RF and mm-Wave Power Generation in Silicon

<p>1. Introduction</p> <p>Part I: Power amplifier design methodologies <br>2. Power amplifier fundamentals</p> <p>Part II: RF Power Amplifier Design Examples<br>3. CMOS power amplifier design for wireless connectivity applications: A highly linear WLAN power amplifier in advanced SoC CMOS <br>4. CMOS power amplifier design for cellular applications: An EDGE/GSM dual-mode quad-band PA in 0.18 µm CMOS<br>5. Energy-efficiency enhancement and linear amplifications: A transformer-based Doherty approach<br>6. Linear power amplification with high back-off efficiency: An out-phasing approach<br>7. Energy efficiency enhancement and linear amplifications: An envelope-tracking (ET) approach <br>8. A digital RF power amplification technique based on the switched-capacitor circuit <br>9. A transformer-based reconfigurable digital polar Doherty power amplifier fully integrated in bulk CMOS</p> <p>Part III: mm-Wave and Terahertz Power Generation Design Examples<br>10. 60 GHz all silicon radio IC: How it all started <br>11. mm-Wave power-combining architectures: Current combining <br>12. mm-Wave power-combining architectures: Hybrid combining<br>13. mm-Wave CMOS design above 60 GHz<br>14. Self-healing techniques for robust mm-Wave power amplification<br>15. mm-Wave class-E PA design in CMOS<br>16. High-speed, efficient, mm-Wave power-mixer-based digital transmitters<br>17. THz power generation beyond transistor f<SUB>max</SUB> <br>18. THz signal generation, radiation, and beam-forming in silicon: A circuit and electromagnetics co-design approach<br>19. Silicon-based THz signal generation with multiphase subharmonic injection-locking oscillators </p>