Designing Control Loops for Linear and Switching Power Supplies : a Tutorial Guide |
Autore | Basso Christophe P. |
Pubbl/distr/stampa | Norwood : , : Artech House, , 2012 |
Descrizione fisica | 1 online resource (613 p.) |
Disciplina | 613 |
Soggetto topico |
Switching power supplies - Design and construction
Process control Power electronics Feedback control systems Electric current converters |
Soggetto genere / forma | Electronic books. |
ISBN | 1-60807-558-3 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Designing Control Loops for Linear and Switching Power Supplies: A Tutorial Guide; Contents; Foreword; Preface; Acknowledgments; Chapter 1 Basics of Loop Control; 1.1 Open-Loop Systems; 1.1.1 Perturbations; 1.2 The Necessity of Control-Closed-Loop Systems; 1.3 Notions of Time Constants; 1.3.1 Working with Time Constants; 1.3.2 The Proportional Term; 1.3.3 The Derivative Term; 1.3.4 The Integral Term; 1.3.5 Combining the Factors; 1.4 Performance of a Feedback Control System; 1.4.1 Transient or Steady State?; 1.4.2 The Step; 1.4.3 The Sinusoidal Sweep; 1.4.4 The Bode Plot.
1.5 Transfer Functions1.5.1 The Laplace Transform; 1.5.2 Excitation and Response Signals; 1.5.3 A Quick Example; 1.5.4 Combining Transfer Functions with Bode Plots; 1.6 Conclusion; Selected Bibliography; Chapter 2 Transfer Functions; 2.1 Expressing Transfer Functions; 2.1.1 Writing Transfer Functions the Right Way; 2.1.2 The 0-db Crossover Pole; 2.2 Solving for the Roots; 2.2.1 Poles and Zeros Found by Inspection; 2.2.2 Poles, Zeros, and Time Constants; 2.3 Transient Response and Roots; 2.3.1 When the Roots Are Moving; 2.4 S-Plane and Transient Response. 2.4.1 Roots Trajectories in the Complex Plane2.5 Zeros in the Right Half Plane; 2.5.1 A Two-Step Conversion Process; 2.5.2 The Inductor Current Slew-Rate Is the Limit; 2.5.3 An Average Model to Visualize Rhp Zero Effects; 2.5.4 The Right Half Plane Zero in the Boost Converter; 2.6 Conclusion; References; Appendix 2A: Determining a Bridge Input Impedance; Reference; Appendix 2B: Plotting Evans Loci with Mathcad; Appendix 2C: Heaviside Expansion Formulas; Reference; Appendix 2D: Plotting a Right Half Plane Zero with Spice; Chapter 3 Stability Criteria of a Control System. 3.1 Building An Oscillator3.1.1 Theory at Work; 3.2 Stability Criteria; 3.2.1 Gain Margin and Conditional Stability; 3.2.2 Minimum Versus Nonminimum-Phase Functions; 3.2.3 Nyquist Plots; 3.2.4 Extracting the Basic Information from the Nyquist Plot; 3.2.5 Modulus Margin; 3.3 Transient Response, Quality Factor, and Phase Margin; 3.3.1 A Second-Order System, the Rlc Circuit; 3.3.2 Transient Response of a Second-Order System; 3.3.4 Opening the Loop to Measure the Phase Margin; 3.3.5 The Phase Margin of a Switching Converter; 3.3.6 Considering a Delay in the Conversion Process. 3.3.7 The Delay in the Laplace Domain3.3.8 Delay Margin versus Phase Margin; 3.4 Selecting the Crossover Frequency; 3.4.1 A Simplified Buck Converter; 3.4.2 The Output Impedance in Closed-Loop Conditions; 3.4.3 The Closed-Loop Output Impedance at Crossover; 3.4.4 Scaling the Reference to Obtain the Desired Output; 3.4.5 Increasing the Crossover Frequency Further; 3.5 Conclusion; References; Chapter 4 Compensation; 4.1 The Pid Compensator; 4.1.1 The Pid Expressions in the Laplace Domain; 4.1.2 Practical Implementation of a Pid Compensator; 4.1.3 Practical Implementation of a Pi Compensator. 4.1.4 The Pid at Work in a Buck Converter. |
