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IEEE 802.11 Kablosuz Ağlarda Güç‐Tasarruf‐Modunu Etkin Kullanan Yaklaşımlar ve Benzetim Ortamında Mukayeseleri

Year 2016, Volume: 16 Issue: 2, 265 - 275, 30.04.2016

Abstract

IEEE 802.11 kablosuz ağları sağladığı esneklik, uygun fiyatlandırma ve kolay kurulum avantajları ile akıllı
cihazlar tarafından günümüzde en çok kullanılan kablosuz ağ erişim teknolojilerinden biri haline
gelmiştir. Yalnız kablosuz bir ağ arayüzünün akıllı cihazlarda aktif olarak kullanılması, bataryanın hızlı
tüketimine ve etkin kullanım süresinin önemli derecede azalmasına sebep olmaktadır. IEEE 802.11
kablosuz ağ standardları (IEEE 802.11a/b/g/n/ac) kullanıcıların ağa erişiminde Çarpışmadan Kaçınmalı
Taşıyıcı Duyarlı Çoklu Erişim (Carrier Sense Multiple Access with Collision Avoidance (CSMA/CA))
yaklaşımını kullanmaktadır. Bu yaklaşım cihazlar arası paket gönderim işlemlerinin çarpışmaması için
ağın dinlenmesine dayanır. Bu dinleme işlemi sırasında cihazlar önemli derecede güç tüketirler. Bu
sorunun çözümü için kablosuz ağ standardında tanımlanan Güç‐Tasarruf‐Modu (PSM) kulanılabilir.
Kablosuz ağ standardında bu kısım tanımlansa da, kabul edilen herhangi bir standard algoritma
bulunmamaktadır. Dolayısıyla, optimal enerji verimliliği için literatürde sunulan bir çok PSM temelli
yaklaşım mevcuttur. Bu çalışma kapsamında öncelikle literatürde sunulan ve PSM protokolünü etkin
kullanan güncel PSM önerileri incelenmektedir. Sonrasında ise bahsi geçen öneriler OMNET benzetim
ortamına aktarılarak enerji verimliliği mukayese edilmektedir.

