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Wireless Networks

Erschienen in:

27.08.2018

A cross layer framework of Radio Resource Allocation for QoS provisioning in multi-channel fading wireless networks

verfasst von: Basabdatta Palit, Suvra Sekhar Das

Erschienen in: Wireless Networks | Ausgabe 1/2020

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Abstract

In this paper, we present an analytical framework for the performance evaluation of Radio Resource Allocation (RRA) in Orthogonal Frequency Division Multiple Access (OFDMA) networks. We focus on Quality of Service (QoS) guaranteed traffic whose capacity, in terms of the number of active user connections, depends on the users’ QoS requirements and channel conditions, and the RRA algorithm. The required QoS is guaranteed by restricting the number of admitted calls, which in turn requires an accurate estimate of the QoS metrics and capacity supported by the RRA when a new call arrives. These estimates for OFDMA networks are variable and usually obtained through time-consuming offline computer simulations. Mathematical frameworks on the other hand yield timely and accurate results. However, earlier known works on analytical modelling of RRA either consider a single channel with random traffic arrivals or multiple channels with full buffer data traffic. In contrast, we develop a queueing theoretic framework considering randomly arriving QoS-guaranteed traffic in a variable-rate multi-channel multi-class OFDMA network. The framework can be used online leading to better dynamic Call Admission Control. We characterize the RRA algorithm using a scheduler control parameter which can regulate the call blocking probability while providing predefined QoS constraints. We model the RRA as a variable service rate, multi-server, multi-class, finite buffer queueing system and verify the derived QoS metrics using extensive Monte-Carlo discrete event simulations.

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Sesia, S., Toufik, I., & Baker, M. (2009). LTE—The UMTS long term evolution: From theory to practice. London: Wiley.CrossRef

Asadi, A., & Mancuso, V. (2013). A survey on opportunistic scheduling in wireless communications. IEEE Communications Surveys and Tutorials, 15(4), 1671–1688. Fourth Quarter.CrossRef

Holma, H., & Toskala, A. (2009). LTE for UMTS-OFDMA and SC-FDMA based radio access. London: Wiley.

3GPP. (2008). Evolved universal terrestrial radio access (E-UTRA); physical layer procedures. TS 36.213.

Palit, B., & Das, S. S. (2015). Performance evaluation of mixed traffic schedulers in OFDMA networks. Wireless Personal Communications, 83(2), 895–924.CrossRef

Ghosh, P., Das, S. S., & Chandhar, P. (2012, May). Estimation of effective radio resource usage for VoIP scheduling in OFDMA cellular networks. In Proceedings of IEEE vehicular technology conference, VTC-Spring (pp. 1–6).

Ahmed, M. H. (2005). Call admission control in wireless networks: A comprehensive survey. IEEE Communications Surveys and Tutorials, 7(1), 49–68. First Quarter.CrossRef

Batabyal, S., & Das, S. S. (2014, May). Analysis of a call admission control algorithm for real-time traffic in OFDMA based cellular networks. In Proceedings of IEEE vehicular technology conference, VTC-Spring (pp. 1–5).

Chung, S. P., & Chen, Y. W. (2012). Performance analysis of call admission control in SFR-based LTE systems. IEEE Communications Letters, 16(7), 1014–1017.CrossRef

10.

Batabyal, S., & Das, S. S. (2013, February). Call admission control for real-time traffic in OFDMA based cellular networks. In Proceedings of national conference on communications, NCC (pp. 1–5).

11.

Le, L. B., Hossain, E., Niyato, D., & Kim, D. I. (2013, June). Mobility-aware admission control with QoS guarantees in OFDMA femtocell networks. In Proceedings of the IEEE international conference on communications, ICC (pp. 2217–2222).

12.

Batabyal, Subhendu, & Das, Suvra Sekhar. (2015). GoS evaluation for OFDMA cellular networks. Wireless Personal Communications, 83(2), 925–957.CrossRef

13.

