| Navigation |
| Overview |
| 2.1 DC to DC converter basics |
| 2.2 DC to DC converters characteristics |
| 2.3 Comparison of topologies |
| 2.4 System requirements |
| 2.5 Linear Regulator |
| 2.6 The Inductive switcher |
| 2.7 The Charge Pump Buck Regulator |
| 2.8 Inductive Boost Regulator |
| 2.9 The Charge Pump Boost Regulator |
| 2.10 Chapter 1 Test |
| Bode plots |
| 3.1 Feedback system |
| 3.2 Poles and Zeros |
| 3.3 Single pole and zero networks |
| 3.4 Multiple poles and zeros |
| 3.5 Stability Criterion |
| 3.6 Application to output network of a linear regulator |
| 3.7 Chapter 2 Test |
| Discretes |
| 4.1 Transistors |
| 4.2 Diodes |
| 4.3 Inductors |
| 4.4 Inductor characteristics |
| 4.5 Shielded inductors |
| 4.6 Capacitor construction |
| 4.7 Capacitor size codes |
| 4.8 Capacitance vs Frequency |
| 4.9 Capacitance vs Temperature |
| 4.10 Capacitance vs Voltage |
| 4.11 Capacitance vs Voltage and Tempature |
| 4.12 Chapter 3 Test |
| Linear Reg |
| 5.1 Linear regulator overview |
| 5.2 LDO evolution |
| 5.3 Drop out voltage |
| 5.4 Ground current |
| 5.5 LDO stability |
| 5.6 Load regulation |
| 5.7 Adaptive stabilization |
| 5.8 Noise consideration |
| 5.9 Thermal considerations |
| 5.10 Shutdown |
| 5.11 Selecting an LDO |
| 5.12 Chapter 4 test |
| Inductive Buck |
| 6.1 Switcher model |
| 6.2 Switcher Analysis |
| 6.3 Inductor selection analysis |
| 6.4 Inductor Selection calculation |
| 6.5 Inductor choice |
| 6.6 Currents in various components |
| 6.7 Capacitor selection analysis |
| 6.8 Loss models |
| 6.9 Low Iout load - DCM |
| 6.10 Low Iout load - PFM and LDO modes |
| 6.11 Transient response |
| 6.12 Chapter 5 test |
| Sw Cap Buck |
| 7.1 Charge pump basics |
| 7.2 Gain Matrix |
| 7.3 Switched cap losses |
| 7.4 Gain Hopping |
| 7.5 SwCap Benefits |
| 7.6 Chapter 6 test |
| Solution choices |
| 8.1 Gather needs |
| 8.2 Situation 1 |
| 8.3 Situation 2 |
| 8.4 Situation 3 |
| 8.5 Situation 4 |
| 8.6 An analytical approach |
| 8.7 A word about the final test |
