人体局域网技术需求与挑战

林金朝; 柏桐; 李国权; 庞宇

doi:10.11959/j.issn.2096-3750.2018.00059

您当前的位置：

首页 >

文章列表页 >

人体局域网技术需求与挑战

前言与综述 | 更新时间：2024-06-05

- 人体局域网技术需求与挑战
- Technological requirements and challenges of body area networks
- 物联网学报 2018年2卷第3期页码：11-20
- 作者机构：
- 作者简介：
  
  [ "林金朝（1966-），男，博士，重庆邮电大学教授、博士生导师，主要研究方向为无线通信传输技术、BAN网络与信息处理技术等。" ]
  [ "柏桐（1987-），男，重庆邮电大学博士，主要研究方向为无线体域网、无线通信。" ]
  [ "李国权（1980-），男，博士，重庆邮电大学副教授、硕士生导师，主要研究方向为MIMO无线通信传输技术、BAN网络与信息处理技术等。" ]
  [ "庞宇（1978-），男，博士，重庆邮电大学教授、博士生导师，主要研究方向为通信集成电路设计、逻辑综合、无线体域网及无线通信等。" ]
- 基金信息：
  
  国家自然科学基金资助项目;The National Natural Science Foundation of China(61671091);国家自然科学基金资助项目;The National Natural Science Foundation of China(61671452);重庆市科委重点研发项目;The Key R＆D Program of Chongqing Science and Technology Committee(cstc2017zdcy-zdyfX0011;2016070204010132);重庆市社会民生保障项目;Chongqing Social and People’s Livelihood Security Projects(cstc2016shmszx40003)
- DOI：10.11959/j.issn.2096-3750.2018.00059
  中图分类号： TP393
- 纸质出版日期：2018-09-30，
  
  网络出版日期：2018-09，
- 稿件说明：
移动端阅览
林金朝, 柏桐, 李国权, 等. 人体局域网技术需求与挑战[J]. 物联网学报, 2018,2(3):11-20.

JINZHAO LIN, TONG BAI, GUOQUAN LI, et al. Technological requirements and challenges of body area networks. [J]. Chinese journal on internet of things, 2018, 2(3): 11-20.
林金朝, 柏桐, 李国权, 等. 人体局域网技术需求与挑战[J]. 物联网学报, 2018,2(3):11-20. DOI： 10.11959/j.issn.2096-3750.2018.00059.

JINZHAO LIN, TONG BAI, GUOQUAN LI, et al. Technological requirements and challenges of body area networks. [J]. Chinese journal on internet of things, 2018, 2(3): 11-20. DOI： 10.11959/j.issn.2096-3750.2018.00059.

摘要

人们对于远程医疗的巨大需求，使得与之相关的人体局域网（BAN

body area network）技术引起了业界广泛关注。BAN系统通过将无线传感器植入人体体内或置于体表，实现对人体体征参数的实时监测与远程诊断，可应用于医疗、健康和娱乐等多个方面。BAN 技术对功耗、服务质量（QoS）、传输速率、安全性能等有更高的技术需求，在此基础上，讨论了体征信息感知、无线数据传输、信息安全以及芯片设计等关键技术的研究现状及发展趋势，分析了BAN应用所面临的各种挑战。

Abstract

With the development of ubiquitous networks and huge requirements of tele-medicine

an emerged new technology of body area network (BAN) has attracted extensive attention.BAN system could be used for medical

personal health and entertainment applications by implanting wireless sensors into or around the human body

which realized real-time detection and diagnosis of physical vital signs.However

BAN had more stringent requirements on power consumption

quality of service (QoS)

security performance and other specifications.Based on its technological requirements

the research status and development trends of key technologies were discussed deeply

such as information perception of vital signs

wireless transmission

information security and integrated circuit design

and the faced challenges in applications were analyzed.

关键词

人体局域网体征信息感知无线传输技术信息安全芯片设计

Keywords

body area networkinformation perception of vital signswireless transmission technology

references

BARAKAH D M, AMMADUDDIN M . A survey of challenges and applications of wireless body area network (WBAN) and role of a virtual doctor server in existing architecture[C]// 2012 IEEE International Conference on Intelligent Systems Modelling and Simulation. 2012: 214-219.

SHANKAR S K, TOMAR A S . A survey on wireless body area network and electronic-healthcare[C]// 2017 IEEE International Conference on Recent Trends in Electronics,Information ＆ Communication Technology. 2017.

GBD Obesity Collaborators, AFSHIN A, FOROUZANFAR M H ,et al. Health effects of overweight and obesity in 195 countries over 25 years[J]. New England Journal of Medicine, 2017,377(15): 13-27.

CAVALLARI R, MARTELLI F, ROSINI R ,et al. A survey on wireless body area networks:technologies and design challenges[J]. IEEE Communications Surveys ＆ Tutorials, 2014,16(3): 1635-1657.

HANSON M A, JR H C P, BARTH A T ,et al. Body area sensor networks:challenges and opportunities[J]. Computer, 2009,42(1): 58-65.