Record Nr. | UNINA-9910462561403321 |
Basso Christophe P. | ||
Norwood : , : Artech House, , 2012 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Designing Control Loops for Linear and Switching Power Supplies : a Tutorial Guide |
Autore | Basso Christophe P. |
Pubbl/distr/stampa | Norwood : , : Artech House, , 2012 |
Descrizione fisica | 1 online resource (613 p.) |
Disciplina | 613 |
Soggetto topico |
Switching power supplies - Design and construction
Process control Power electronics Feedback control systems Electric current converters |
ISBN | 1-60807-558-3 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Designing Control Loops for Linear and Switching Power Supplies: A Tutorial Guide; Contents; Foreword; Preface; Acknowledgments; Chapter 1 Basics of Loop Control; 1.1 Open-Loop Systems; 1.1.1 Perturbations; 1.2 The Necessity of Control-Closed-Loop Systems; 1.3 Notions of Time Constants; 1.3.1 Working with Time Constants; 1.3.2 The Proportional Term; 1.3.3 The Derivative Term; 1.3.4 The Integral Term; 1.3.5 Combining the Factors; 1.4 Performance of a Feedback Control System; 1.4.1 Transient or Steady State?; 1.4.2 The Step; 1.4.3 The Sinusoidal Sweep; 1.4.4 The Bode Plot.
1.5 Transfer Functions1.5.1 The Laplace Transform; 1.5.2 Excitation and Response Signals; 1.5.3 A Quick Example; 1.5.4 Combining Transfer Functions with Bode Plots; 1.6 Conclusion; Selected Bibliography; Chapter 2 Transfer Functions; 2.1 Expressing Transfer Functions; 2.1.1 Writing Transfer Functions the Right Way; 2.1.2 The 0-db Crossover Pole; 2.2 Solving for the Roots; 2.2.1 Poles and Zeros Found by Inspection; 2.2.2 Poles, Zeros, and Time Constants; 2.3 Transient Response and Roots; 2.3.1 When the Roots Are Moving; 2.4 S-Plane and Transient Response. 2.4.1 Roots Trajectories in the Complex Plane2.5 Zeros in the Right Half Plane; 2.5.1 A Two-Step Conversion Process; 2.5.2 The Inductor Current Slew-Rate Is the Limit; 2.5.3 An Average Model to Visualize Rhp Zero Effects; 2.5.4 The Right Half Plane Zero in the Boost Converter; 2.6 Conclusion; References; Appendix 2A: Determining a Bridge Input Impedance; Reference; Appendix 2B: Plotting Evans Loci with Mathcad; Appendix 2C: Heaviside Expansion Formulas; Reference; Appendix 2D: Plotting a Right Half Plane Zero with Spice; Chapter 3 Stability Criteria of a Control System. 3.1 Building An Oscillator3.1.1 Theory at Work; 3.2 Stability Criteria; 3.2.1 Gain Margin and Conditional Stability; 3.2.2 Minimum Versus Nonminimum-Phase Functions; 3.2.3 Nyquist Plots; 3.2.4 Extracting the Basic Information from the Nyquist Plot; 3.2.5 Modulus Margin; 3.3 Transient Response, Quality Factor, and Phase Margin; 3.3.1 A Second-Order System, the Rlc Circuit; 3.3.2 Transient Response of a Second-Order System; 3.3.4 Opening the Loop to Measure the Phase Margin; 3.3.5 The Phase Margin of a Switching Converter; 3.3.6 Considering a Delay in the Conversion Process. 3.3.7 The Delay in the Laplace Domain3.3.8 Delay Margin versus Phase Margin; 3.4 Selecting the Crossover Frequency; 3.4.1 A Simplified Buck Converter; 3.4.2 The Output Impedance in Closed-Loop Conditions; 3.4.3 The Closed-Loop Output Impedance at Crossover; 3.4.4 Scaling the Reference to Obtain the Desired Output; 3.4.5 Increasing the Crossover Frequency Further; 3.5 Conclusion; References; Chapter 4 Compensation; 4.1 The Pid Compensator; 4.1.1 The Pid Expressions in the Laplace Domain; 4.1.2 Practical Implementation of a Pid Compensator; 4.1.3 Practical Implementation of a Pi Compensator. 4.1.4 The Pid at Work in a Buck Converter. |
