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01-05-2016

Joint spectrum load balancing and handoff management in cognitive radio networks: a non-cooperative game approach

Authors: Mina Fahimi, Abdorasoul Ghasemi

Published in: Wireless Networks | Issue 4/2016

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Abstract

We propose a non-cooperative game theory based algorithm for spectrum management problem in cognitive radio networks taking into account the spectrum handoff effects. The objective is to minimize the spectrum access time of Secondary Users (SUs) which are competing for spectrum opportunities in heterogeneous environment. In this paper, the preemptive resume priority (PRP) M/G/1 queuing model is used to characterize the multiple handoff and data delivery time of SUs. Also an explicit solution for channels selection probabilities of each SU is extracted for PRP M/M/1 model specifically. The effect of handoffs is considered as the interrupted packets which return to the SUs’ low priority queue when the high priority Primary User’s packets are arrived to take service. The queuing delay of SUs’ and the effect of these returned packets are considered in order to balance the load of SUs on channels so that the minimum spectrum access time is sensed by each SU. The non-cooperative spectrum load balancing with handoff management game is proposed to find a distributed solution for each SU. It is shown that this game has a unique Nash equilibrium point which can be achieved by SUs as decision makers. At this equilibrium, each SU incurs the minimum delay on all channels while the free spectrum holes of channels are utilized efficiently. Simulation results are provided to evaluate the performance of the proposed scheme in terms of spectrum access delay, fairness, and channels spectrum holes utilization.

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Haykin, S. (2005). Cognitive radio: Brain-empowered wireless communications. IEEE Journal on Selected Areas in Communications, 23(2), 201–220.CrossRef

Mitola, J., et al. (1999). Cognitive radio: Making software radios more personal. IEEE Personal Communications, 6(4), 13–18.CrossRef

Zhao, Q., & Sadler, B. M. (2007). A survey of dynamic spectrum access. IEEE Signal Processing Magazine, 24(3), 79–89.CrossRef

Akyildiz, I. F., Lee, W.-Y., Vuran, M. C., & Mohanty, S. (2006). NeXt generation/dynamic spectrum access/cognitive radio wireless networks: A survey. Computer Networks, 50(13), 2127–2159.CrossRefMATH

Wang, L. C., Wang, C. W., & Adachi, F. (2011). Load balancing spectrum decision for cognitive radio networks. IEEE Journal on Selected Areas in Communications, 29(4), 757–769.CrossRef

Lo, S.-C., & Tseng, C.-W.T. (2007). A novel multi-channel MAC protocol for wireless ad hoc networks. In IEEE Vehicular Technology Conference (VTC 2007), Dublin, Ireland (pp. 46–50).

Kim, T.-S., Lim, H., & Hou, J. C. (2008). Understand and improving the spatial reuse in multihop wireless networks. IEEE Transaction on Mobile Computing, 7(10), 1200–1212.CrossRef

Zhao, Q., Geirhofer, S., Tong, L., & Sadler, B. M. (2008). Opportunistic spectrum access via periodic channel sensing. IEEE Transaction on Signal Processing, 56(2), 785–796.MathSciNetCrossRef

Berlemann, L., Mangold, S., Hiertz, G. R., & Walke, B. (2006). Spectrum load smoothing: Distributed quality-of-service support for cognitive radios in open spectrum. European Transactions on Telecommunications, 17(3), 395–406.CrossRef

10.

Chen, Q., Chen, J., & Tang, L. (2009). Dynamic spectrum load balancing for cognitive radio. In International symposium on computer network and multimedia technology (CNMT 2009). Wuhan, China (pp. 1–4).

11.

Fischer, S., Petrova, M., Mahonen, P., & Vocking, B. (2007). Distributed load balancing algorithm for adaptive channel allocation for cognitive radios. In Proceedings of the 2nd conference cognitive radio oriented wireless networks and communications (CrownCom 2007). Orlando, FL (pp. 508–513).

12.

Fischer, S., Mahonen, P., & Schongens, M. (2008). Load balancing for dynamic spectrum assignment with local information for secondary users. In 3rd IEEE symposium on new Frontiers in dynamic spectrum access networks (DySPAN 2008), Chicago, IL (pp. 1–9).

13.

Shiang, H. P., & van der Schaar, M. (2008). Queuing based dynamic channel selection for heterogeneous multimedia application over cognitive radio networks. IEEE Transaction on Multimedia, 10(5), 896–909.CrossRef

14.

