Chichester, England : , : Wiley, , 2016

©2016

1-119-05375-7

1-119-05275-0

1 online resource (268 p.)

621.381534

Pulse circuits

DC-to-DC converters

PWM power converters

Electronic books.

Inglese

Includes index.

Laboratory Manual for Pulse-Width Modulated DC-DC Power Converters; Contents; Preface; For Instructors; For Students; Acknowledgments; List of Symbols; Part I Open-Loop Pulse-Width Modulated DC-DC Converters-Steady-State and Performance Analysis and Simulation of Converter Topologies; 1 Boost DC-DC Converter in CCM-Steady-State Simulation; Objectives; Specifications; Pre-lab; Quick Design; Procedure; A. Simulation of the Boost Converter and its Analysis in Steady State; B. Simulation of the Boost Converter to Determine the Power Losses and Overall Efficiency; Postlab Questions

2 Efficiency and DC Voltage Transfer Function of PWM Boost DC-DC Converter in CCMObjectives; Theory; Specifications; Pre-lab; Quick Design; Procedure; A. Efficiency as a Function of the Input Voltage at Full and Light Load Conditions; B. Efficiency as a Function of the Output Current at Minimum, Nominal, and Maximum Input Voltages; C. DC Voltage Transfer Function as a Function of the Duty Cycle; Post-lab Questions; 3 Boost DC-DC Converter in DCM-Steady-State Simulation; Objectives; Specifications; Pre-lab; Quick Design; Procedure

A. Simulation of the Boost Converter and its Analysis in Steady State B.

Simulation of the Boost Converter to Determine the Power Losses and Overall Efficiency; Post-lab Questions; 4 Efficiency and DC Voltage Transfer Function of PWM Boost DC-DC Converter in DCM; Objectives; Theory; Specifications; Pre-lab; Quick Design; Procedure; A. Efficiency as a Function of the Input Voltage at Various Load Conditions; B. Efficiency as a Function of the Output Current at Minimum, Nominal, and Maximum Input Voltages; C. DC Voltage Transfer Function as a Function of the Duty Cycle; Post-lab Questions

5 Open-Loop Boost AC-DC Power Factor Corrector-Steady-State Simulation Objectives; Specifications; Pre-lab; Quick Design; Procedure; A. Simulation of the Boost Converter as a Power Factor Corrector; B. Simulation of the Boost Converter as a Peak Rectifier Circuit; Post-lab Questions; 6 Buck DC-DC Converter in CCM-Steady-State Simulation; Objectives; Specifications; Pre-lab; Quick Design; Procedure; A. Simulation of the Buck Converter and its Analysis in Steady State; B. Simulation of the Buck Converter to Determine the Power Losses and Overall Efficiency; Post-lab Questions

7 Efficiency and DC Voltage Transfer Function of PWM Buck DC-DC Converter in CCM Objectives; Theory; Specifications; Pre-lab; Quick Design; Procedure; A. Efficiency of the Buck Converter as a Function of the Input Voltage at Full and Light Load Conditions; B. Efficiency of the Buck Converter as a Function of the Output Current at Minimum, Nominal, and Maximum Input Voltages; C. DC Voltage Transfer Function of the Buck Converter as a Function of the Duty Cycle; Post-lab Questions; 8 Buck DC-DC Converter in DCM-Steady-State Simulation; Objectives; Specifications; Pre-lab; Quick Design; Procedure

A. Simulation of the Buck Converter in DCM and its Analysis in Steady State

Designed to complement a range of power electronics study resources, this unique lab manual helps students to gain a deep understanding of the operation, modeling, analysis, design, and performance of pulse-width modulated (PWM) DC-DC power converters. Exercises focus on three essential areas of power electronics: open-loop power stages; small-signal modeling, design of feedback loops and PWM DC-DC converter control schemes; and semiconductor devices such as silicon, silicon carbide and gallium nitride.   Meeting the standards required by industrial employers, the lab manual combines program