Circuits and Systems for the Internet of Things : CAS4IoT.

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Internet-of-Things (IoT) can be envisaged as a dynamic network of interconnected physical and virtual entities ("things"), with their own identities and attributes, seamlessly integrated in order to e.g. actively participate in economic or societal processes, interact with services, and re...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Goes, João
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Bloomfield : River Publishers, 2017.
Colección:Tutorials in Circuits and Systems Ser.
Temas:
Electronic circuits.
Internet of things.
Circuits électroniques.
Internet des objets.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Front Cover; Half Title
  • Circuits and Systems for the Internet of Things; Full Title
  • Tutorials in Circuits and Systems; Copyright Page; Table of contents; Introduction; Chapter 1
  • Ultra-Low-Voltage and Micro-Power Analog Design for Internet of Things; 1. Introduction; 2. Introduction; 3. Introduction; 4. Introduction; 5. Introduction; 6. Introduction; 7. Introduction; 8. Introduction; 9. Introduction; 10. Introduction; 11. SWOT Analysis; 12. Strengths: Sensors; 13. Strengths: Sensors; 14. Strengths: Electronics & Communication; 15. Opportunities: Quality of Life.
  • 16. Threats: Safety, Privacy17. Threats: Machine dependency; 18. Weaknesses: Packaging Testing; 19. Weaknesses: Packaging Testing; 20. Weaknesses: Power Harvesting; 21. Weaknesses: Power Harvesting; 22. Weaknesses -> Strength: Energy Storage; 23. Features; 24. Features; 25. Features; 26. Features; 27. What is critical?; 28. Communication; 29. Communication; 30. Communication; 31. Communication: Fast wake-up; 32. In Summary; 33. Therefore; 34. Low Voltage Low Power Analog; 35. Low Voltage Low Power Analog; 36. The threshold-supply voltage race; 37. Clock Boostrap.
  • 38. Use of zero threshold MOS transistors39. Use of boostrap; 40. Input and output Op-Amp Swing; 41. Input and output Op-Amp Swing; 42. Sampled-data Gain-stage; 43. Sampled-data Gain-stage; 44. Sampled-data Gain-stage; 45. Sampled-data Gain-stage; 46. Reference Generator with SD Gain-stage; 47. Reference Generator with SD Gain-stage; 48. 0.4 V Supply Reference Generator; 49. 0.4 V Supply Reference Generator; 50. 0.4 V Supply Reference Generator; 51. 0.4 V Supply Reference Generator; 52. 0.4 V Supply Reference Generator; 53. Sigma-Delta with Inverter based Integrator.
  • 54. Sigma-Delta with Inverter based Integrator55. Sigma-Delta with Inverter based Integrator; 56. SAR Architectures useful for ULV and ULP; 57. SAR Architectures useful for ULV and ULP; 58. SAR Architectures useful for ULV and ULP; 59. SAR Architectures useful for ULV and ULP; 60. SAR Architectures useful for ULV and ULP; 61. SAR for 10-b of resolution; 62. SAR for 10-b of resolution; 63. SAR for 10-b of resolution; 64. SAR for 10-b of resolution; 65. How obtaining lower power and voltage?; 66. SAR with supply lower than 0.3 V?; 67. Conclusions.
  • Chapter 2
  • SAR ADCs for Internet of Things: Basics and Innovations1. Outline; 2. ADCs for IoT; 3. ADC Architecture Overview; 4. Outline; 5. Successive Approximation Principle; 6. Basic SAR ADC Architecture; 7. Overall Noise; 8. Overall Linearity, Gain, Offset; 9. Overall Speed; 10. Overall Power Consumption; 11. Overall Chip Area; 12. Outline; 13. T & H Basic Circuit and Operation; 14. T & H CMOS Switch; 15. T & H Boosting Techniques; 16. T & H Imperfections; 17. T & H On-Resistance; 18. T & H Charge Injection; 19. T & H Distortion: INL and Spectrum; 20. T & H Distortion vs Input Frequency.

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