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Wireless Networks

Erschienen in:

16.06.2020

QoS provisioning in energy-efficient cooperative networks with power assignment and relay deployment planning

verfasst von: Jane-Hwa Huang, Sz-Yan Hsu

Erschienen in: Wireless Networks | Ausgabe 7/2020

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Abstract

The cooperative network is an energy-efficient technology to provide ubiquitous broadband access and quality-of-service (QoS). This paper investigates the tradeoffs among QoS, capacity, and power consumption in the cooperative networks. By adaptively selecting among the direct, relay, and cooperative transmission (TX) modes for users, we can enhance the capacity with lower transmission power. Furthermore, we determine the proper relay location and transmission powers of base station (BS) and relay station, so that more users can exploit the low-power two-hop TX modes to enhance the capacity and reduce the delay. In the real networks, if the packet queue is empty, the BS can be idle without sending (to save energy). Hence, we also properly increase the link capacity and idle probability to further reduce power consumption. We develop an analytical model to evaluate the delay, variance, capacity, idle probability, and actual power consumption in unsaturated traffic conditions. Then, we apply an optimization approach to analytically determine the optimal relay location and transmission powers, aiming to maximize the overall energy efficiency (EE) subject to the delay requirements. Numerical results show that the adaptive TX-mode selection scheme along with the joint power assignment and relay deployment planning can significantly enhance the capacity and reduce the power consumption. Then, the goal of QoS support can be achieved with higher EE.

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Zhang, R., Qi, C., Li, Y., Ruan, Y., Wang, C.-X., & Zhang, H. (2019). Towards energy-efficient underlaid device-to-device communications: A joint resource management approach. IEEE Access, 7, 31385–31396.CrossRef

Ahmed, E., & Gharavi, H. (2018). Cooperative vehicular networking: A survey. IEEE Transactions on Intelligent Transportation Systems, 96, 996–1014.CrossRef

Huang, J., Gharavi, H., Yan, H., & Xing, C.-C. (2017). Network coding in relay-based device-to-device communications. IEEE Network, 31, 102–107.CrossRef

Vannithamby, R., & Talwar, S. (Eds.). (2017). Towards 5G: Applications, requirements and candidate technologies. New York: Wiley.

Feng, D., Jiang, C., Lim, G., Jr Cimini, L. J., Feng, G., & Li, G. Y. (2013). A survey of energy-efficient wireless communications. IEEE Communications Surveys and Tutorials, 15(1), 167–178. First Quarter.CrossRef

Li, L., Dong, C., Wang, L., & Hanzo, L. (2016). Spectral-efficient bidirectional decode-and-forward relaying for full-duplex communication. IEEE Transactions on Vehicular Technology, 65(9), 7010–7020.CrossRef

Ding, Z., Xing, S., Yan, F., & Shen, L. (2019). Impact of optimal hop distance on the network lifetime for wireless sensor networks with QoS requirements. IEEE Communications Letters, 23(3), 534–537.CrossRef

Huang, J.-H., Wang, L.-C., Chang, C.-J., & Wen-Shan, S. (2010). Design of optimal relay locations in two-hop cellular systems. ACM/Springer Wireless Networks, 16(8), 2179–2189.CrossRef

Chang, C.-Y., Chang, C.-T., Wang, T.-C., & Li, M.-H. (2015). Throughput-enhanced relay placement mechanism in WiMAX 802.16j multihop relay networks. IEEE Systems Journal, 9(3), 728–742.CrossRef

10.

Zhao, N., Yu, F. R., Sun, H., & Li, M. (2016). Adaptive power allocation schemes for spectrum sharing in interference-alignment-based cognitive radio networks. IEEE Transactions on Vehicular Technology, 65(5), 3700–3714.CrossRef

11.

Zhao, N., Cao, Y., Yu, F. R., Chen, Y., Jin, M., & Leung, V. C. M. (2018). Artificial noise assisted secure interference networks with wireless power transfer. IEEE Transactions on Vehicular Technology, 67(2), 1087–1098.CrossRef

12.

Chu, M., He, B., Liao, X., Gao, Z., & Leung, V. C. M. (2018). On the design of power splitting relays with interference alignment. IEEE Transactions on Communications, 66(4), 1411–1424.CrossRef

13.

Ng, D. W. K., & Schober, R. (2010). Cross-layer scheduling for OFDMA amplify-and-forward relay networks. IEEE Transactions on Vehicular Technology, 59(3), 1443–1458.CrossRef

14.

Zappone, A., Atapattu, S., Renzo, M. D., Evans, J. S., & Debbah, M. (2018). Energy-efficient relay assignment and power control in multi-user and multi-relay networks. IEEE Wireless Communications Letters, 7(6), 1070–1073.CrossRef

15.

Atapattu, S., Dharmawansa, P., Di Renzo, M., Tellambura, C., & Evans, J. S. (2019). Multi-user relay selection for full-duplex radio. IEEE Transactions on Communications, 67(2), 955–972.CrossRef

16.

Naeem, M., Khwaja, A. S., Anpalagan, A., & Jaseemuddin, M. (2016). Green cooperative cognitive radio: A multiobjective optimization paradigm. IEEE Systems Journal, 10(1), 240–250.CrossRef

17.