Chronopoulos, A. T., Musku, M. R., Penmatsa, S., & Popescu, D. C. (2008). Spectrum load balancing for medium access in cognitive radio systems. IEEE Communication Letters, 12(5), 353–355.CrossRef

15.

Wang, L.-C., & Wang, C.-W. (2008). Spectrum handoff for cognitive radio networks: Reactive-sensing or proactive-sensing? In IEEE international conferance on performance: Computing and communications, Austin, Texas (pp. 343–348)

16.

Wang, C.-W., & Wang, L.-C. (2010). Modeling and analysis for reactive-decision spectrum handoff in cognitive radio networks. In Global Telecommunications Conference (GLOBECOM 2010), Miami, FL (pp. 1–6).

17.

Baroudi, U., & Alfadhly, A. (2011). Effect of mobility and primary appearance probability on spectrum handoff. In IEEE 73rd Vehicular Technology Conference (VTC 2011), Yokohama, Japan (pp. 1–6).

18.

Wang, C.-W., & Wang, L.-C. (2009). Modeling and analysis for proactive-decision pectrum handoff in cognitive radio networks. In IEEE international conference on communications, (ICC 2009) (pp. 1–6).

19.

Song, Y., & Xie, J. (2010) Common hopping based proactive spectrum handoff in cognitive radio ad hoc networks. In IEEE Global Telecommunications Conference (GLOBECOM 2010), Miami, FL (pp. 1–5).

20.

Yang, L., Cao, L., & Zheng, H. (2008). Proactive channel access in dynamic spectrum networks. Physical Communication, 1(2), 103–111.CrossRef

21.

Liu, H.-J., Wang, Z.-X., Li, S.-F., & Yi, M. (2008). Study on the performance of spectrum mobility in cognitive wireless network. In IEEE Singapore international conference on communication systems (ICCS 2008), Guangzhou, China (pp. 1010–1014).

22.

Wang, L.-C., Wang, C.-W., & Feng, K.-T. (2011). A queueing-theoretical framework for QoS-enhanced spectrum management in cognitive radio networks. IEEE Wireless Communications, 18(6), 18–26.CrossRef

23.

Wang, L. C., Wang, C. W., & Chang, C. J. (2012). Modeling and analysis for spectrum handoffs in cognitive radio networks. IEEE Transactions on Mobile Computing, 11(9), 1499–1513.CrossRef

24.

Fahimi, M., & Ghasemi, A. (2014). Modeling and analysis the PRP M/G/1 queuing system for cognitive radio networks with handoff effects and stability conditions. In Proceedings of the Iranian Conference on Electrical Engineering (ICEE 2014), Iran, Tehran.

25.

Kleinrock, L. (1975). Queuing systems (1st ed.). New York: Wiley-Interscience.MATH

26.

Bertsekas, D., & Gallager, R. (1987). Data networks (1st ed.). Upper Saddle River, NJ: Prentice Hall Inc.MATH

27.

Kim, C., & Kameda, H. (1992). An algorithm for optimal static load balancing in distributed computer systems. IEEE Transactions on Computers, 41(3), 381–384.CrossRef

28.

Osborn, M. J., & Rubinstein, A. (1998). A course in game theory (1st ed.). Cambridge, MA: MIT Press.

29.

Fudenberg, D., & Levine, D. K. (1998). Game theory (1st ed.). Cambridge, MA: MIT Press.MATH

30.

Scutari, G., Palomar, D. P., Facchinei, F., & Pang, J.-S. (2010). Convex optimization, game theory and variational inequality theory. IEEE Signal Processing Magazine, 27(3), 35–49.CrossRef

31.

Boyd, S., & Vandenberghe, L. (2004). Convex optimization. Cambridge, MA: Cambridge University Press.CrossRefMATH

32.

Grosu, D., & Chronopoulos, A. (2005). Noncooperative load balancing in distributed systems. Journal of Parallel and Distributed Computing, 65(9), 1022–1034.CrossRefMATH

33.

Ross, S. M. (1996). Stochastic processes (2nd ed.). New York: Wiley.MATH

34.

Jain, R. (1991). The art of computer systems performance analysis: Techniques for experimental design, measurement, simulation, and modeling. New York: Wiley.MATH

Title: Joint spectrum load balancing and handoff management in cognitive radio networks: a non-cooperative game approach
Authors: Mina Fahimi
Abdorasoul Ghasemi
Publication date: 01-05-2016
Publisher: Springer US
Published in: Wireless Networks / Issue 4/2016
Print ISSN: 1022-0038
Electronic ISSN: 1572-8196
DOI: https://doi.org/10.1007/s11276-015-1023-z

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