Обзор технологий беспроводных нательных сетей

Обзор технологий беспроводных нательных сетей

Автор: Злотникова Римма Евгеньевна

Журнал: Проблемы информатики @problem-info

Рубрика: Прикладные информационные технологии

Статья в выпуске: 1 (38), 2018 года.

Бесплатный доступ

В данной статье рассматриваются беспроводные нательные сети (WBAN), обосновывается их актуальность, предоставляются сведения о сферах их применения. Рассматривается классификация WBAN с точки трения используемой технологии беспроводной связи. Перечисляются основные системные требования, такие как скорость передачи данных, диапазон используемых частот, уровень потребляемой мощности передатчиков, показатели качества обслуживания и некоторые другие. Приводится обзор стандартов для реализации WBAN: IEEE 802.15.4 и IEEE 802.15.6. Сообщается о некоторых характеристиках устройств и основных проблемах при проектировании и реализации WBAN.

Еще

Беспроводные сети, технологии беспроводной связи, беспроводные на¬тельные сети, мониторинг, датчики, классификация, топология, системные требования, потребляемая мощность

Короткий адрес: https://sciup.org/143167057

IDR: 143167057

Список литературы Обзор технологий беспроводных нательных сетей

  • Milenkovic, С. Отто, and E. Jovanov. Wireless sensor networks for personal health monitoring: Issues and an implementation//Computer Communications. Special issue: Wireless Sensor Networks: Performance, Reliability, Security, and Beyond. 2006. V. 29. P. 2521-2533.
  • Денисенко M. Б. Население России до 2025 года//Pro et Contra. 2012. Т. 16. № 4-5. С. 153-170.
  • Chen XL. Gonzalez S., Vasilakos A., Cao II. and Leung V. Body area networks: A survey//Mobile Networks and Applications. 2011. V. 16. P. 171 193.
  • Ullah S., Shen В., Islam S. M. R., Khan P., Saleem S., and Kwak K. S. A study of medium access control protocols for wireless body area networks/arXiv preprint arXiv: 1004.3890, 2010.
  • IEEE standard for local and metropolitan area networks: Part 15.6: Wireless body area networks//IEEE submission, February 2012.
  • Smith and L. Hanlen. Wireless body area networks: Towards a wearable intranet. ISCIT Tutorial, September 2012.
  • Kwon H. and Lee S. Energy-efficient multi-hop transmission in body area networks//in 20th IEEE Int. Symp. on Personal, Indoor and Mobile Radio Commun. (PIMRC). September 2009. P. 2142-2146.
  • Hanson XL. Powell II. Barth A., Ringgenberg K., Calhoun В., Avion J., and Lach J. Body area sensor networks: Challenges and opportunities//Computer. Jan. 2009. V. 42. P. 58-65.
  • DlSHMAN. Inventing wellness systems for aging in place//Computer. May 2004. V. 37. P. 3 I II.
  • Xing J. and Zhu Y. A survey on body area network,//in 5th Int. Conf. on Wireless Communications. Networking and Mobile Computing (WiCom '09). Sept. 2009. P. 1-4.
  • Ullah S., Higgin H., Siddiqui M. A., and Kwak K. S. A study of implanted and wearable body sensor networks//in Proc. 2nd KES Int. Conf. on Agent and multi-agent systems: technologies and applications, (Berlin, Heidelberg). Springer-Verlag. 2008. P. 161-173.
  • Wang B. and Pei Y. Body area networks/Encyclopedia of Wireless and Mobile Communications, Edited by Borko Furht, Taylor and Francis. 2007. V. 98.
  • Ullah S., Khan P., Ullah N., Saleem S., Higgins II. and Kwak K. A review of wireless body area networks for medical applications/arXiv preprint arXiv:1001.0831. 2010. V. abs/1001.0831.
