|
|
|
| The Development of Wearable Technologies |
1 Shenzhen Institutes of Advanced Technologies, Chinese Academy of Sciences, Shenzhen 518055, China
2 Shenzhen Key Laboratory of LowCost Healthcare, Shenzhen 518055, China
3 School of Information Engineering, Wuhan University of Technology, Wuhan 430070, China |
|
|
|
|
Abstract In this paper, the connotations and extensions of wearable technologies were expounded, and the origins of the technique development and histories were summarized from the stateofart of wearable technologies. Then the key technologies were introduced mainly including communication technology, chips, sensors and flexible components. The wearable operation systems and interactive models were concluded. The common application scenes were stated as well as the research orients. The study discussed the research contents and applications of wearable technologies, which formed a research frame of wearable technologies.
|
|
|
|
|
|
[1]Amft O, Lukowicz P. From backpacks to smartphones:
past, present, and future of wearable computers[J]. IEEE Pervasive Computing, 2009, 3: 8-13.
[2]Zheng XS, Foucault C, Matos da Silva P, et al. Eyewearable technology for machine maintenance: effects of display position and handsfree operation[C]//Bo Begole. Proceedings of the 33rd Annual ACM Conference on Human Factors in Computing Systems. New York: ACM, 2015: 2125-2134.
[3]Gao Yiwen, Li He, Luo Yan. An empirical study of wearable technology acceptance in healthcare [J]. Industrial Management & Data Systems, 2015, 115(9): 1261-1267.
[4]Shore JH, Aldag M, McVeigh FL, et al. Review of mobile health technology for military mental health [J]. Military Medicine, 2014, 179(8): 865-878.
[ 5]Vallurupalli SD, Paydak H, Agarwal SH, et al. Wearable technology to improve education and patient outcomes in a cardiology fellowship programa feasibility study [J]. Health and Technology, 2013, 3(4): 267-270.
[6]Jackson MM, Valentin G, Freil L, et al. Facilitating interactions for dogs with occupations: wearable communication interfaces for working dogs [J]. Personal and Ubiquitous Computing, 2015, 19(1): 155-173.
[7]Marson SM. A selective history of Internet technology and social work [J]. Computers in Human Services, 1997, 14(2): 35-49.
[8]McQuillan JM, Falk G, Richer I. A Review of the development and performance of the ARPANET routing algorithm[J]. IEEE Transactions on Communications, 1978, 26(12): 1802-1811.
[9]Rogers JD. Internet working and the politics of science: NSFNET in Internet history[J]. The Information Society, 1998, 14(3): 213-228.
[10]Crovella ME, Bestavros A. Selfsimilarity in world wide Web traffic: evidence and possible causes[J]. IEEE/ACM Transactions on Networking, 1997, 5(6): 835-846.
[11]戴建忠.电子商务概论[M]. 2版. 北京:清华大学出版社,2012:87-88.
[12]尹育新,戎宏娜.浅谈一种全新的网络技术: 物联网[J]. 信息系统工程,2010,2:105-106.
[13]Mattern F, Floerkemeier C. From the Internet of computers to the Internet of Things[M]//From Active Data Management to EventBased Systems and More. Berlin:Springer Berlin Heidelberg, 2010:242-259.
[14]陈东义.可穿戴式计算机的发展与趋势[J].重庆大学学报:自然科学版,2000,3:119-124.
[15]栾相科.国产可穿戴设备点线面联动布局[J].中国战略新兴产业,2014,18:18.
[16]Gubbi J, Buyya R, Marusic S, et al. Internet of things (IoT): a vision, architectural elements and future directions[J]. Future Generation Computer Systems, 2013, 29(7): 1645-1660.
[17]Wei J. How wearables intersect with the Cloud and the Internet of things: considerations for the developers of wearables[J]. IEEE Consumer Electronics Magazine, 2014, 3〖STBZ〗(3): 53-56.