Record Nr. | UNINA-9910786582003321 |
Basso Christophe P. | ||
Norwood : , : Artech House, , 2012 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Designing Control Loops for Linear and Switching Power Supplies : a Tutorial Guide |
Autore | Basso Christophe P. |
Pubbl/distr/stampa | Norwood : , : Artech House, , 2012 |
Descrizione fisica | 1 online resource (613 p.) |
Disciplina | 613 |
Soggetto topico |
Switching power supplies - Design and construction
Process control Power electronics Feedback control systems Electric current converters |
ISBN | 1-60807-558-3 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Designing Control Loops for Linear and Switching Power Supplies: A Tutorial Guide; Contents; Foreword; Preface; Acknowledgments; Chapter 1 Basics of Loop Control; 1.1 Open-Loop Systems; 1.1.1 Perturbations; 1.2 The Necessity of Control-Closed-Loop Systems; 1.3 Notions of Time Constants; 1.3.1 Working with Time Constants; 1.3.2 The Proportional Term; 1.3.3 The Derivative Term; 1.3.4 The Integral Term; 1.3.5 Combining the Factors; 1.4 Performance of a Feedback Control System; 1.4.1 Transient or Steady State?; 1.4.2 The Step; 1.4.3 The Sinusoidal Sweep; 1.4.4 The Bode Plot.
1.5 Transfer Functions1.5.1 The Laplace Transform; 1.5.2 Excitation and Response Signals; 1.5.3 A Quick Example; 1.5.4 Combining Transfer Functions with Bode Plots; 1.6 Conclusion; Selected Bibliography; Chapter 2 Transfer Functions; 2.1 Expressing Transfer Functions; 2.1.1 Writing Transfer Functions the Right Way; 2.1.2 The 0-db Crossover Pole; 2.2 Solving for the Roots; 2.2.1 Poles and Zeros Found by Inspection; 2.2.2 Poles, Zeros, and Time Constants; 2.3 Transient Response and Roots; 2.3.1 When the Roots Are Moving; 2.4 S-Plane and Transient Response. 2.4.1 Roots Trajectories in the Complex Plane2.5 Zeros in the Right Half Plane; 2.5.1 A Two-Step Conversion Process; 2.5.2 The Inductor Current Slew-Rate Is the Limit; 2.5.3 An Average Model to Visualize Rhp Zero Effects; 2.5.4 The Right Half Plane Zero in the Boost Converter; 2.6 Conclusion; References; Appendix 2A: Determining a Bridge Input Impedance; Reference; Appendix 2B: Plotting Evans Loci with Mathcad; Appendix 2C: Heaviside Expansion Formulas; Reference; Appendix 2D: Plotting a Right Half Plane Zero with Spice; Chapter 3 Stability Criteria of a Control System. 3.1 Building An Oscillator3.1.1 Theory at Work; 3.2 Stability Criteria; 3.2.1 Gain Margin and Conditional Stability; 3.2.2 Minimum Versus Nonminimum-Phase Functions; 3.2.3 Nyquist Plots; 3.2.4 Extracting the Basic Information from the Nyquist Plot; 3.2.5 Modulus Margin; 3.3 Transient Response, Quality Factor, and Phase Margin; 3.3.1 A Second-Order System, the Rlc Circuit; 3.3.2 Transient Response of a Second-Order System; 3.3.4 Opening the Loop to Measure the Phase Margin; 3.3.5 The Phase Margin of a Switching Converter; 3.3.6 Considering a Delay in the Conversion Process. 