SeongHwan Cho scite author profile

The potential for collaborative, robust networks of microsensors has attracted a great deal of research attention. For the most part, this is due to the compelling applications that will be enabled once wireless microsensor networks are in place; location-sensing, environmental sensing, medical monitoring and similar applications are all gaining interest. However, wireless microsensor networks pose numerous design challenges. For applications requiring longterm, robust sensing, such as military reconnaissance, one important challenge is to design sensor networks that have long system lifetimes. This challenge is especially difficult due to the energyconstrained nature of the devices. In order to design networks that have extremely long lifetimes, we propose a physical layer driven approach to designing protocols and algorithms. We first present a hardware model for our wireless sensor node and then introduce the design of physical layer aware protocols, algorithms, and applications that minimize energy consumption of the system. Our approach prescribes methods that can be used at all levels of the hierarchy to take advantage of the underlying hardware. We also show how to reduce energy consumption of non-ideal hardware through physical layer aware algorithms and protocols.

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Low-power wireless sensor networks

Min

et al.

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Wireless distributed microsensor systems will enable fault tolerant monitoring and control of a variety of applications. Due to the large number of microsensor nodes that may be deployed and the need for long system lifetimes, replacing the battery is not an option. Sensor systems must utilize the minimal possible energy while operating over a wide range of operating scenarios. This paper presents an overview of the key technologies required for low-energy distributed microsensors. These include power aware computation/communication component technology, low-energy signaling and networking, system partitioning based on computation and communication tradeoffs, and a power aware software infrastructure.

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Design Considerations for Ultra-Low Energy Wireless Microsensor Nodes

Calhoun

Daly

Verma

et al. 2005

IEEE Trans. Comput.

240

103

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Energy-centric enabling tecumologies for wireless sensor networks

Min

Bhardwaj

Cho

et al. 2002

IEEE Wireless Commun.

198

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A 9 bit, 1.12 ps Resolution 2.5 b/Stage Pipelined Time-to-Digital Converter in 65 nm CMOS Using Time-Register

Kim

Cho

2014

IEEE J. Solid-State Circuits

139

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SeongHwan Cho

Physical layer driven protocol and algorithm design for energy-efficient wireless sensor networks

Low-power wireless sensor networks

Design Considerations for Ultra-Low Energy Wireless Microsensor Nodes

Energy-centric enabling tecumologies for wireless sensor networks

A 9 bit, 1.12 ps Resolution 2.5 b/Stage Pipelined Time-to-Digital Converter in 65 nm CMOS Using Time-Register

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