[18]梁健航. 可穿戴设备, 社交有陷阱[J]. 新营销, 2014, 12:38-40.
[19]Haartsen J. Bluetooth: The universal radio interface for ad hoc, wireless connectivity[J]. Ericsson Review, 1998, 3(1): 110-117.
[20]Gomez C, Oller J, Paradells J. Overview and evaluation of bluetooth low energy: an emerging lowpower wireless technology [J]. Sensors, 2012, 12(9): 11734-11753.
[21]Wang CY, Wei HY. IEEE 80211 n MAC enhancement and performance evaluation[J]. Mobile Networks and Applications, 2009, 14(6):760-771.
[22]单祥茹. TI 再次扩充IoT低功耗无线连接产品阵营 [J].中国电子商情: 基础电子,2015,416-17.
[23]Misra P, Enge P. Global positioning system: signals, measurements and performance [M]. 2nd ed. Lincoln: GangaJamuna Press, 2006: 1-89.
[24]江兴. Broadcom推出面向移动应用的先进单片GPS解决方案[J]. 半导体信息, 2008(2): 27.
[25]Wegmueller MS, Kuhn A, Froehlich J, et al. An attempt to model the human body as a communication channel[J]. IEEE Transactions on Biomedical Engineering, 2007, 5410): 1851-1857.
[26]Want R. Near field communication [J]. IEEE Pervasive Computing, 2011, 10(3): 4-7.
[27]Baronti P, Pillai P, Chook VWC, et al. Wireless sensor networks: a survey on the state of the art and the 80215 4 and ZigBee standards[J]. Computer Communications, 2007, 307): 1655-1695.
[28]Ng KA, Chan PK. A CMOS analog frontend IC for portable EEG/ECG monitoring applications[J]. IEEE Transactions on Circuits and Systems I , 2005, 52(11): 2335-2347.
[29]Yang CC, Hsu YL. A review of accelerometrybased wearable motion detectors for physical activity monitoring[J]. Sensors, 2010, 10(8): 7772-7788.
[30]Shichiri M, Asakawa N, Yamasaki Y, et al. Telemetry glucose monitoring device with needletype glucose sensor: a useful tool for blood glucose monitoring in diabetic individuals[J]. Diabetes Care, 1986, 9(3): 298-301.
[31]Fiala J, Bingger P, Ruh D, et al. An implantable optical blood pressure sensor based on pulse transit time [J]. Biomedical Microdevices, 2013, 15(1): 73-81.
[32]Han D, Zheng Y, Je M. A 018μm front end for ECG/EEG/neural sensor interface[C]// Ong M. Proceedings of the 2012 IEEE International Symposium on RadioFrequency Integration Technology (RFIT). New York: IEEE, 2012: 107-109.
[33]Chang H, Sun Z, Ho KYF, et al. A highly sensitive ultraviolet sensor based on a facile in situ solutiongrown ZnO nanorod/graphene heterostructure[J]. Nanoscale, 2011, 3(1): 258-264.
[34]Ding G, Sandtner J, Bleuler H. A novel flexible PCB conductive structure for electrodynamic bearings and measurement in its induced voltage[J]. Journal of Electrical Engineering & Technology, 2015, 10:2001-2008.
[35]Chou JC, Tsai YL, Cheng TY, et al. Fabrication of arrayed flexible screenprinted glucose biosensor based on microfluidic framework[J]. IEEE Sensors Journal , 2014, 141): 178-183.
[36]Chowdhury GG. Natural language processing [J]. Annual Review of Information Science and Technology, 2003, 37(1): 51-89.
[37]Meeng M, Knobbe A. Flexible enrichment with Cortana–software demo[C]// Bosch A. Proceedings of BeneLearn. Nijmegen: TexKernel, 2011: 117-119.
[38]Ren Z, Meng J, Yuan J, et al. Robust hand gesture recognition with kinect sensor[C]//Proceedings of the 19th ACM International Conference on Multimedia. New York: ACM, 2011: 759-760.
