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Book
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Chapter
Conclusion
In Chap. 1, the motivations short-range radios have been studied, followed by the general definition of .
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Chapter
Introduction
The immense scope of potentiates huge market opportunities for short-range wireless connectivity. To achieve this, it is highly desirable to use and short-range radios.
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Chapter
A 2.4-GHz ZigBee Receiver Exploiting an RF-to-BB-Current-Reuse Blixer + Hybrid Filter Topology in 65-nm CMOS
radios have essentially underpinned the development of short-range wireless technologies [1] such as personal/body-area networks and Internet of Things.
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Chapter
A Sub-GHz Multi-ISM-Band ZigBee Receiver Using Function-Reuse and Gain-Boosted N-Path Techniques for IoT Applications
represents a competitive and large market for short-range wireless connectivity [1, 2]. According to [3], by 2020 the IoT market will be close to hundreds of billion dollars (annually ~16 billions). To br...
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Chapter
Design and Implementation of Ultra-Low-Power ZigBee/WPAN Receiver
In recent years, the proliferation of short-range wireless applications and personal healthcare calls for ultra-low power and cost radios [1]. Ultra-low designs have been one of the key directions to approa...
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Chapter
Analysis and Modeling of a Gain-Boosted N-Path Switched-Capacitor Bandpass Filter
The demand of highly-integrated multi-band transceivers has driven the development of blocker-tolerant software-defined radios that can avoid the cost (and loss) of the baluns and SAW filters [1–3].