  • LlPPRANDT M., ElCHELBERG M., THRONICKE W., KRUGER J., DRUKE I. WlLLEMSEN D., BUSCH C, FlEHE C, Zeeb E., and Hein A. Osamid: An open service platform for healthcare monitoring applications//in 2nd Conf. on Human System Interactions (HSI'09). IEEE, 2009. P. 139 -145.
  • Nehmer J., Becker M., Karshmer A., and Lamm R. Living assistance systems: an ambient intelligence approach//in Proc. 28th Int. Conf. on Software engineering. ACM, 2006. P. 13-51).
  • Latre В., Braem В., Moerman I. Blondia ('. and Demeester P. A survey on wireless body area networks//Wlrless Network. Jan. 2011. V. 17. P. 1-18.
  • N. de Vicq, Robert F., Penders J., Gyselinckx В., and Torfs T. Wireless body area network for sleep staging//in IEEE Biomedical Circuits and Systems Conf. (BIOCAS 2007). 2007. P. 163-166.
  • Lewis D. 802.15.6 call for applications-response summary/in 1508-0407-00-0006-tg6-applications-summary.doc.
  • Gopalan S. and Park J.-T. Energy-efficient mac protocols for wireless body area networks: Survey//in Ultra Modern Telecommunications and Control Systems and Workshops (ICUMT) Int. Congress. 2010. P. 739-744.
  • Smith D., Miniutti D., Lamahewa T. A., and Hanlen L. Propagation models for body area networks: A survey and new outlook//IEEE Antennas and Propagation Mag., Dec. 2013.
  • Carrano R., Passos D., Magalhaes L., and Albuquerque C. Survey and taxonomy of duty cycling mechanisms in wireless sensor networks//IEEE Commun. Surveys Tutorials. 2013. V. P. N 99. P. 1-14.
  • Sudevalayam S. and Kulkarni P. Energy harvesting sensor nodes: Survey and implications//IEEE Commun. Surveys Tutorials. 2011. V. 13. N 3. P. 443-461.
  • Specification of the Bluetooth System version 4.0. Bluetooth SIC June 2010. : http://www.bluetooth.com.
  • Patel M. and Wang J. Applications, challenges, and prospective in emerging body area networking technologies//IEEE Trans. Wireless Commun. Feb. 2010. V. 17. N 1. P. 80-88.
  • Cao H., Leung V., Chow C, and Chan H. Enabling technologies for wireless body area networks: A survey and outlook//IEEE Commun. Mag. Dec. 2009. V. 47. N 12. P. 84-93.
  • Khan W., Xiang Y., Aalsalem M., and Arshad Q. Mobile phone sensing systems: A survey//IEEE Commun. Surveys Tutorials. 2013. V. 15. N 1. P. 402-427.
  • Bradley P. D. Implantable ultralow-power radio chip facilitates inbody communications//RF DESIGN. 2007. V. 30. N 6. P. 20.
  • Yuce M. R. and Но С. K. Implementation of body area networks based on mics/wmts medical bands for healthcare systems//in 30th Annu. Int. Conf. IEEE Engineering in Medicine and Biology Society, 2008. EMBS 2008. IEEE, 2008. P. 3417-3421.
  • Tachtatzis ('. Franco F., Tracey I). Timmons N., and Morrison J. An energy analysis of IEEE 802.15.6 scheduled access modes//in IEEE GLOBECOM Workshops (GC Wkshps). Dec. 2010. P. 1270-1275.
  • Khan J. Y., Yuce M. R., Bulger G., and Harding B. Wireless body area network (wban) design techniques and performance evaluation//J. of medical systems. 2012. V. 36, N 3. P. 1441-1457.
  • IEEE 802.15.4 Standard, Part 15.4: Wireless Medium Access Control (MAC) and Physical Layer (PHY) Specifications for Low Rate Wireless Personal Area Networks (LR-WTANs). Piscataway, New Jersey, 08855-1331: IEEE, 2006. ://standards.ieee.org/getieee802/802.15.html
  • IEEE standard for local and metropolitan area networks part 15.6: Wireless body area networks. IEEE Std 802.15.6-2012. February 2012. P. 1-271.
