## Fundamentals of power electronics Erickson solution Book Pdf

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### Index of the Fundamental Of power electronic by erickson

Chapter1: Introduction

1.1. Introduction to power processing

1.2. Some applications of power electronics

1.3. Elements of power electronics

Summary of the course

Chapter 2

Principles of Steady-State Converter Analysis

2.1. Introduction

2.2. Inductor volt-second balance, capacitor charge

balance, and the small ripple approximation

2.3. Boost converter example

2.4. Cuk converter example

2.5. Estimating the ripple in converters containing twopole low-pass filters

2.6. Summary of key points

Principles of Steady-State Converter Analysis

2.1. Introduction

2.2. Inductor volt-second balance, capacitor charge

balance, and the small ripple approximation

2.3. Boost converter example

2.4. Cuk converter example

2.5. Estimating the ripple in converters containing twopole low-pass filters

2.6. Summary of key points

Chapter 3. Steady-State Equivalent Circuit

Modeling, Losses, and Efficiency

3.1. The dc transformer model

3.2. Inclusion of inductor copper loss

3.3. Construction of equivalent circuit model

3.4. How to obtain the input port of the model

3.5. Example: inclusion of semiconductor conduction

losses in the boost converter model

3.6. Summary of key pointsChapter

4. Switch Realization

4.1. Switch applications

Single-, two-, and four-quadrant switches. Synchronous rectifiers

4.2. A brief survey of power semiconductor devices

Power diodes, MOSFETs, BJTs, IGBTs, and thyristors

4.3. Switching loss

Transistor switching with clamped inductive load. Diode

recovered charge. Stray capacitances and inductances, and

ringing. Efficiency vs. switching frequency.

4.4. Summary of key pointsIntroduction to

Discontinuous Conduction Mode (DCM)

●Occurs because switching ripple in inductor current or capacitor voltage

causes polarity of applied switch current or voltage to reverse, such

that the current- or voltage-unidirectional assumptions made in realizing

the switch are violated.

●Commonly occurs in dc-dc converters and rectifiers, having singlequadrant switches. May also occur in converters having two-quadrant

switches.

●Typical example: dc-dc converter operating at light load (small load

current). Sometimes, dc-dc converters and rectifiers are purposely

designed to operate in DCM at all loads.

●Properties of converters change radically when DCM is entered:

Output impedance is increased

Dynamics are altered

Control of output voltage may be lost when load is removed

Modeling, Losses, and Efficiency

3.1. The dc transformer model

3.2. Inclusion of inductor copper loss

3.3. Construction of equivalent circuit model

3.4. How to obtain the input port of the model

3.5. Example: inclusion of semiconductor conduction

losses in the boost converter model

3.6. Summary of key pointsChapter

4. Switch Realization

4.1. Switch applications

Single-, two-, and four-quadrant switches. Synchronous rectifiers

4.2. A brief survey of power semiconductor devices

Power diodes, MOSFETs, BJTs, IGBTs, and thyristors

4.3. Switching loss

Transistor switching with clamped inductive load. Diode

recovered charge. Stray capacitances and inductances, and

ringing. Efficiency vs. switching frequency.

4.4. Summary of key pointsIntroduction to

Discontinuous Conduction Mode (DCM)

●Occurs because switching ripple in inductor current or capacitor voltage

causes polarity of applied switch current or voltage to reverse, such

that the current- or voltage-unidirectional assumptions made in realizing

the switch are violated.

●Commonly occurs in dc-dc converters and rectifiers, having singlequadrant switches. May also occur in converters having two-quadrant

switches.

●Typical example: dc-dc converter operating at light load (small load

current). Sometimes, dc-dc converters and rectifiers are purposely

designed to operate in DCM at all loads.

●Properties of converters change radically when DCM is entered:

*M*becomes load-dependentOutput impedance is increased

Dynamics are altered

Control of output voltage may be lost when load is removed

Chapter 6. Converter Circuits

6.1. Circuit manipulations

6.2. A short list of

converters

6.3. Transformer isolation

6.4. Converter evaluation

and design

6.5. Summary of key

points

• Where do the boost,

buck-boost, and other

converters originate?

• How can we obtain a

converter having given

desired properties?

• What converters are

possible?

• How can we obtain

transformer isolation in a

converter?

• For a given application,

which converter is best?

Chapter 7. AC Equivalent Circuit Modeling

7.1. Introduction

7.2. The basic ac modeling approach

7.3. Example: A nonideal flyback converter

7.4. State-space averaging

7.5. Circuit averaging and averaged switch modeling

7.6. The canonical circuit model

7.7. Modeling the pulse-width modulator

7.8. Summary of key points

Chapter 8. Converter Transfer Functions

8.1. Review of Bode plots

8.1.1. Single pole response

8.1.2. Single zero response

8.1.3. Right half-plane zero

8.1.4. Frequency inversion

8.1.5. Combinations

8.1.6. Double pole response: resonance

8.1.7. The low-Q approximation

8.1.8. Approximate roots of an arbitrary-degree polynomial

8.2. Analysis of converter transfer functions

8.2.1. Example: transfer functions of the buck-boost converter

8.2.2. Transfer functions of some basic CCM converters

......

Chapter 20

Quasi-Resonant Converters

Introduction

20.1 The zero-current-switching quasi-resonant switch cell

20.1.1 Waveforms of the half-wave ZCS quasi-resonant switch cell

20.1.2 The average terminal waveforms

20.1.3 The full-wave ZCS quasi-resonant switch cell

20.2 Resonant switch topologies

20.2.1 The zero-voltage-switching quasi-resonant switch

20.2.2 The zero-voltage-switching multiresonant switch

20.2.3 Quasi-square-wave resonant switches

20.3 Ac modeling of quasi-resonant converters

20.4 Summary of key points

Quasi-Resonant Converters

Introduction

20.1 The zero-current-switching quasi-resonant switch cell

20.1.1 Waveforms of the half-wave ZCS quasi-resonant switch cell

20.1.2 The average terminal waveforms

20.1.3 The full-wave ZCS quasi-resonant switch cell

20.2 Resonant switch topologies

20.2.1 The zero-voltage-switching quasi-resonant switch

20.2.2 The zero-voltage-switching multiresonant switch

20.2.3 Quasi-square-wave resonant switches

20.3 Ac modeling of quasi-resonant converters

20.4 Summary of key points

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