Karray, M. K. (2010). Analytical evaluation of QoS in the downlink of OFDMA wireless cellular networks serving streaming and elastic traffic. IEEE Transactions on Wireless Communications, 9(5), 1799–1807.MathSciNetCrossRef

14.

Castellanos-Lopez, S. L., Cruz-Perez, F. A., Rivero-Angeles, M. E., & Hernandez-Valdez, G. (2014). Joint connection level and packet level analysis of cognitive radio networks with VoIP traffic. IEEE Journal on Selected Areas in Communications, 32(3), 601–614.CrossRef

15.

Fan, Y., Kuusela, M., Lunden, P., & Valkama, M. (2008, April). Downlink VoIP support for Evolved UTRA. In Proceedings of IEEE wireless communications and networking conference, WCNC (pp. 1933–1938).

16.

Le, L. B., Hossain, E., & Alfa, T. S. (2006). Delay statistics and throughput performance for multi-rate wireless networks under multiuser diversity. IEEE Transactions on Wireless Communications, 5(11), 3234–3243.CrossRef

17.

Omahen, K. J. (1977). Capacity bounds for multiresource queues. Journal of the ACM, 24(4), 646–663.MathSciNetCrossRef

18.

Gross, D., Shortle, J. F., Thompson, J. M., & Harris, C. M. (2008). Fundamentals of queueing theory (4th ed.). New York, NY: Wiley-Interscience.CrossRef

19.

Liu, Q., Zhou, S., & Giannakis, G. B. (2005). Queuing with adaptive modulation and coding over wireless links: Cross-layer analysis and design. IEEE Transactions on Wireless Communications, 4(3), 1142–1153.CrossRef

20.

Wang, H. S., & Moayeri, N. (1995). Finite-state Markov channel-a useful model for radio communication channels. IEEE Transactions on Vehicular Technology, 44(1), 163–171.CrossRef

21.

Liu, Q., Zhou, S., & Giannakis, G. B. (2004). Cross-layer combining of adaptive modulation and coding with truncated ARQ over wireless links. IEEE Transactions on Wireless Communications, 3(5), 1746–1755.CrossRef

22.

Wang, X., Liu, Q., & Giannakis, G. B. (2007). Analyzing and optimizing adaptive modulation coding jointly with ARQ for QoS-guaranteed traffic. IEEE Transactions on Vehicular Technology, 56(2), 710–720.CrossRef

23.

Liu, Q., Zhou, S., & Giannakis, G. B. (2005). Cross-layer scheduling with prescribed QoS guarantees in adaptive wireless networks. IEEE Journal on Selected Areas in Communications, 23(5), 1056–1066.CrossRef

24.

Vo, N. S., Duong, T. Q., Zepernick, H. J., & Fiedler, M. (2015). A cross-layer optimized scheme and its application in mobile multimedia networks with QoS provision. IEEE Systems Journal, 99, 1–14.

25.

Poggioni, P. B. M., & Rugini, L. (2010). QoS analysis of a scheduling policy for heterogeneous users employing AMC jointly with ARQ. IEEE Transactions on Communications, 58(9), 2639–2652.CrossRef

26.

Wang, J., Huang, A., Cai, L., & Wang, W. (2013). On the queue dynamics of multiuser multichannel cognitive radio networks. IEEE Transactions on Vehicular Technology, 62(3), 1314–1328.CrossRef

27.

Rashid, M. M., Hossain, M. J., Hossain, E., & Bhargava, V. K. (2009). Opportunistic spectrum scheduling for multiuser cognitive radio: A queueing analysis. IEEE Transactions on Wireless Communications, 8(10), 5259–5269.CrossRef

28.

Bonald, T., & Proutière, A. (2003). Wireless downlink data channels: User performance and cell dimensioning. In Proceedings of annual international conference on mobile computing and networking, MobiCom (pp. 339–352). New York: ACM. https://doi.org/10.1145/938985.939020.