[39]Stahl JS, Van Alphen AM, De Zeeuw CI. A comparison of video and magnetic search coil recording of mouse eye movements [J]. Journal of Neuroscience Methods, 2000, 99(1):101-110.
[40]Schmitt KU, Muser MH, Lanz C, et al. Comparing eye movements recorded by search coil and infrared eye tracking [J]. Journal of Clinical Monitoring and Computing, 2007, 21(1):49-53.
41]李卫娜,侯文生,郑小林,等. 基 于 Electrooculogram 的眼动信息识别[J]. 仪器仪表学报,2007,28(8):1428-1433.
[42]汤小丹,梁红兵.计算机操作系统 [M]. 西安:西安电子科技大学出版社,2007.
[43]Inam R, MkiTurja J, Sjdin M, et al. Hard realtime support for hierarchical scheduling in FreeRTOS[C]// Arzen KE, Proceedings of the 23rd Euromicro Conference on RealTime Systems. Los Alamitos: IEEE Computer Society, 2011: 51-60.
[44]Norum WE. EPICS on the RTEMS realtime executive for multiprocessor systems[J]. Review of Scientific Instruments, 2002, 73(3): 1560-1562.
[45]Massa AJ. Embedded software development with eCos [M]. New Jersy: Prentice Hall Professional, 2003: 1-10.
[46]Mishra SM. Android wear platform [M]//Wearable Android: Android wear and Google fit App development, New York: Wiley, 2015: 121-168.
[47]Riches G, Martinez Jr R, Maison J, et al. An Apple watch introduction [M]//Riches G. Apple Watch for Developers. New York: Apress, 2015: 19-25.
[48]Gadyatskaya O, Massacci F, Zhauniarovich Y. Security in the Firefox OS and Tizen mobile platforms [J]. Computer, 2014 (6): 57-63.
[49]关天瑜. 腾讯TOS系统联手inWatch布局智能手表[J]. 计算机与网络, 2015(12): 10.
[50]黎明. 阿里云初体验[J].个人电脑, 2014(11): 89-93.
[51]Fong E M, Chung W Y. Mobile cloudcomputingbased healthcare service by noncontact ECG monitoring[J]. Sensors, 2013, 13(12): 16451-16473.
[52]Wan C, Szymkiewicz SJ. Left ventricular function improvement after recent MI in patients using a wearable cardioverter defibrillator[J]. Circulation, 2014, 130(Suppl 2): A18973-A18973.
[53]Simon BJ, Errico JP, Raffle JT. Noninvasive magnetic or electrical nerve stimulation to treat or prevent dementia: U.S. Patent Application 13/671,859[P]. 2012-11-8.
[54]Quy RJ. Method and apparatus for exercise monitoring combining exercise monitoring and visual data with wireless wearable devices: U.S. Patent Application 14/220,682[P]. 2014-3-20.
[55]Parak J, Tarniceriu A, Renevey P, et al. Evaluation of the beattobeat detection accuracy of pulse on wearable optical heart rate monitor[C]//Cerutti S. Proceedings of the 37th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC). New York: IEEE, 2015:8099-8102.
[56]Lee S, Yan L, Roh T, et al. A 75 W realtime scalable body area network controller and a 25 W ExG sensor IC for compact sleep monitoring applications[J]. IEEE Journal of SolidState Circuits, 2012, 47(1): 323-334.
[57]GonzálezValenzuela S, Chen M, Leung V. Mobility support for health monitoring at home using wearable sensors[J]. IEEE Transactions on Information Technology in Bimedicine, 2011, 15(4): 539-549.
[58]Thampan T, Shah D, Cook C, et al. Development and evaluation of portable and wearable fuel cells for soldier use[J]. Journal of Power Sources, 2014, 259: 276-281.
|
|
|
|
