Analog Electronics In A Day Analog Electronic Design Outline-continued Current feedback op amp analysis · Circuit board layout Non-ideal op amp conditions High speed amplifier applications Single-supply op amp applications · Converter basics Converter Applications Power applications 1-7
1-7 Analog Electronics In A Day Analog Electronic Design 1-7 • Current feedback op amp analysis • Circuit board layout • Non-ideal op amp conditions • High speed amplifier applications • Single-supply op amp applications • Converter basics • Converter Applications • Power applications
Analog Electronics In A Day Analog electronic des Table of contents 1. Introduction 1-1 Why are we here What you will learn Review outlier 2. Passive Devices 2-1 Resistors Capacitors Inductors Diodes 3. Active Devices Ideal and first level real models bjt. jfet MOSFET, VFB op amp CFB op amp, comparator 1-8
1-8 Analog Electronics In A Day Analog Electronic Design 1-8 1. Introduction 1-1 • Why are we here • What you will learn • Review outline 2. Passive Devices 2-1 • Resistors • Capacitors • Inductors • Diodes 3. Active Devices 3-1 • Ideal and first level real models BJT, JFET, MOSFET, VFB op amp, CFB op amp, comparator
Analog Electronics In A Day Analog electronic design 4. Circuit Equations Ohms law Kirchoff laws Voltage divider rule Current divider rule Thevenin's rule Norton s rule Superposition 5. Derivation of ideal op amp equation 5-1 Use voltage divider law Kirchoff's law and ohms law Do inverting, non-inverting differential, grounded component in feedback loop 1-9 1-9
1-9 Analog Electronics In A Day Analog Electronic Design 1-9 4. Circuit Equations 4-1 • Ohm’s law • Kirchoff’s laws • Voltage divider rule • Current divider rule • Thevenin’s rule • Norton’s rule • Superposition 5. Derivation of ideal op amp equation 5-1 • Use voltage divider law, Kirchoff’s law and Ohm’s law • Do inverting, non-inverting, differential, grounded component in feedback loop
Analog Electronics In A Day Analog Electronic Design 6. Feedback Analysis Tools 6-1 Block diagrams Bode plots 7. Stability 7-1 Stability equation VFB op amp equations Second order equations Overshoot and stability Phase marg Oscillation and oscillators 8. VFB Op Amp Compensation Dominant pole Feed forward Lead/lag Compensated attenuator 1-10
1-10 Analog Electronics In A Day Analog Electronic Design 1-10 6. Feedback Analysis Tools 6-1 • Block diagrams • Bode plots 7. Stability 7-1 • Stability equation • VFB op amp equations • Second order equations • Overshoot and stability • Phase margin • Oscillation and Oscillators 8. VFB Op Amp Compensation 8-1 • Dominant pole • Feed forward • Lead/lag • Compensated attenuator
Analog Electronics In A Day Analog Electronic Design 9. CFB Op Amp Analysis 9-1 · Derive the equations Stability Analysis 10. Circuit Board Layout 10-1 Ground plane Decoupling capacitors Parallel traces Faraday shield Capacitance Differential versus single-ended 11. Non-deal conditions 11-1 Offset voltage Error versus frequen Common-mode rejection versus frequency Output swing-versus frequency, load, and distortion Noise 111
1-11 Analog Electronics In A Day Analog Electronic Design 1-11 9. CFB Op Amp Analysis 9-1 • Derive the equations • Stability Analysis 10. Circuit Board Layout 10-1 • Ground Plane • Decoupling capacitors • Parallel traces • Faraday shield • Capacitance • Differential versus single-ended 11. Non-Ideal Conditions 11-1 • Offset voltage • Error versus frequency • Common-mode rejection versus frequency • Output swing-versus frequency, load, and distortion • Noise