29.

Boddu, S., Philip, B. V., & Das, S. S. (2016). Analysis of bandwidth requirement of users in flexible reuse cellular networks. IEEE Communications Letters, 20(3), 614–617.CrossRef

30.

ITU-R. (2008). Guidelines for evolution of radio interface technologies for IMT advanced. ITU-R, M 2135.

31.

Tadayon, N., & Aissa, S. (2014). Multi-channel cognitive radio networks: Modeling, analysis and synthesis. IEEE Journal on Selected Areas in Communications, 32(11), 2065–2074.CrossRef

32.

Nogueira, A., Salvador, P., Valadas, R., & Pacheco, A. (2011). Markovian modelling of internet traffic (pp. 98–124). Berlin, Heidelberg: Springer.

33.

Minn, H., Zeng, M., & Bhargava, V. K. (2001). On ARQ scheme with adaptive error control. IEEE Transactions on Vehicular Technology, 50(6), 1426–1436.CrossRef

34.

Wu, J., Mehta, N. B., Molisch, A. F., & Zhang, J. (2011). Unified spectral efficiency analysis of cellular systems with channel-aware schedulers. IEEE Transactions on Communications, 59(12), 3463–3474.CrossRef

35.

Kleinrock, L. (1975). Queueing systems, vol. I: Theory (pp. 103–105). New York: Wiley Interscience.MATH

36.

Zhang, H., Huang, S., Jiang, C., Long, K., Leung, V. C. M., & Poor, H. V. (2017). Energy efficient user association and power allocation in millimeter-wave-based ultra dense networks with energy harvesting base stations. IEEE Journal on Selected Areas in Communications, 35(9), 1936–1947.CrossRef

37.

Zhang, H., Qiu, Y., Long, K., Karagiannidis, G. K., Wang, X., & Nallanathan, A. (2018). Resource allocation in noma-based fog radio access networks. IEEE Wireless Communications, 25(3), 110–115.CrossRef

38.

Zhang, H., Fang, F., Cheng, J., Long, K., Wang, W., & Leung, V. C. M. (2018). Energy-efficient resource allocation in noma heterogeneous networks. IEEE Wireless Communications, 25(2), 48–53.CrossRef

39.

Fang, F., Zhang, H., Cheng, J., & Leung, V. C. M. (2016). Energy-efficient resource allocation for downlink non-orthogonal multiple access network. IEEE Transactions on Communications, 64(9), 3722–3732.CrossRef

40.

Jain, R. K., Chiu, D.-M. W., & Hawe, W. R. (1984). A quantitative measure of fairness and discrimination for resource allocation in shared computer systems. Technical report, Dec.-TR-301, Digital Equipment Corporation. arxiv:9809099

41.

Nain, G., Das, S. S., & Chatterjee, A. (2018). Low complexity user selection with optimal power allocation in downlink noma. IEEE Wireless Communications Letters, 7(2), 158–161.CrossRef

42.

Ding, Z., Lei, X., Karagiannidis, G. K., Schober, R., Yuan, J., & Bhargava, V. K. (2017). A survey on non-orthogonal multiple access for 5g networks: Research challenges and future trends. IEEE Journal on Selected Areas in Communications, 35(10), 2181–2195.CrossRef

43.

Hui, J. Y. (1988). Resource allocation for broadband networks. IEEE Journal on Selected Areas in Communications, 6(9), 1598–1608.CrossRef

Titel: A cross layer framework of Radio Resource Allocation for QoS provisioning in multi-channel fading wireless networks
verfasst von: Basabdatta Palit
Suvra Sekhar Das
Publikationsdatum: 27.08.2018
Verlag: Springer US
Erschienen in: Wireless Networks / Ausgabe 1/2020
Print ISSN: 1022-0038
Elektronische ISSN: 1572-8196
DOI: https://doi.org/10.1007/s11276-018-1821-1

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