3.3.7 The Delay in the Laplace Domain3.3.8 Delay Margin versus Phase Margin; 3.4 Selecting the Crossover Frequency; 3.4.1 A Simplified Buck Converter; 3.4.2 The Output Impedance in Closed-Loop Conditions; 3.4.3 The Closed-Loop Output Impedance at Crossover; 3.4.4 Scaling the Reference to Obtain the Desired Output; 3.4.5 Increasing the Crossover Frequency Further; 3.5 Conclusion; References; Chapter 4 Compensation; 4.1 The Pid Compensator; 4.1.1 The Pid Expressions in the Laplace Domain; 4.1.2 Practical Implementation of a Pid Compensator; 4.1.3 Practical Implementation of a Pi Compensator. 4.1.4 The Pid at Work in a Buck Converter. |
Record Nr. | UNINA-9910827111003321 |
Basso Christophe P. | ||
Norwood : , : Artech House, , 2012 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Linear circuit transfer functions : an introduction to fast analytical techniques / / Christophe Basso |
Autore | Basso Christophe P. |
Pubbl/distr/stampa | Chichester, West Sussex ; ; Hoboken, NJ : , : Wiley, , 2016 |
Descrizione fisica | 1 online resource (463 p.) |
Disciplina | 621.3815 |
Collana | Wiley - IEEE |
Soggetto topico |
Transfer functions
Electric circuits, Linear |
ISBN |
1-119-23635-5
1-119-23636-3 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
About the Author ix -- Preface xi -- Acknowledgement xiii -- 1 Electrical Analysis / Terminology and Theorems 1 -- 1.1 Transfer Functions, an Informal Approach 1 -- 1.1.1 Input and Output Ports 3 -- 1.1.2 Different Types of Transfer Function 6 -- 1.2 The Few Tools and Theorems You Did Not Forget . . . 11 -- 1.2.1 The Voltage Divider 11 -- 1.2.2 The Current Divider 12 -- 1.2.3 Thévenin's Theorem at Work 14 -- 1.2.4 Norton's Theorem at Work 19 -- 1.3 What Should I Retain from this Chapter? 25 -- 1.4 Appendix 1A / Finding Output Impedance/Resistance 26 -- 1.5 Appendix 1B / Problems 37 -- Answers 39 -- 2 Transfer Functions 41 -- 2.1 Linear Systems 41 -- 2.1.1 A Linear Time-invariant System 43 -- 2.1.2 The Need for Linearization 43 -- 2.2 Time Constants 44 -- 2.2.1 Time Constant Involving an Inductor 47 -- 2.3 Transfer Functions 49 -- 2.3.1 Low-entropy Expressions 54 -- 2.3.2 Higher Order Expressions 59 -- 2.3.3 Second-order Polynomial Forms 60 -- 2.3.4 Low-Q Approximation for a 2nd-order Polynomial 62 -- 2.3.5 Approximation for a 3rd-order Polynomial 68 -- 2.3.6 How to Determine the Order of the System? 69 -- 2.3.7 Zeros in the Network 76 -- 2.4 First Step Towards a Generalized 1st-order Transfer Function 78 -- 2.4.1 Solving 1st-order Circuits with Ease, Three Examples 82 -- 2.4.2 Obtaining the Zero with the Null Double Injection 89 -- 2.4.3 Checking Zeros Obtained in Null Double Injection with SPICE 94 -- 2.4.4 Network Excitation 95 -- 2.5 What Should I Retain from this Chapter? 100 -- References 101 -- 2.6 Appendix 2A / Problems 102 -- Answers 105 -- 3 Superposition and the Extra Element Theorem 116 -- 3.1 The Superposition Theorem 116 -- 3.1.1 A Two-input/Two-output System 120 -- 3.2 The Extra Element Theorem 126 -- 3.2.1 The EET at Work on Simple Circuits 130 -- 3.2.2 The EET at Work / Example 2 132 -- 3.2.3 The EET at Work / Example 3 137 -- 3.2.4 The EET at Work / Example 4 138 -- 3.2.5 The EET at Work / Example 5 140 -- 3.2.6 The EET at Work / Example 6 146 -- 3.2.7 Inverted Pole and Zero Notation 150.
