学位论文详细信息
Crystal-Less RF Communication Integrated Circuits for Wireless Sensor Networks.
CMOS;Wireless Sensor Networks;Radio;Crystal-Less;Low-Power;Cubic-Millimeter;Electrical Engineering;Engineering;Electrical Engineering
Huang, Kuo-KenSylvester, Dennis Michael ;
University of Michigan
关键词: CMOS;    Wireless Sensor Networks;    Radio;    Crystal-Less;    Low-Power;    Cubic-Millimeter;    Electrical Engineering;    Engineering;    Electrical Engineering;   
Others  :  https://deepblue.lib.umich.edu/bitstream/handle/2027.42/99763/kkhuang_1.pdf?sequence=1&isAllowed=y
瑞士|英语
来源: The Illinois Digital Environment for Access to Learning and Scholarship
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【 摘 要 】

The evolution of computing devices has changed daily life significantly over the past decades, and it is still advancing towards pervasive and ubiquitous networks. At each step, the volume shrinks by 2-3 orders of magnitude while the functionality and computing power remains constant or increases. Wireless sensor networks (WSN) are perceived as the next big step of computing technology for a variety of applications, including environmental sensing, health monitoring, un-obtrusive surveillance and invisible labeling. With thin-film micro-battery technology and CMOS scaling, we can now envision complete sensor nodes with cubic-mm form factors. As node volume reduces, external components like a crystal frequency reference, which does not scale with frequency or process, becomes one of the bottlenecks of realizing cubic-mm WSN node devices.This dissertation covers several aspects of the energy and integration challenges associated with cubic-mm WSN nodes without crystal references. Several new compact and low-power RF circuits for the synchronization and communication of WSN nodes are proposed and discussed. A 60GHz antenna-referenced frequency-locked loop (FLL) using an on-chip patch antenna as both the radiator and the frequency reference has been demonstrated for RF synchronization. The FLL, targeting communication of non-coherent energy detection systems, provides adequate frequency accuracy without crystal references. A 10GHz ultra-wideband (UWB) crystal-less transmitter with an on-chip monopole antenna has also been demonstrated. It operates over the supply voltage range of a micro-battery; generate tunable pulse durations and center frequencies, and lives on an on-chip local decoupling capacitor only. A 1MHz temperature-compensated relaxation oscillator is also proposed in the dissertation for baseband data synchronization. With the modified RC network of the conventional relaxation oscillator, the transfer function of the network has a transmission zero, introducing an additional degree-of-freedom for temperature compensation design. Finally, a 60GHz transmit/receive (T/R) switch-less antenna front-end using an on-chip patch antenna is presented, which has an in-band isolation inherited from the standing wave pattern without implementing a T/R switch. The research projects have explored the circuit design techniques and system integration for cubic-mm energy-constrained devices, achieving both long lifetimes and small volumes for WSN applications.

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