References

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  • Balaji B., Tamma B.R., and Manoj B., 2010. A novel power saving strategy for greening IEEE 802.11 based wireless networks. GLOBECOM, Florida, USA.
  • Ding N., Pathak A., Koutsonikolas D., Shepard C., Hu Y.C., and Zhong L., 2012. Realizing the full potential of psm using proxying. INFOCOM, Orlando, FL. He, Y. and Yuan R., 2009. A novel scheduled power saving mechanism for 802.11 wireless LANs. Mobile Computing, IEEE Transactions on 8(10): 1368‐1383.
  • Jang K.Y., Hao S., Sheth A., and Govindan R., 2011. Snooze: energy management in 802.11 n WLANs. Conference on emerging Networking Experiments and Technologies, New York, USA.
  • Jung D., Kim R., and Lim H., 2014. Power‐saving strategy for balancing energy and delay performance in WLANs. Computer Communications 50: 3‐9.
  • Jung E.S., and Vaidya N., 2002. A power saving mac protocol for wireless networks. INFOCOM, NY, USA. Jung E.S., and Vaidya N.H., 2008. Improving IEEE 802.11 power saving mechanism. Wireless Networks 14(3): 375‐391.
  • Kravets R., and Krishnan P., 1998. Power management techniques for mobile communication. ACM/IEEE international conference on Mobile computing and networking, Dallas, Texas.
  • Langendoen K., and Halkes G., 2005. Energy‐efficient medium access control. Embedded systems handbook, 34, 31‐34.
  • Li Y., Zhang X., and Yeung K.L., A novel delayed wakeup scheme for efficient power management in infrastructure‐based IEEE 802.11 WLANs. Wireless Communications and Networking Conference (WCNC), New Orleans, USA.
  • Manweiler J., and Choudhury R.R., 2011. Avoiding the rush hours: WiFi energy management via traffic isolation. International conference on Mobile systems, applications and services, Washington, USA.
  • Omori K., Tanigawa Y., and Tode H., 2015. A study on power saving using RTS/CTS handshake and burst transmission in wireless LAN. Information and Telecommunication Technologies (APSITT), Sri Lanka. Pefkianakis I., Chandrashekar J., and Lundgren H., 2014.
  • User‐Driven Idle Energy Save for 802.11 x Mobile Devices. Mobile Ad Hoc and Sensor Systems, Philadelphia, USA.
  • Qiao D., and Shin K.G., 2005. Smart power‐saving mode for IEEE 802.11 wireless LANs. IEEE Computer and Communications Societies, INFOCOM, Miami, USA. Rozner E., Navda V., Ramjee R., and Rayanchu S., 2010.
  • NAPman: network‐assisted power management for wifi devices. International conference on Mobile systems, applications and services, San Francisco, CA. Stine J.A., and De Veciana G., 2002. Improving energy efficiency of centrally controlled wireless data networks. Wireless Networks 8(6): 681‐700.
  • Sudarshan S., Prasad R., Kumar A., Bhatia R., and Tamma B.R., 2014. Ubersleep: An innovative mechanism to save energy in IEEE 802.11 based WLANs. Electronics, Computing and Communication Technologies (IEEE CONECCT), Bangalore, India.
  • Suh C., Ko Y.B., and Kim J.H., 2005. Enhanced power saving for ieee 802.11 wlan with dynamic slot allocation. Mobile Ad‐hoc and Sensor Networks, Wuhan, China.
  • Swain P., Chakraborty S., Nandi S., and Bhaduri P., 2014. Performance modeling and evaluation of IEEE 802.11 IBSS power save mode. Ad Hoc Networks, 13: 336‐ 350.
  • Tauber M., and Bhatti S.N., 2012. The effect of the 802.11 power save mechanism (PSM) on energy efficiency and performance during system activity. Green Computing and Communications (GreenCom), Besançon, France.
  • Tuysuz M.F., Ucan M., and Ayneli D., 2015. A novel energy‐efficient medium access control over saturated IEEE 802.11 WLANs. Wireless Communications and Mobile Computing Conference (IWCMC), Dubrovnik, Croatia.
  • Tuysuz M.F., 2014. An energy‐efficient QoS‐based network selection scheme over heterogeneous WLAN – 3G networks. Computer Networks, 75(A), 113‐133.
  • Tuysuz M.F., Ucan M., and Ayneli D., 2015. Energy‐ Efficient Medium Access Control over IEEE 802.11 Wireless Heterogeneous Networks. International Conference on Communications in China (ICCC2015), Shenzhen, China.
  • Zhang F., Todd T.D., Zhao D., and Kezys V., 2006. "Power saving access points for IEEE 802‐11 wireless network infrastructure. IEEE Transactions on Mobile Computing, 5(2): 144‐156.
  • Zhu F., and Niu Z., 2008. Priority based power saving mode in WLAN. IEEE GLOBECOM, New Orleans, USA.
  • Zhu Y.H., Luan S., Leung V., and Chi K., 2015. Enhancing timer‐based power management to support delayintolerant uplink traffic in infrastructure IEEE 802.11
  • WLANs. IEEE Transactions on Vehicular Technology, 64(1): 386‐399.
Year 2016, Volume: 16 Issue: 2, 265 - 275, 30.04.2016