3.3 A Generalized Transfer Function for 1st-order Systems 153 -- 3.3.1 Generalized Transfer Function / Example 1 156 -- 3.3.2 Generalized Transfer Function / Example 2 159 -- 3.3.3 Generalized Transfer Function / Example 3 163 -- 3.3.4 Generalized Transfer Function / Example 4 170 -- 3.3.5 Generalized Transfer Function / Example 5 174 -- 3.4 Further Reading 180 -- 3.5 What Should I Retain from this Chapter? 180 -- References 182 -- 3.6 Appendix 3A / Problems 183 -- Answers 185 -- References 218 -- 4 Second-order Transfer Functions 219 -- 4.1 Applying the Extra Element Theorem Twice 219 -- 4.1.1 Low-entropy 2nd-order Expressions 227 -- 4.1.2 Determining the Zero Positions 231 -- 4.1.3 Rearranging and Plotting Expressions 233 -- 4.1.4 Example 1 / A Low-Pass Filter 235 -- 4.1.5 Example 2 / A Two-capacitor Filter 241 -- 4.1.6 Example 3 / A Two-capacitor Band-stop Filter 245 -- 4.1.7 Example 4 / An LC Notch Filter 248 -- 4.2 A Generalized Transfer Function for 2nd-Order Systems 255 -- 4.2.1 Inferring the Presence of Zeros in the Circuit 256 -- 4.2.2 Generalized 2nd / order Transfer Function / Example 1 257 -- 4.2.3 Generalized 2nd / order Transfer Function / Example 2 262 -- 4.2.4 Generalized 2nd / order Transfer Function / Example 3 266 -- 4.2.5 Generalized 2nd / order Transfer Function / Example 4 273 -- 4.3 What Should I Retain from this Chapter ? 277 -- References 279 -- 4.4 Appendix 4A / Problems 279 -- Answers 282 -- References 311 -- 5 Nth-order Transfer Functions 312 -- 5.1 From the 2EET to the NEET 312 -- 5.1.1 3rd-order Transfer Function Example 317 -- 5.1.2 Transfer Functions with Zeros 320 -- 5.1.3 A Generalized Nth-order Transfer Function 327 -- 5.2 Five High-order Transfer Functions Examples 335 -- 5.2.1 Example 2: A 3rd-order Active Notch Circuit 341 -- 5.2.2 Example 3: A 4th-order LC Passive Filter 349 -- 5.2.3 Example 4: A 4th-order Band-pass Active Filter 355 -- 5.2.4 Example 5: A 3rd-order Low-pass Active GIC Filter 368 -- 5.3 What Should I Retain from this Chapter ? 383. References 385 -- 5.5 Appendix 5A / Problems 385 -- Answers 388 -- References 431 -- Conclusion 433 -- Glossary of Terms 435 -- Index 439. |
Record Nr. | UNINA-9910136778603321 |
Basso Christophe P. | ||
Chichester, West Sussex ; ; Hoboken, NJ : , : Wiley, , 2016 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Linear circuit transfer functions : an introduction to fast analytical techniques / / Christophe Basso |
Autore | Basso Christophe P. |
Pubbl/distr/stampa | Chichester, West Sussex ; ; Hoboken, NJ : , : Wiley, , 2016 |
Descrizione fisica | 1 online resource (463 p.) |
Disciplina | 621.3815 |
Collana | Wiley - IEEE |
Soggetto topico |
Transfer functions
Electric circuits, Linear |
ISBN |
1-119-23635-5
1-119-23636-3 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
About the Author ix -- Preface xi -- Acknowledgement xiii -- 1 Electrical Analysis / Terminology and Theorems 1 -- 1.1 Transfer Functions, an Informal Approach 1 -- 1.1.1 Input and Output Ports 3 -- 1.1.2 Different Types of Transfer Function 6 -- 1.2 The Few Tools and Theorems You Did Not Forget . . . 11 -- 1.2.1 The Voltage Divider 11 -- 1.2.2 The Current Divider 12 -- 1.2.3 Thévenin's Theorem at Work 14 -- 1.2.4 Norton's Theorem at Work 19 -- 1.3 What Should I Retain from this Chapter? 25 -- 1.4 Appendix 1A / Finding Output Impedance/Resistance 26 -- 1.5 Appendix 1B / Problems 37 -- Answers 39 -- 2 Transfer Functions 41 -- 2.1 Linear Systems 41 -- 2.1.1 A Linear Time-invariant System 43 -- 2.1.2 The Need for Linearization 43 -- 2.2 Time Constants 44 -- 2.2.1 Time Constant Involving an Inductor 47 -- 2.3 Transfer Functions 49 -- 2.3.1 Low-entropy Expressions 54 -- 2.3.2 Higher Order Expressions 59 -- 2.3.3 Second-order Polynomial Forms 60 -- 2.3.4 Low-Q Approximation for a 2nd-order Polynomial 62 -- 2.3.5 Approximation for a 3rd-order Polynomial 68 -- 2.3.6 How to Determine the Order of the System? 69 -- 2.3.7 Zeros in the Network 76 -- 2.4 First Step Towards a Generalized 1st-order Transfer Function 78 -- 2.4.1 Solving 1st-order Circuits with Ease, Three Examples 82 -- 2.4.2 Obtaining the Zero with the Null Double Injection 89 -- 2.4.3 Checking Zeros Obtained in Null Double Injection with SPICE 94 -- 2.4.4 Network Excitation 95 -- 2.5 What Should I Retain from this Chapter? 100 -- References 101 -- 2.6 Appendix 2A / Problems 102 -- Answers 105 -- 3 Superposition and the Extra Element Theorem 116 -- 3.1 The Superposition Theorem 116 -- 3.1.1 A Two-input/Two-output System 120 -- 3.2 The Extra Element Theorem 126 -- 3.2.1 The EET at Work on Simple Circuits 130 -- 3.2.2 The EET at Work / Example 2 132 -- 3.2.3 The EET at Work / Example 3 137 -- 3.2.4 The EET at Work / Example 4 138 -- 3.2.5 The EET at Work / Example 5 140 -- 3.2.6 The EET at Work / Example 6 146 -- 3.2.7 Inverted Pole and Zero Notation 150.
