Cambridge : , : Cambridge University Press, , 2013

1-139-62439-3

1-107-23250-3

1-139-03072-8

1-139-60951-3

1-139-60822-3

1-139-61137-2

1-139-61509-2

1-299-40567-3

1-139-62067-3

1 online resource (xii, 190 pages) : digital, PDF file(s)

TEC008010

621.3841/33

Electric filters, Bandpass

Radio frequency integrated circuits - Design and construction

Inglese

Title from publisher's bibliographic system (viewed on 05 Oct 2015).

Includes bibliographical references and index.

Machine generated contents note: Part I. Introduction to Highly Integrated and Tunable RF Receiver Front Ends: 1. Introduction; 2. Front-end integration challenges and system requirements; 3. 2G receiver SAW elimination; 4. 3G receiver SAW elimination; 5. Summary and conclusions; Part II. Active Blocker Cancellation Techniques in Receivers: 6. Introduction; 7. Concept of receiver translational loop; 8. Non-ideal effects; 9. Circuit implementations; 10. Measurement results; 11. Feedback blocker cancellation techniques; 12. Summary and conclusions; Part III. Impedance Transformation: Introduction to the Simplest On-Chip SAW Filter: 13. Introduction; 14. Impedance transformation by a 50% passive mixer; 15. Application as on-chip SAW filter; 16. Impact of harmonics on the sharpness of the proposed filter;

17. Differential implementation; 18. Summary and conclusions; Part IV. Four-Phase High-Q Bandpass Filters: 19. Introduction; 20. Impedance transformation by a four-phase filter; 21. Differential implementation of four-phase high-Q bandpass filter; 22. Application as an on-chip SAW filter; 23. Impact of harmonics on the sharpness of the proposed filter; 24. Four-phase high-Q bandpass filter with a complex baseband impedance; 25. Four-phase high-Q bandpass filter with quadrature RF inputs; 26. Harmonic upconversion and downconversion; 27. A SAW-less receiver with on-chip four-phase high-Q bandpass filters; 28. Summary and conclusions; Part V. M-Phase High-Q Bandpass Filters: 29. Introduction; 30. Impedance transformation by M-phase filters; 31. Differential implementation of M-phase high-Q filter; 32. Application as an on-chip SAW filter; 33. Impact of harmonics on the sharpness of the M-phase bandpass filter; 34. M-phase high-Q filter with complex baseband impedances; 35. M-phase high-Q bandpass filter with quadrature RF inputs; 36. M-phase high-Q bandpass filter with N-phase complex bandpass filters; 37. Harmonic upconversion; 38. Summary and conclusions; Part VI. Design of a Superheterodyne Receiver Using M-Phase Filters: 39. Introduction; 40. Proposed superheterodyne receiver architecture; 41. Design and implementation of the receiver chain; 42. Measurement results; 43. Summary and conclusions; Part VII. Impact of Imperfections on the Performance of M-Phase Filters: 44. Introduction; 45. Mathematical background; 46. LO phase noise; 47. Second-order nonlinearity in the switches of the bandpass filter; 48. Quadrature error in the original 50% duty-cycle clock phases; 49. Harmonic downconversion; 50. Thermal noise of switches; 51. Parasitic capacitors of switches; 52. Switch charge injection; 53. Mismatches; 54. Summary and conclusions; Part VIII. M-Phase Filtering and Duality: 55. Introduction; 56. Dual of an electrical circuit, dual of a switch; 57. Dual of M-phase filter, differential implementation of M-phase filter and its dual; 58. Dual of M-phase high-Q filter with complex baseband impedances; 59. Summary and conclusions.

Examining the most important developments in highly integrated wireless RF front ends, this book describes and evaluates both active and passive solutions for on-chip high-Q filtering, and explores M-phase filters in depth. An accessible step-by-step approach is used to introduce everything an RF designer needs to know about these filters, including their various forms, principles of operation, and their performance against implementation-related imperfections. Real-world examples are described in depth, and detailed mathematical analyses demonstrate the practical quantification of pertinent circuit parameters.