Abstract

References

  • https://www.rohde‐schwarz.com/us/solutions/wirelesscommunications/ wlan‐wifi/in‐focus/technology‐intro duction_106713 .html., (17.02.2012) 802.11ac: The Fifth Generation of Wi‐Fi., (01.08 2012) IEEE Std 802.11: Wireless LAN Medium Access Control and Physical Layer Specifications., (01.05.1997)
  • Anastasi, G., Conti M., Gregori E. and Passarella A., 2004. Saving energy in wi‐fi hotspots through 802.11 psm: an analytical model. Workshop on Modeling and Optimization in Mobile, Ad Hoc and Wireless Networks, Cambridge (UK).
  • Balaji B., Tamma B.R., and Manoj B., 2010. A novel power saving strategy for greening IEEE 802.11 based wireless networks. GLOBECOM, Florida, USA.
  • Ding N., Pathak A., Koutsonikolas D., Shepard C., Hu Y.C., and Zhong L., 2012. Realizing the full potential of psm using proxying. INFOCOM, Orlando, FL. He, Y. and Yuan R., 2009. A novel scheduled power saving mechanism for 802.11 wireless LANs. Mobile Computing, IEEE Transactions on 8(10): 1368‐1383.
  • Jang K.Y., Hao S., Sheth A., and Govindan R., 2011. Snooze: energy management in 802.11 n WLANs. Conference on emerging Networking Experiments and Technologies, New York, USA.
  • Jung D., Kim R., and Lim H., 2014. Power‐saving strategy for balancing energy and delay performance in WLANs. Computer Communications 50: 3‐9.
  • Jung E.S., and Vaidya N., 2002. A power saving mac protocol for wireless networks. INFOCOM, NY, USA. Jung E.S., and Vaidya N.H., 2008. Improving IEEE 802.11 power saving mechanism. Wireless Networks 14(3): 375‐391.
  • Kravets R., and Krishnan P., 1998. Power management techniques for mobile communication. ACM/IEEE international conference on Mobile computing and networking, Dallas, Texas.
  • Langendoen K., and Halkes G., 2005. Energy‐efficient medium access control. Embedded systems handbook, 34, 31‐34.
  • Li Y., Zhang X., and Yeung K.L., A novel delayed wakeup scheme for efficient power management in infrastructure‐based IEEE 802.11 WLANs. Wireless Communications and Networking Conference (WCNC), New Orleans, USA.
  • Manweiler J., and Choudhury R.R., 2011. Avoiding the rush hours: WiFi energy management via traffic isolation. International conference on Mobile systems, applications and services, Washington, USA.
  • Omori K., Tanigawa Y., and Tode H., 2015. A study on power saving using RTS/CTS handshake and burst transmission in wireless LAN. Information and Telecommunication Technologies (APSITT), Sri Lanka. Pefkianakis I., Chandrashekar J., and Lundgren H., 2014.
  • User‐Driven Idle Energy Save for 802.11 x Mobile Devices. Mobile Ad Hoc and Sensor Systems, Philadelphia, USA.
  • Qiao D., and Shin K.G., 2005. Smart power‐saving mode for IEEE 802.11 wireless LANs. IEEE Computer and Communications Societies, INFOCOM, Miami, USA. Rozner E., Navda V., Ramjee R., and Rayanchu S., 2010.
  • NAPman: network‐assisted power management for wifi devices. International conference on Mobile systems, applications and services, San Francisco, CA. Stine J.A., and De Veciana G., 2002. Improving energy efficiency of centrally controlled wireless data networks. Wireless Networks 8(6): 681‐700.
  • Sudarshan S., Prasad R., Kumar A., Bhatia R., and Tamma B.R., 2014. Ubersleep: An innovative mechanism to save energy in IEEE 802.11 based WLANs. Electronics, Computing and Communication Technologies (IEEE CONECCT), Bangalore, India.
  • Suh C., Ko Y.B., and Kim J.H., 2005. Enhanced power saving for ieee 802.11 wlan with dynamic slot allocation. Mobile Ad‐hoc and Sensor Networks, Wuhan, China.
  • Swain P., Chakraborty S., Nandi S., and Bhaduri P., 2014. Performance modeling and evaluation of IEEE 802.11 IBSS power save mode. Ad Hoc Networks, 13: 336‐ 350.
  • Tauber M., and Bhatti S.N., 2012. The effect of the 802.11 power save mechanism (PSM) on energy efficiency and performance during system activity. Green Computing and Communications (GreenCom), Besançon, France.
  • Tuysuz M.F., Ucan M., and Ayneli D., 2015. A novel energy‐efficient medium access control over saturated IEEE 802.11 WLANs. Wireless Communications and Mobile Computing Conference (IWCMC), Dubrovnik, Croatia.
  • Tuysuz M.F., 2014. An energy‐efficient QoS‐based network selection scheme over heterogeneous WLAN – 3G networks. Computer Networks, 75(A), 113‐133.
  • Tuysuz M.F., Ucan M., and Ayneli D., 2015. Energy‐ Efficient Medium Access Control over IEEE 802.11 Wireless Heterogeneous Networks. International Conference on Communications in China (ICCC2015), Shenzhen, China.
  • Zhang F., Todd T.D., Zhao D., and Kezys V., 2006. "Power saving access points for IEEE 802‐11 wireless network infrastructure. IEEE Transactions on Mobile Computing, 5(2): 144‐156.
  • Zhu F., and Niu Z., 2008. Priority based power saving mode in WLAN. IEEE GLOBECOM, New Orleans, USA.
  • Zhu Y.H., Luan S., Leung V., and Chi K., 2015. Enhancing timer‐based power management to support delayintolerant uplink traffic in infrastructure IEEE 802.11
  • WLANs. IEEE Transactions on Vehicular Technology, 64(1): 386‐399.
There are 26 citations in total.