3.3 A Generalized Transfer Function for 1st-order Systems 153 -- 3.3.1 Generalized Transfer Function / Example 1 156 -- 3.3.2 Generalized Transfer Function / Example 2 159 -- 3.3.3 Generalized Transfer Function / Example 3 163 -- 3.3.4 Generalized Transfer Function / Example 4 170 -- 3.3.5 Generalized Transfer Function / Example 5 174 -- 3.4 Further Reading 180 -- 3.5 What Should I Retain from this Chapter? 180 -- References 182 -- 3.6 Appendix 3A / Problems 183 -- Answers 185 -- References 218 -- 4 Second-order Transfer Functions 219 -- 4.1 Applying the Extra Element Theorem Twice 219 -- 4.1.1 Low-entropy 2nd-order Expressions 227 -- 4.1.2 Determining the Zero Positions 231 -- 4.1.3 Rearranging and Plotting Expressions 233 -- 4.1.4 Example 1 / A Low-Pass Filter 235 -- 4.1.5 Example 2 / A Two-capacitor Filter 241 -- 4.1.6 Example 3 / A Two-capacitor Band-stop Filter 245 -- 4.1.7 Example 4 / An LC Notch Filter 248 -- 4.2 A Generalized Transfer Function for 2nd-Order Systems 255 -- 4.2.1 Inferring the Presence of Zeros in the Circuit 256 -- 4.2.2 Generalized 2nd / order Transfer Function / Example 1 257 -- 4.2.3 Generalized 2nd / order Transfer Function / Example 2 262 -- 4.2.4 Generalized 2nd / order Transfer Function / Example 3 266 -- 4.2.5 Generalized 2nd / order Transfer Function / Example 4 273 -- 4.3 What Should I Retain from this Chapter ? 277 -- References 279 -- 4.4 Appendix 4A / Problems 279 -- Answers 282 -- References 311 -- 5 Nth-order Transfer Functions 312 -- 5.1 From the 2EET to the NEET 312 -- 5.1.1 3rd-order Transfer Function Example 317 -- 5.1.2 Transfer Functions with Zeros 320 -- 5.1.3 A Generalized Nth-order Transfer Function 327 -- 5.2 Five High-order Transfer Functions Examples 335 -- 5.2.1 Example 2: A 3rd-order Active Notch Circuit 341 -- 5.2.2 Example 3: A 4th-order LC Passive Filter 349 -- 5.2.3 Example 4: A 4th-order Band-pass Active Filter 355 -- 5.2.4 Example 5: A 3rd-order Low-pass Active GIC Filter 368 -- 5.3 What Should I Retain from this Chapter ? 383. References 385 -- 5.5 Appendix 5A / Problems 385 -- Answers 388 -- References 431 -- Conclusion 433 -- Glossary of Terms 435 -- Index 439. |
Record Nr. | UNINA-9910820449703321 |
Basso Christophe P. | ||
Chichester, West Sussex ; ; Hoboken, NJ : , : Wiley, , 2016 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|