PATEL M, WANG J . Applications,challenges,and prospective in emerging body area networking technologies[J]. IEEE Wireless Communications, 2010,17(1): 80-88.

JUNG J, HA K, LEE J ,et al. Wireless body area network in a ubiquitous healthcare system for physiological signal monitoring and health consulting[J]. International Journal of Signal Processing Image Processing ＆ Pattern Recognition, 2008,1(1).

WANG H, BAI T, PANG Y ,et al. The dynamic encryption methodbased on ecg characteristic value[C]// International Conference in Communications,Signal Processing and Systems. Springer,Singapore, 2016: 431-438.

ZOU Y, HAN J, XUAN S ,et al. An energy-efficient design for ECG recording and R-Peak detection based on wavelet transform[J]. IEEE Transactions on Circuits ＆ Systems II Express Briefs, 2015,62(2): 119-123.

GOODFELLOW J, ESCALONA O J, KODOTH V ,et al. Denoising and automated r-peak detection in the ECG using discrete wavelet transform[C]// Computing in Cardiology Conference. IEEE, 2017.

YAZDANI S, VESIN J M . Adaptive mathematical morphology for QRS fiducial points detection in the ECG[J]. 2014: 725-728.

SONG L, WANG Y, GUAN L . A P-wave detection method in ECG based on multi-feature and wavelet-amplitude threshold[C]// International Conference on Information and Communications Technologies. IET, 2014:3.093.

LEUTHEUSER H, GRADL S, ANNEKEN L ,et al. Instantaneous Pand T-wave detection:assessment of three ECG fiducial points detection algorithms[C]// IEEE,International Conference on Wearable and Implantable Body Sensor Networks. IEEE, 2016: 329-334.

BALOUCHESTANI M, RAAHEMIFAR K, KRISHNAN S . A high reliability detection algorithm for wireless ECG systems based on compressed sensing theory[C]// Engineering in Medicine and Biology Society. IEEE, 2013: 4722-4725.

庞宇, 邓璐, 林金朝 ,等. 基于形态滤波的心电信号去除基线漂移方法[J]. 物理学报, 2014,63(9): 98701-098701.

PANG Y, DENG L, LIN J Z ,et al. A method of removing baseline drift in ECG signal based on morphological filtering[J]. Acta Physica Sinica, 2014,63(9): 98701-098701.

KHAN I, NECHAYEV Y I, HALL P S . On-body diversity channel characterization[J]. IEEE Transactions on Antennas ＆ Propagation, 2010,58(2): 573-580.

SMITH D B, MINIUTTI D, LAMAHEWA T A ,et al. Propagation models for body-area networks:a survey and new outlook[J]. IEEE Antennas ＆ Propagation Magazine, 2014,55(5): 97-117.

CHAGANTI V, HANLEN L, SMITH D . Are narrowband wireless on-body networks wide-sense stationary[J]. IEEE Transactions on Wireless Communications, 2014,13(5): 2432-2442.

AOYAGI T, ISWANDI , KIM M ,et al . Body motion and channel response of dynamic body area channel[C]// European Conference on Antennas and Propagation. IEEE, 2011: 3138-3142.

FU R, PAHLAVAN K . Characteristic and modeling of human body motions for body area network applications[J]. International Journal of Wireless Information Networks, 2012,19(3): 219-228.

PANG Y, LEI Q, Lin J ,et al. Channel models of body area networks[J]. Sensor Letters, 2013,11(4): 731-735.

IEEE 802.15(TG6).IEEE Std 802.15.6TM-2012[S].2012. 2012.

ULLAH S, HIGGINS H, BRAEM B ,et al. A comprehensive survey of wireless body area networks[J]. Journal of Medical Systems, 2012,36(3): 1065-1094.

MA H H, YU C Y, YU J Y ,et al. A synchronization method for crystal-less OFDM-based wireless body area network applications[C]// Soc Design Conference. IEEE, 2010: 448-451.

LIN J, ZHOU Y, PANG Y ,et al. A low-power circuit for BPSK and QPSK demodulation for body area networks applications[C]// International Symposium on Bioelectronics and Bioinformatics. IEEE, 2011: 240-243.

WANG J, HAN K, ALEXANDRIDIS A ,et al. A baseband processing ASIC for body area networks[J]. Journal of Ambient Intelligence ＆Humanized Computing, 2018(9): 1-8.

OMENI O, WONG A, BURDETT A J ,et al. Energy efficient medium access protocol for wireless medical body area sensor networks[J]. IEEE Transactions on Biomedical Circuits ＆ Systems, 2008,2(4):251.

MARINKOVIĆ SJ, POPOVICI EM, SPAGNOL C ,et al. Energy-efficient low duty cycle MAC protocol for wireless body area networks[J]. IEEE Transactions on Information Technology in Biomedicine a Publication of the IEEE Engineering in Medicine ＆ Biology Society, 2009,13(6):915.

AMEEN M A, LIU J, ULLAH S ,et al. A power efficient MAC protocol for implant device communication in Wireless Body Area Networks[C]// Consumer Communications and NETWORKING Conference. IEEE, 2011: 1155-1160.