Details

Primary Language Turkish
Subjects Engineering
Journal Section Articles
Authors

Mehmet Fatih Tüysüz

Publication Date April 30, 2016
Submission Date April 21, 2016
Published in Issue Year 2016 Volume: 16 Issue: 2

Cite

APA Tüysüz, M. F. (2016). IEEE 802.11 Kablosuz Ağlarda Güç‐Tasarruf‐Modunu Etkin Kullanan Yaklaşımlar ve Benzetim Ortamında Mukayeseleri. Afyon Kocatepe Üniversitesi Fen Ve Mühendislik Bilimleri Dergisi, 16(2), 265-275.
AMA Tüysüz MF. IEEE 802.11 Kablosuz Ağlarda Güç‐Tasarruf‐Modunu Etkin Kullanan Yaklaşımlar ve Benzetim Ortamında Mukayeseleri. Afyon Kocatepe Üniversitesi Fen Ve Mühendislik Bilimleri Dergisi. April 2016;16(2):265-275.
Chicago Tüysüz, Mehmet Fatih. “IEEE 802.11 Kablosuz Ağlarda Güç‐Tasarruf‐Modunu Etkin Kullanan Yaklaşımlar Ve Benzetim Ortamında Mukayeseleri”. Afyon Kocatepe Üniversitesi Fen Ve Mühendislik Bilimleri Dergisi 16, no. 2 (April 2016): 265-75.
EndNote Tüysüz MF (April 1, 2016) IEEE 802.11 Kablosuz Ağlarda Güç‐Tasarruf‐Modunu Etkin Kullanan Yaklaşımlar ve Benzetim Ortamında Mukayeseleri. Afyon Kocatepe Üniversitesi Fen Ve Mühendislik Bilimleri Dergisi 16 2 265–275.
IEEE M. F. Tüysüz, “IEEE 802.11 Kablosuz Ağlarda Güç‐Tasarruf‐Modunu Etkin Kullanan Yaklaşımlar ve Benzetim Ortamında Mukayeseleri”, Afyon Kocatepe Üniversitesi Fen Ve Mühendislik Bilimleri Dergisi, vol. 16, no. 2, pp. 265–275, 2016.
ISNAD Tüysüz, Mehmet Fatih. “IEEE 802.11 Kablosuz Ağlarda Güç‐Tasarruf‐Modunu Etkin Kullanan Yaklaşımlar Ve Benzetim Ortamında Mukayeseleri”. Afyon Kocatepe Üniversitesi Fen Ve Mühendislik Bilimleri Dergisi 16/2 (April 2016), 265-275.
JAMA Tüysüz MF. IEEE 802.11 Kablosuz Ağlarda Güç‐Tasarruf‐Modunu Etkin Kullanan Yaklaşımlar ve Benzetim Ortamında Mukayeseleri. Afyon Kocatepe Üniversitesi Fen Ve Mühendislik Bilimleri Dergisi. 2016;16:265–275.
MLA Tüysüz, Mehmet Fatih. “IEEE 802.11 Kablosuz Ağlarda Güç‐Tasarruf‐Modunu Etkin Kullanan Yaklaşımlar Ve Benzetim Ortamında Mukayeseleri”. Afyon Kocatepe Üniversitesi Fen Ve Mühendislik Bilimleri Dergisi, vol. 16, no. 2, 2016, pp. 265-7.
Vancouver Tüysüz MF. IEEE 802.11 Kablosuz Ağlarda Güç‐Tasarruf‐Modunu Etkin Kullanan Yaklaşımlar ve Benzetim Ortamında Mukayeseleri. Afyon Kocatepe Üniversitesi Fen Ve Mühendislik Bilimleri Dergisi. 2016;16(2):265-7.