Sum-rate maximization and energy-cost minimization for renewable energy empowered base-stations using zero-forcing beamforming

Zero-forcing (ZF) beamforming is a practical linear transmission scheme that eliminates inter-user interference in the downlink of a multiuser multiple-input single-output (MISO) wireless system. By considering base-stations (BSs) that are supported by renewable energy, this work examines offline and online ZF beamforming designs based on two different objectives, namely, sum-rate maximization and energy-cost minimization. For offline policies, the channel states and the energy arrivals are assumed to be known a priori for all time instants whereas, in the online policies, only causal information is available. The designs are subject to energy causality and energy storage constraints, i.e., the constraint that energy cannot be used before it arrives and the constraint that the stored energy cannot exceed the maximum battery storage capacity. In the sum-rate maximization problem, the base-station is assumed to be supported only by renewable energy and the goal is to maximize the sum rate over all users by a predetermined deadline. The optimization of the ZF beamforming direction and power allocation can be decoupled, and the solutions can be found exactly. In the energy-cost minimization problem, the base-station is assumed to be supported by both renewable and power-grid energy, and the goal is to minimize the cost of purchasing grid energy subject to quality-of-service constraints at the users. The problem can be formulated as a convex optimization problem and can be solved efficiently using off-the-shelf solvers. Offline solutions are first obtained and the intuitions gained from their results are used to derive effective online policies. The effectiveness of the proposed policies are demonstrated through computer simulations.

[1]  Ross D. Murch,et al.  Transmit-preprocessing techniques with simplified receivers for the downlink of MISO TDD-CDMA systems , 2004, IEEE Transactions on Vehicular Technology.

[2]  Giuseppe Caire,et al.  Joint Beamforming and Scheduling for a Multi-Antenna Downlink with Imperfect Transmitter Channel Knowledge , 2007, IEEE Journal on Selected Areas in Communications.

[3]  Jinho Choi,et al.  MMSE multiuser downlink multiple antenna transmission for CDMA systems , 2004, IEEE Transactions on Signal Processing.

[4]  Andrea J. Goldsmith,et al.  On the optimality of multiantenna broadcast scheduling using zero-forcing beamforming , 2006, IEEE Journal on Selected Areas in Communications.

[5]  Rui Zhang,et al.  Optimal Save-Then-Transmit Protocol for Energy Harvesting Wireless Transmitters , 2012, IEEE Transactions on Wireless Communications.

[6]  Shlomo Shamai,et al.  On the achievable throughput of a multiantenna Gaussian broadcast channel , 2003, IEEE Transactions on Information Theory.

[7]  Erik G. Larsson,et al.  Complete Characterization of the Pareto Boundary for the MISO Interference Channel , 2008, IEEE Transactions on Signal Processing.

[8]  Jing Yang,et al.  Optimal Broadcast Scheduling for an Energy Harvesting Rechargeable Transmitter with a Finite Capacity Battery , 2012, IEEE Transactions on Wireless Communications.

[9]  Jeffrey G. Andrews,et al.  Femtocell networks: a survey , 2008, IEEE Communications Magazine.

[10]  Martin Haardt,et al.  Zero-forcing methods for downlink spatial multiplexing in multiuser MIMO channels , 2004, IEEE Transactions on Signal Processing.

[11]  Yao-Win Peter Hong,et al.  Downlink multiuser beamforming and power control for base stations empowered by renewable energy , 2013, 2013 IEEE 24th Annual International Symposium on Personal, Indoor, and Mobile Radio Communications (PIMRC).

[12]  Erik G. Larsson,et al.  The MISO interference channel from a game-theoretic perspective: A combination of selfishness and altruism achieves pareto optimality , 2008, 2008 IEEE International Conference on Acoustics, Speech and Signal Processing.

[13]  Aylin Yener,et al.  Transceiver optimization for multiuser MIMO systems , 2004, IEEE Transactions on Signal Processing.

[14]  Dario Rossi,et al.  A Survey of Green Networking Research , 2010, IEEE Communications Surveys & Tutorials.

[15]  Martina Cardone,et al.  SINR balancing and beamforming for the MISO interference channel , 2011, 2011 IEEE 22nd International Symposium on Personal, Indoor and Mobile Radio Communications.

[16]  A. Lee Swindlehurst,et al.  A vector-perturbation technique for near-capacity multiantenna multiuser communication-part I: channel inversion and regularization , 2005, IEEE Transactions on Communications.

[17]  Aylin Yener,et al.  Optimum Transmission Policies for Battery Limited Energy Harvesting Nodes , 2010, IEEE Transactions on Wireless Communications.

[18]  L. C. Godara,et al.  Handbook of Antennas in Wireless Communications , 2001 .

[19]  Rui Zhang,et al.  Cooperative Multi-Cell Block Diagonalization with Per-Base-Station Power Constraints , 2009, IEEE Journal on Selected Areas in Communications.

[20]  Ami Wiesel,et al.  Linear precoding via conic optimization for fixed MIMO receivers , 2006, IEEE Transactions on Signal Processing.

[21]  Weidong Yang,et al.  Optimal downlink power assignment for smart antenna systems , 1998, Proceedings of the 1998 IEEE International Conference on Acoustics, Speech and Signal Processing, ICASSP '98 (Cat. No.98CH36181).

[22]  Jing Yang,et al.  Transmission with Energy Harvesting Nodes in Fading Wireless Channels: Optimal Policies , 2011, IEEE Journal on Selected Areas in Communications.

[23]  Stephen P. Boyd,et al.  Convex Optimization , 2004, Algorithms and Theory of Computation Handbook.

[24]  Holger Boche,et al.  Solution of the multiuser downlink beamforming problem with individual SINR constraints , 2004, IEEE Transactions on Vehicular Technology.

[25]  Zhisheng Niu,et al.  Optimal Power Allocation for Energy Harvesting and Power Grid Coexisting Wireless Communication Systems , 2013, IEEE Transactions on Communications.