Abstract
In this paper, we present a deterministic resource allocation model for a hybrid uplink wireless orthogonal frequency and time division multiple access network. Since the input data of the model may be affected by uncertainty, we further consider a stochastic formulation of the problem which we transform into an equivalent deterministic binary second-order conic program (SOCP). Subsequently, we use this binary SOCP to derive an equivalent integer linear programming formulation. The proposed models are aimed at maximizing the total bandwidth channel capacity subject to user power and sub-carrier assignment constraints while simultaneously scheduling users in time. As such, the models are best suited for non-real-time applications where sub-channel multiuser diversity can be further exploited simultaneously in frequency and time domains. Finally, in view of the large execution times required by CPLEX to solve the proposed models, we propose a variable neighborhood search metaheuristic procedure. Our numerical results show tight bounds and near optimal solutions for most of the instances when compared to the optimal solution of the problem. Moreover, we obtain better feasible solutions than CPLEX in the stochastic case. Finally, these bounds are obtained at a very low computational cost.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Notes
A frame is a packet which transmits the data. Each frame is composed of T slots and N sub-carriers.
References
Adasme, P., & Lisser, A. (2014). Stochastic and semidefinite optimization for scheduling in orthogonal frequency division multiple access networks. Journal of Scheduling, 17, 445–469.
Adasme, P., Lisser, A., & Soto, I. (2011). Robust semidefinite relaxations for a quadratic OFDMA resource allocation scheme. Computers and Operations Research, 38, 1377–1399.
Adasme, P., Lisser, A., & Wang, C. (2013). A distributionally robust formulation for stochastic quadratic Bi-level programming. In Proceedings of the 2nd international conference on operations research and enterprise systems (ICORES 2013), Barcelona, Spain (pp. 24–31).
Air Interface for Fixed Broadband Wireless Access Systems, MAC and Additional PHY Specifications for 2-11 GHz, IEEE Std. 802.16a (2003).
Amzallag, D., Armarnik, T., Livschitz, M., & Raz, D. (2007). Multi-cell slots allocation in OFDMA systems. In 16th IST mobile and wireless communications summit.
Birge, J., & Louveaux, F. (1997). Introduction to stochastic programming (Vol. 421). Springer Series in Operations Research. New York: Springer.
Cao, Z., Tureli, U., & Liu, P. (2003). Optimum subcarrier assignment for OFDMA uplink. In IEEE conference record of the thirty-seventh Asilomar (Vol. 1, pp. 708–712).
Chang, Y., Chien, F., & Kuo, C. (2007). Cross-layer QoS analysis of opportunistic OFDM-TDMA and OFDMA networks. IEEE Journal on Selected Areas in Communications, 25, 657–666.
Cheng, J., Delage, E., & Lisser, A. (2014). Distributionally robust stochastic knapsack problem. SIAM Journal on Optimization, 24, 1485–1506.
Cheng, J., & Lisser, A. (2012). A second-order cone programming approach for linear programs with joint probabilistic constraints. Operations Research Letters, 40, 325–328.
Delage, E., & Ye, Y. (2010). Distributionally robust optimization under moment uncertainty with application to data-driven problems. Operations Research, 58, 596–612.
Fortet, R. (1960). Applications de lálgebre de boole en recherche operationelle. Revue Francaise de Recherche Operationelle, 4, 17–26.
Gaivoronski, A., Lisser, A., Lopez, R., & Hu, X. (2011). Knapsack problem with probability constraints. Journal of Global Optimization, 49, 397–413.
Hansen, P., & Mladenovic, N. (2001). Variable neighborhood search: Principles and applications. European Journal of Operational Research, 130, 449–467.
Hansen, P., Mladenovic, N., & Perez, B. (2001). Variable neighborhood decomposition search. Journal of Heuristics, 7, 335–350.
Katoozian, M., Navaie, K., & Yanikomeroglu, H. (2008). Optimal utility-based resource allocation for OFDM networks with multiple types of traffic. In IEEE vehicular technology conference (pp. 2223–2227).
Keller, T., & Hanzo, L. (2000). Adaptive multicarrier modulation: A convenient framework for time frequency processing in wireless communications. Proccedings of the IEEE, 88, 611–640.
Kim, I., Lee, H. L., Kim, B., & Lee, Y. H. (2001). On the use of linear programming for dynamic subchannel and bit allocation in multiuser OFDM. IEEE GLOBECOM, 01(6), 3648–3652.
Lobo, M., Vandenberghe, L., Boyd, S., & Lebret, H. (1998). Applications of second-order cone programming. Linear Algebra and Its Applications, 284, 193–228.
Mladenovic, N., & Hansen, P. (1997). Variable neighborhood search. Computers & OR, 24, 1097–1100.
MOSEK. (2011). MOSEK is an optimization software designed to solve large-scale mathematical optimization problems. http://www.mosek.com/.
Navaie, K., & Yanikomeroglu, H. (2006). Optimal downlink resource allocation for non-realtime traffic in cellular CDMA/TDMA networks. IEEE Communications Letters, 10, 278–280.
Prékopa, A. (1995). Stochastic programming, 600. Dordrecht: Kluwer.
Shen, Z., Andrews, J., & Evans, B. (2003). Short range wireless channel prediction using local information. IEEE Conference Record of the Thirty-Seventh Asilomar, 1, 1147–1151.
Stankovic, J. (2008). When sensor and actuator networks cover the world. ETRI Journal, 30, 627–633.
Sternad, M., & Aronsson, D. (2005). Channel estimation and prediction for adaptive OFDMA/TDMA uplinks based on overlapping pilots. In Proceedings of IEEE international conference on acoustics, speech, and signal processing (ICASSP 2005) (Vol. 3, pp. 861–864).
Sternad, M., Svensson, T., Ottosson, T., Ahlen, A., Svensson, A., & Brunstrom, A. (2007). Towards systems beyond 3G based on adaptive OFDMA transmission. Proceedings of the IEEE, 95, 2432–2455.
Varghese, G., & Zheng, F. (2010). A new study on the power distribution of OFDMA, SC-FDMA and CP-CDMA signals. In Proceedings of the 71st IEEE vehicular technology conference (VTC 2010-Spring) (pp. 1–6).
Wong, I., Zukang, S., Evans, B., & Andrews, J. (2004). A low complexity algorithm for proportional resource allocation in OFDMA systems. In IEEE workshop on signal processing systems (Vol. 16).
Acknowledgments
We are grateful to the referees for their valuable comments to improve this paper.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Adasme, P., Lisser, A. Uplink scheduling for joint wireless orthogonal frequency and time division multiple access networks. J Sched 19, 349–366 (2016). https://doi.org/10.1007/s10951-015-0442-0
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10951-015-0442-0