adjusting the number of active converter phases based on the output load current, a significant improvement in efficiency over the full range of operation is obtained (up to 25%). The stability and inductor current transition problems related to this mode of operation are also resolved. At last, two reconfigurable digital controller architectures with multi-parameter estimation are introduced. Both controllers eliminate the need for external analog current/temperature sensing circuits by accurately estimating phase inductor currents and identifying critical phase parameters such as equivalent resistances, inductances and output capacitance. A sensorless non-linear, average current-mode controller is introduced to provide fast transient response (under 5 μs), small voltage deviation and dynamic current sharing with multi-phase converters. To equalize the thermal stress of phase components, a conduction loss-based current sharing scheme is proposed and implemented.

Page generated in 0.1026 seconds