Vardhe, K., Reynolds, D., & Woerner, B. D. (2010). Joint power allocation and relay selection for multiuser cooperative communication. IEEE Transactions on Wireless Communications, 9(4), 1255–1260.CrossRef

18.

Loodaricheh, R. A., Mallick, S., & Bhargava, V. K. (2014). Energy-efficient resource allocation for OFDMA cellular networks with user cooperation and QoS provisioning. IEEE Transactions on Wireless Communications, 13(11), 6132–6146.CrossRef

19.

Zhou, Z., Xiong, F., Chen, X., He, Y., & Mumtaz, S. (2018). Energy-efficient vehicular heterogeneous networks for green cities. IEEE Transactions on Industrial Informatics, 14(4), 1522–1531.CrossRef

20.

Huang, J.-H., & Hsu, S.-Y. (2015). Joint power assignment and relay location design for cooperative power-efficient networks with adaptive transmission mode selection. In IEEE WCNC.

21.

Gao, H., Zhang, S., Su, Y., & Diao, M. (2019). Joint resource allocation and power control algorithm for cooperative D2D heterogeneous networks. IEEE Access, 7, 20632–20643.CrossRef

22.

Sun, J., Zhang, Z., Xing, C., & Xiao, H. (2018). Uplink resource allocation for relay-aided device-to-device communication. IEEE Transactions on Intelligent Transportation Systems, 19(12), 3883–3892.CrossRef

23.

Xiao, H., Zhang, Z., & Chronopoulos, A. T. (2018). Performance analysis of multi-source multi-destination cooperative vehicular networks with the hybrid decode-amplify-forward cooperative relaying protocol. IEEE Transactions on Intelligent Transportation Systems, 19(9), 3081–3086.CrossRef

24.

Bedeer, E., et al. (2015). Fairness-aware energy-efficient resource allocation for AF Co-Operative OFDMA networks. IEEE Journal on Selected Areas in Communications, 33(12), 2478–2493.CrossRef

25.

Alahmadi, A., Liang, Y., Tian, R., Ren, J., & Li, T. (2019). Blocking probability analysis for relay-assisted OFDMA networks using stochastic geometry. In International conference on computing, networking and communications (ICNC).

26.

Efazati, S., Ghalamkari, B., Azmi, P., & Jorswieck, E. A. (2019). Quality of service performance analysis of relaying networks with multiple buffer-aided relays. IEEE Transactions on Vehicular Technology, 68(4), 4016–4026.CrossRef

27.

Karatza, G. P., Peppas, K. P., & Sagias, N. C. (2018). Effective capacity of multisource multidestination cooperative systems under cochannel interference. IEEE Transactions on Vehicular Technology, 67(9), 8411–8421.CrossRef

28.

Qiao, D. (2019). Outage effective capacity of buffer-aided diamond relay systems using HARQ-IR. IEEE Transactions on Vehicular Technology, 68(1), 540–553.CrossRef

29.

Qiao, D., & Gursoy, M. C. (2016). Statistical delay tradeoffs in buffer-aided two-hop wireless communication systems. IEEE Transactions on Communications, 64(11), 4563–4577.CrossRef

30.

Yulin, H., Gross, J., & Schmeink, A. (2016). QoS-constrained energy efficiency of cooperative ARQ in multiple DF relay systems. IEEE Transactions on Vehicular Technology, 65(2), 848–859.CrossRef

31.

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

32.

Dapeng, W., & Negi, R. (2003). Effective capacity: A wireless link model for support of quality of service. IEEE Transactions on Wireless Communications, 2(4), 630–643.CrossRef

33.

Liu, K. J. R., Sadek, A. K., Su, W., & Kwasinski, A. (2009). Cooperative communications and networking. Cambridge: Cambridge University Press.MATH

34.

IEEE 802.16 Broadband Wireless Access Working Group. (2007). Multi-hop relay system evaluation methodology (channel model and performance metric). IEEE 802.16j-06/013r3.

35.

IEEE 802.16 Broadband Wireless Access Working Group. (2005). CINR measurements using the EESM method. IEEE C802.16e-05/141r3.

36.

Andrews, J. G., Ghosh, A., & Muhamed, R. (2007). Fundamentals of WiMAX: Understanding broadband wireless networking. Upper Saddle River: Prentice Hall.

37.

Holland, J. H. (1975). Adoption in natural and artificial system. Ann Arbor, MI: The University of Michigan Press.

38.

Stuber, G. L. (2012). Principles of mobile communication (3rd ed.). Berlin: Springer.CrossRef

39.

Abramowitz, M., & Stegun, I. A. (1965). Handbook of mathematical functions: with formulas, graphs, and mathematical tables. New York: Dover Publications.MATH

Titel: QoS provisioning in energy-efficient cooperative networks with power assignment and relay deployment planning
verfasst von: Jane-Hwa Huang
Sz-Yan Hsu
Publikationsdatum: 16.06.2020
Verlag: Springer US
Erschienen in: Wireless Networks / Ausgabe 7/2020
Print ISSN: 1022-0038
Elektronische ISSN: 1572-8196
DOI: https://doi.org/10.1007/s11276-020-02375-3

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