LIU B, YAN Z, CHEN C W . Medium access control for wireless body area networks with QoS provisioning and energy efficient design[J]. IEEE Transactions on Mobile Computing, 2017,16(2): 422-434.

LI Y . A cross-layer optimization design for implanted BAN communication system[J]. 医工所科研产出, 2012.

BOULIS A, SMITH D, MINIUTTI D ,et al. Challenges in body area networks for healthcare:the MAC[J]. Communications Magazine IEEE, 2012,50(5): 100-106.

MAMAN M, OUVRY L . BATMAC:an adaptive TDMA MAC for body area networks performed with a space-time dependent channel model[C]// International Symposium on Medical Information ＆ Communication Technology. IEEE, 2011: 1-5.

LIN C H, LIN C J, CHEN W T . Channel-aware polling-based MAC protocol for body area networks:design and analysis[J]. IEEE Sensors Journal, 2017,PP(99): 1-1.

TONG B, LIN J, PANG Y ,et al. A protocol with self-adaptive guard band for body area networks[J]. IET Communications, 2018.

LIU J, LI Q, YAN R ,et al. Efficient authenticated key exchange protocols for wireless body area networks[J]. Eurasip Journal on Wireless Communications ＆ Networking, 2015,2015(1):188.

GANGADARI B R, AHAMED S R . Design of cryptographically secure AES like S-Box using second-order reversible cellular automata for wireless body area network applications[J]. Healthcare Technology Letters, 2017,3(3): 177-183.

HO J M, . A versatile suite of strong authenticated key agreement protocols for body area networks[C]// Wireless Communications and Mobile Computing Conference. IEEE, 2012: 683-688.

LI F, HONG J . Efficient certificateless access control for wireless body area networks[J]. IEEE Sensors Journal, 2016,16(13): 5389-5396.

CHAN H, PERRIG A, SONG D . Random key predistribution schemes for sensor networks[J]. Symposium on Security and Privacy, 2003: 197-213.

LIU D, NING P, DU W . Group-based key predistribution for wireless sensor networks[J]. ACM Transactions on Sensor Networks (TOSN), 2008,4(2): 1-30.

WANG H, FANG H, XING L ,et al. An integrated biometric-based security framework using wavelet-domain HMM in wireless body area networks (WBAN)[C]// IEEE International Conference on Communications. IEEE, 2011: 1-5.

SEEPERS R M, STRYDIS C, SOURDIS I ,et al. Enhancing heart-beat-based security for mhealth applications[J]. IEEE Journal of Biomedical ＆ Health Informatics, 2017,21(1): 254-262.

BAI T, LIN J, LI G ,et al. A lightweight method of data encryption in BANs using electrocardiogram signal[J]. Future Generation Computer Systems, 2018.

WU Y, WANG K, SUN Y ,et al. R2NA:received signal strength (RSS) ratio-based node authentication for body area network[J]. Sensors, 2013,13(12): 16512-16532.

YUAN J, SHI L, YU S ,et al. Authenticated secret key extraction using channel characteristics for body area networks[C]// ACM Conference on Computer and Communications Security. ACM, 2012: 1028-1030.

LI Z Z, WANG H G, DANESHMAND M ,et al. Secure and efficient key generation and agreement methods for wireless body area networks[C]// IEEE International Conference on Communications. IEEE, 2017: 1-6.

ZHANG Z, WANG H, VASILAKOS A V ,et al. Channel information based cryptography and authentication in wireless body area networks[C]// International Conference on Body Area Networks. 2013: 132-135.

JAVALI C, REVADIGAR G, LIBMAN L ,et al. SeAK:secure authentication and key generation protocol based on dual antennas for wireless body area networks[M]. Springer International Publishing, 2014: 74-89.

LAI L, LIANG Y, DU W . Cooperative key generation in wireless networks[J]. IEEE Journal on Selected Areas in Communications, 2012,30(8): 1578-1588.

WANG J, HAN K, ALEXANDRIDIS A ,et al. An ASIC implementation of security scheme for body area networks[C]// IEEE International Symposium on Circuits and Systems. IEEE, 2018: 1-5.

LIU X, PHYU M W, WANG Y ,et al. An ultra low power baseband transceiver IC for wireless body area network in 0.18-$\mu$ m CMOS technology[C]// IEEE Transactions on Very Large Scale Integration Systems. 2011: 1418-1428.

CHEN M, HAN J, FANG D ,et al. An ultra low-power and area-efficient baseband processor for WBAN transmitter[C]// Signal and Information Processing Association Summit and Conference. IEEE, 2013: 1-4.

LIANG Y, ZHOU Y, LI Y . The design and implementation of IEEE 802.15.6 baseband on FPGA[J]. 2013.

CHOUGRANI H, SCHWOERER J, HORREN P H ,et al. UWB-IRdigital baseband architecture for IEEE 802.15.6 wireless BAN[C]// IEEE International Conference on Electronics,Circuits and Systems. IEEE, 2014: 866-869.

浏览量

1259

下载量

CSCD

文章被引用时，请邮件提醒。

提交

工具集

关联资源

暂无数据