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100 1 Goes, João.|0https://id.loc.gov/authorities/names/
n2001001108
245 10 Circuits and Systems for the Internet of Things :
|bCAS4IoT.
264 1 Bloomfield :|bRiver Publishers,|c2017.
300 1 online resource (346 pages).
336 text|btxt|2rdacontent
337 computer|bc|2rdamedia
338 online resource|bcr|2rdacarrier
347 text file|2rdaft
490 1 Tutorials in Circuits and Systems Ser.
500 21. T & H kT/C Sampling Noise.
505 0 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.
505 8 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.
505 8 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.
505 8 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.
505 8 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.
520 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 react autonomously to events while
sensing the environment. By enabling things to connect and
becoming recognizable, while providing them with
intelligence, informed and context based decisions are
expected in a broad range of domains spanning from health
and elderly care to energy efficiency, either providing
business competitive advantages to companies, either
addressing key social concerns. The level of connectivity
and analytical intelligence provided by the IoT paradigm
is expected to allow creating new services that would not
be feasible by other means. This CAS4IoT book targets post
-graduate students and design engineers, with the skills
to understand and design a broader range of analog,
digital and mixed-signal circuits and systems, in the
field of IoT, spanning from data converters for sensor
interfaces to radios, ensuring a good balance between
academia and industry, combined with a judicious selection
of worldwide distinguished authors.
588 0 Print version record.
590 eBooks on EBSCOhost|bEBSCO eBook Subscription Academic
Collection - North America
650 0 Electronic circuits.|0https://id.loc.gov/authorities/
subjects/sh85042279
650 0 Internet of things.|0https://id.loc.gov/authorities/
subjects/sh2013000266
650 7 Electronic circuits.|2fast|0https://id.worldcat.org/fast/
906874
650 7 Internet of things.|2fast|0https://id.worldcat.org/fast/
1894151
655 4 Electronic books.
776 08 |iPrint version:|aGoes, João.|tCircuits and Systems for
the Internet of Things : CAS4IoT.|dBloomfield : River
Publishers, ©2017
830 0 Tutorials in Circuits and Systems Ser.
856 40 |uhttps://rider.idm.oclc.org/login?url=https://
search.ebscohost.com/login.aspx?direct=true&scope=site&
db=nlebk&AN=1800580|zOnline ebook via EBSCO. Access
restricted to current Rider University students, faculty,
and staff.
856 42 |3Instructions for reading/downloading the EBSCO version
of this ebook|uhttp://guides.rider.edu/ebooks/ebsco
901 MARCIVE 20231220
948 |d20211213|cEBSCO|tEBSCOebooksacademic NEW Oct-Nov 5018
|lridw
994 92|bRID
