Unjukkerja Standar ZigBee pada WPAN dengan Topologi Mesh
Abstract
ZigBee standard can be used in wireless sensor networks (WSN) with a mesh topology. WSN which formed WPAN that uses ZigBee standard has the capability to thousands of WSN devices can be combined in a single WPAN. With that ability need to do testing WPAN performance parameters to get the number of WSN devices for the best performance in mesh topology. Using simulation program, the research measure throughput, traffic (sent, receive and drop), delay and hop number parameters. Testing about the influence of the number of WSN devices is done by running a simulation of the 20 kind WPAN where every WPAN has one WSN gateway and the number of WSN devices ranging from 5 and increasingly by 5 to reach the 100 WSN devices in a single WPAN. The results showed that WPAN performance with ZigBee standard in mesh topology has the best conditions when the maximum number WSN devices achieve 20 WSN devices.
References
Leung Sam, Gomez Wil, Kim Jung Jun, ZigBee Mesh Network Simulation Using Opnet and Study of Routing Selection, Final Project Communication Networks, Simon Fraser University (SFU), 2009.
Myung J. Lee, Rui Zhang, Jianliang Zheng, Gahng-Seop Ahn, Chunhui Zhu, Tae Rim Park, Sung Rae Cho, Chang Sub Shin, And Jun Sun Ryu, WPAN Mesh Standard Low Rate Part: Meshing the Wireless Sensor Networks, IEEE Journal On Selected Areas In Communications, 2010,Vol. 28, No. 7, pp. 973 983.
Hammoodi, I.S. Stewart B.G. Kocian A. McMeekin S.G., A Comprehensive Performance Study of OPNET Modeler For ZigBee Wireless Sensor Networks, Third International Conference on Next Generation Mobile Applications, Services and Technologies, 2009, pp 357- 362.
Devineni Abhiram, Performance Evaluation of Body Area Network Using ZigBee Protocol, Thesis, San Diego State University, 2011.
Hnatyshin Vasil, Asenov Hristo And Robinson John, Practical Methodology For Modeling Wireless Routing Protocols Using Opnet Modeler, Department of Computer Science, Rowan University, 2010.
Sajjad A. Madani, Jawad Kazmi, Stefan Mahlknecht, Wireless Sensor Networks: Modeling and Simulation, Vienna University of Technology, Vienna, Austria, 2010.
Chung Ming Huang, Yuh Shyan Chen, Telematics Communication Technologies and Vehicular Networks: Wireless Architectures and Applications, Information Science Reference, 2010.
Sinan Gezici, Ulas C. Kozat, Reliable Communications for Short Range Wireless Systems, University Press, Cambridge, 2011.
J. Zhang, P. P. Orlik, Z. Sahinoglu, A. F. Molisch, and P. Kinney, UWB Systems for Wireless Sensor Networks, Proc. IEEE, 2009, vol. 97, no. 2, pp. 313 331.
Daintree Networks, Mesh Networks?, white paper, 2007.
ZigBee Alliance, ZigBee Wireless Sensor Applications for Health, Wellness and Fitness, white paper, 2009.
B. Heile, Wireless Sensors and Control Networks: Enabling New Opportunities with ZigBee, San Jose, CA, ZigBee Alliance Tutorial, 2006.
R. Kraemer and M. D. Katz, Short Range Wireless Communications: Emerging Technologies and Applications, 1st ed. Chichester, UK: John Wiley, 2009.
IEEE Computer Society, Part 15.4: Wireless Medium Access Control (MAC) and Physical Layer (PHY) Specifications for Low Rate Wireless Personal Area Networks (WPANs) (Revision of IEEE Std 802.15.4-2003), Institute of Electrical and Electronics Engineers, 2006.
Pei Zheng, Feng Zhao, David Tipper, Wireless Networking Complete, Morgan Kaufmann Publishers, USA, 2010.
Xiang Yang Li, Wireless Ad Hoc and Sensor Networks, Cambridge University Press, 2008.
Lukosius Arturas, Opportunistic Routing in Multi-Sink Mobile Ad Hoc Wireless Sensor Networks, Master Thesis, Communication Networks, University of Bremen, 2007.
Magsino Kristoffer Clyde, Kamath H. Srikanth, Simulation of Routing Protocols of Wireless sensor Networks, World Academy of Science, Engineering and Technology, pp. 211 213, 2009.
Cho Kideok, Le Mun Young, Ko Dong-il, Kwon Taek Young, Choi Yanghee, An Efficient Multicast Routing in IEEE 802.15.5 Networks, Computer Science and Engineering, Seoul National University, 2009.
IEEE Standard for Information Technology, Telecommunications and Information Exchange Between Systems, Local and Metropolitan Area Networks Specific Requirements, available online: http://standards.ieee.org/getieee802/download/802.15.4-2006.pdf, 2006.
Ismail Guvenc, Zafer Sahinoglu, ZigBee Networks and Low-Rate UWB Communications, University Press, Cambridge, 2011.
IEEE 802.15 Working Group for WPAN, available online: http://ieee802.org/15/index.html
Thonet Gilles, Allard-Jacquin Patrick, Colle Pierre, ZigBee WiFi Coexistence, White Paper and Test Report, Schneider Electric, 2008.
Binhack Michael, Kupris Gerald, Customer Specific Wireless Network Solutions Based on Standard IEEE 802.15.4, Freescale Semiconductor GmbH, Germany, 2006.
Burchfield T. Ryan and S. Venkatesan, Maximizing Throughput in ZigBee Wireless Networks through Analysis, Simulations and Implementations, Computer Engineering Program, University of Texas at Dallas, 2006.
© Jurnal Nasional Teknik Elektro dan Teknologi Informasi, under the terms of the Creative Commons Attribution-ShareAlike 4.0 International License.