  • Reddy P., Reddy P. В., and Reddy V. K. Body area networks//J. of Telematics and Informatics. 2013. V. 1, N 1.
  • Astrin W., Li H.-B., and Kohno R. Standardization for body area networks//IEICE Trans. Commun., 2009. N 2, P. 366-72.
  • Elhadj Ben, Chaari L., and Kamoun L. A survey of routing protocols in wireless body area networks for healthcare applications//Int. J. of E-Health and Medical Commun. (IJEHMC). 2012. P. 1-18.
  • Kwak K., Ullah S., and Ullah N. An overview of IEEE 802.15.6 standard//in 3rd Int. Symp. on Applied Sciences in Biomedical and Communication Technologies (ISABEL). Nov. 2010. P. 1-6.
  • Ullah S., Higgins II. Внаем В., Lathe В., Blondia С, Moerman I. Saleem S., Rahman Z., and Kwak K. A comprehensive survey of wireless body area networks//J. of Medical Systems. 2010. P. 1-30.
  • Nehmer J., Becker M., Karshmer A., and Lamm R. Living assistance systems: an ambient intelligence approach//in Proc. 28th Int. Conf. on Software engineering. ACM, 2006. P. 43-50.
  • Schwoerer Li. Y. Yoon J., Farserotu J., Yang W., Sayrafian K., Miniutti I). and Lewis D. IEEE 802.15.6 regulation subcommittee report. May 2010.
  • Boulis, D. Smith, Miniutti D., Libman L., and Tselishchev Y. Challenges in body area networks for healthcare: the mac//IEEE Commun. Mag. May 2012. V. 50. N 5. P. 100-106.
  • Ullah S., Higgins II. Braem В., Latre В., Blondia ('. Moerman I., Saleem S., Rahman Z., and Kwak K. A comprehensive survey of wireless body area networks//J. of Medical Systems. 2012. V. 36. P. 1065-1094.
  • Nehmer J., Becker XL. Karshmer A., and Lamm R. Living assistance systems: an ambient intelligence approach//in Proc. 28th Int. Conf. on Software engineering. ACM, 2006. P. 15-51).
  • Pantelopoulos and Bourbakis N. A survey on wearable biosensor systems for health monitoring//in 30th Annu. Int. Conf. IEEE Engineering in Medicine and Biology Society 2008. К MBS 2008. P. 4887-4890.
  • Alemdar and C. Ersoy. Wireless sensor networks for healthcare: A survey//Computer Networks. 2010. V. 54. N 15. P. 2688-2710.
  • Kumar S., Kambhatla К., Ни F., Lifson XL. and Xiao Y. Ubiquitous computing for remote cardiac patient monitoring: a survey//Int. J. of telemedicine and applications. 2008. V. 2008. P. 3.
  • Caldeira J., rodrigues J., and Lorenz P. Toward ubiquitous mobility solutions for body sensor networks on healthcare//IEEE Commun. Mag. 2012. V. 50. N 5. P. 108-115.
  • Intra-mobility support solutions for healthcare wireless sensor networks 2013; handover issues//IEEE Sensors J. 2013. V. 13. N 11. P. 4339-4348.
  • Эскиндаров M. А. Место России и перспективы позиционирования в мировом хозяйстве в современных условиях//Внешнеэкономическая политика России в условиях глобальных вызовов: Монография/Финуниверситет; под ред. А. А. Ткаченко. XI. 2015. С. 35-51.
  • Latre, Braem В., Moerman I. Blondia С, and Demeester P. A survey on wireless body area networks//Wireless Netw. 2011. V. 17. N 1. P. 1-18.
  • Shakhov Vladimir V., Migov Denis. Reliability of Ad Hoc Networks with Imperfect Nodes. Lecture Notes in Computer Science. Springer, 2014. V. 8715. P. 49-58.
  • ITU -Radio Regulations. Volume 1, Sectio iv. : http://life.itu.int/radioclub/rr/rindex.htm, 2012.
  • Carrano R., Passos D., Magalhaes L., and Albuquerque C. Survey and taxonomy of duty cycling mechanisms in wireless sensor networks//IEEE Commun. Surveys Tutorials. 2013. V. PP. N 99, P. 1-14.
