A low complexity UWB PHY baseband transceiver for IEEE 802.15.6 WBAN

2017 30th IEEE International System-on-Chip Conference (SOCC) Pub Date : 2017-09-01 DOI:10.1109/SOCC.2017.8226054

A. Bondok, A. M. El-Mohandes, A. Shalaby, M. Sayed

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引用次数: 3

Abstract

Dealing with critical health issues requires the existence of an intelligent health care system capable of monitoring the patients wherever they are, which increases the demand for a wireless health care system. One possible realization of such a system is the wireless body area network standard defined by IEEE 802.15.6. Based on IEEE 802.15.6, this paper proposes a low complexity implementation of the ultra-wideband physical layer transceiver. A full practical transceiver is introduced with Pulse Shaping, Pulse Deshaping, Time Hopping, Packet Detection and Frame Synchronization included. Chirp pulse is used to shape the data bits in order to minimize the out-of-band radiations. New hardware efficient strategy is used for packet detection. The functionality of the transceiver is tested through computer simulations. All of the design modules were written in Matlab then prototyped using verilog hardware description language. The transceiver is then synthesized targeting 65 nm CMOS technology. The transceiver consumes 443.83 μW in 65 nm technology and conforms to all of standard requirements.

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ieee802.15.6 WBAN的低复杂度UWB PHY基带收发器

处理关键的健康问题需要智能医疗保健系统的存在，无论患者身在何处，都能够对其进行监控，这就增加了对无线医疗保健系统的需求。这种系统的一个可能实现是由IEEE 802.15.6定义的无线体域网络标准。基于IEEE 802.15.6标准，提出了一种低复杂度的超宽带物理层收发器实现方案。介绍了一个完整的实用收发器，包括脉冲整形、脉冲整形、跳时、包检测和帧同步。啁啾脉冲是用来塑造数据位，以尽量减少带外辐射。在数据包检测中采用了新的硬件高效策略。通过计算机仿真测试了收发器的功能。所有的设计模块都是用Matlab编写的，然后使用verilog硬件描述语言进行原型设计。然后针对65nm CMOS技术合成收发器。该收发器在65nm工艺下的功耗为443.83 μW，符合所有标准要求。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2017 30th IEEE International System-on-Chip Conference (SOCC)

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