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Lecture 5: Semiconductor Device Implementation ECE 481: Power Electronics Prof. Daniel Costinett Department of Electrical Engineering and Computer Science University of Tennessee Knoxville Fall 2013

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Page 1: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent

Lecture 5: Semiconductor Device Implementation

ECE 481: Power ElectronicsProf. Daniel Costinett

Department of Electrical Engineering and Computer Science

University of Tennessee Knoxville

Fall 2013

Page 2: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 3: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 4: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 5: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 6: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 7: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 8: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 9: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 10: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 11: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 12: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 13: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 14: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 15: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 16: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 17: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent
Page 18: Lecture 5: Semiconductor Device Implementationweb.eecs.utk.edu/~dcostine/ECE481/fall2013/lectures/L5_slides.pdf · Fundamentals of power Electronics 33 Chapter 3: Steady-state equivalent

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