  • FCC -Medical Body Area Networks -small entity compliance guide. : http://www.fcc.gov/document/medical-body-area-networks, May 2013.
  • ITU TG 1-8 Working Group 1. Characteristics of ultra-wideband (UWTB) devices. : http://wcsp.eng.usf.edu/papers/UWBBasics.doc, Jan., 2003.
  • Chavez-Santiago R., Nolan K., Holland О. I)к Nardis I. Ferro J., Barroca N., Borges L., Velez F., Goncalves V., and Balasingham I. Cognitive radio for medical body area networks using ultra wideband//IEEE Wireless Commun. 2012. V. 19. N 4. P. 71 К1.
  • H о vak ее м i an Y., Naik K., and Nayak A. A survey on dependability in body area networks//Medical Information Commun. Technology (ISMICT), 2011 5th Int. Symp. On. P. 10-14.
  • Lara O. and Labrador M. A survey on human activity recognition using wearable sensors//IEEE Commun. Surveys Tutorials. 2013. v! 15. N 3. P. 1192-1209.
  • Ullah S., Khan P., Ullah N., Saleem S., Higgins II. and Sup Kwak K. A review of wireless body area networks for medical applications//Int. J. of Commun., Netw. and System Sciences. 2009. V. 2. N 8. P. 797 -803.
  • Seyedi XL. Kibret В., Lai D. Т., and Faulkner M. A survey on intrabody communications for body area network applications, 2013.
  • IEEE 802.15.4 Standard, Part 15.4: Wireless Medium Access Control (MAC) and Physical Layer (PHY) Specifications for LowRate Wireless Personal Area Networks (LR-WPANs). Piscataway, New Jersey, 08855-1331: IEEE, 2006. ://standards.ieee.org/getieee802/802.15.html.
  • Вае, Н. Сно, Song К., Lee Н., and Yoo H.-J. The signal transmission mechanism on the surface of human body for body channel communication//IEEE Trans. Microw. Theory Tech. 2012. V. 60. N 3. P. 582-593.
  • Akyildiz F., Brunetti F., and BlAzquez C. Nanonetworks: A new communication paradigm//Comput. Netw. Aug. 2008. V. 52. N 12. P. 2260 -2279.
  • La Polla M., Martinelli F., and Sgandurra D. A survey on security for mobile devices//IEEE Commun. Surveys Tutorials. 2013. V. 15. N 1. P. 446-471.
  • Шахов В. В., Юргенсон А. Н., Соколова О. Д. Моделирование воздействия атаки Black Hole на беспроводные сети//Программные продукты и системы. 2017. Т. 30. № 1. С. 34-39.
  • Shakhov V. V. Protecting Wireless Sensor Networks from Energy Exhausting Attacks, Lecture Notes in Computer Science. 2013. Springer. V. 7971. P. 184-193.
  • Galluccio, Melodia Т., Palazzo S., and Santagati G. Challenges and implications of using ultrasonic communications in intra-body area networks//Wireless On-demand Network Systems and Services (WONS), 2012 9th Annu. Conf. on. 2012. P. 182-189.
  • Shakhov V. V., Koo I., Rodionov A. S. Energy exhaustion attacks in wireless networks//IEEE Int. Conf. on Computer and Information Sciences (SIBIRCON). 2017. P. 1-3.
  • Shakhov V. V., Koo I. Experiment Design for Parameter Estimation in Probabilistic Sensing Models//IEEE Sensors Journal. 2017. V. 17. I. 24. P. 8431-8437.
  • Shakhov V. V. Performance Evaluation of MAC Protocols in Energy Harvesting Wireless Sensor Networks. Lecture Notes in Computer Science. Springer, 2016. V. 9787. P. 344-352.
  • Materukhin A., Shakhov V. V., Sokolova O. D. An efficient method for collecting spatio-temporal data in the WSN using mobile sinks//IEEE Int. Conf. on Computer and Information Sciences (SIBIRCON), 2017. P. 118-120.
Еще
Статья научная
SciUp 2024 © 2024 ©