Sum throughput maximization in a slotted Aloha network with energy harvesting nodes

In this paper, we propose distributed static and dynamic optimal policies in a random access environment, comprised of energy harvesting (EH) nodes, in order to maximize the sum throughput. In static approach, each EH node exploits an optimal constant power to transmit its packets. However in dynamic one, the EH nodes adjust their transmission powers based on their network information, leading to exploit variable transmission powers. In static algorithm, the maximization is done through modeling energy buffer of EH nodes by a two-dimensional discrete time Markov chain which includes the effect of on-line charging and limited energy buffer. However, in dynamic approach, the variable power is allotted to EH nodes through modeling the problem as a Markov decision process. We observe that dynamic approach outperforms the static one by suitable management of collisions and available energy. Simulation results confirm our analytical approach.

[1]  Dinesh Rajan,et al.  Delay bounded rate and power control in energy harvesting wireless networks , 2011, 2011 IEEE Wireless Communications and Networking Conference.

[2]  Qing Bai,et al.  Throughput maximization for energy harvesting nodes transmitting over time-varying channels , 2013, 2013 IEEE International Conference on Communications (ICC).

[3]  Hung-Yu Wei,et al.  Markov chain performance model for IEEE 802.11 devices with energy harvesting source , 2012, 2012 IEEE Global Communications Conference (GLOBECOM).

[4]  Farid Ashtiani,et al.  Throughput analysis of a slotted Aloha-based network with energy harvesting nodes , 2012, 2012 IEEE 23rd International Symposium on Personal, Indoor and Mobile Radio Communications - (PIMRC).

[5]  V. Shenoy,et al.  Throughput Maximization of Delay-Constrained Traffic in Wireless Energy Harvesting Sensors , 2010, 2010 IEEE International Conference on Communications.

[6]  Gerhard Fettweis,et al.  The global footprint of mobile communications: The ecological and economic perspective , 2011, IEEE Communications Magazine.

[7]  S. Wittevrongel,et al.  Queueing Systems , 2019, Introduction to Stochastic Processes and Simulation.

[8]  Umberto Spagnolini,et al.  Dynamic Framed-ALOHA for Energy-Constrained Wireless Sensor Networks with Energy Harvesting , 2010, 2010 IEEE Global Telecommunications Conference GLOBECOM 2010.

[9]  Simonetta Balsamo,et al.  Queueing Networks , 2007, SFM.

[10]  Andrea Fumagalli,et al.  Cooperative and Reliable ARQ Protocols for Energy Harvesting Wireless Sensor Nodes , 2007, IEEE Transactions on Wireless Communications.

[11]  Martin L. Puterman,et al.  Markov Decision Processes: Discrete Stochastic Dynamic Programming , 1994 .

[12]  Jing Yang,et al.  Resource management for fading wireless channels with energy harvesting nodes , 2011, 2011 Proceedings IEEE INFOCOM.

[13]  Alireza Seyedi,et al.  Analysis and Design of Energy Harvesting Wireless Sensor Networks with Linear Topology , 2011, 2011 IEEE International Conference on Communications (ICC).

[14]  Vinod Sharma,et al.  Optimal energy management policies for energy harvesting sensor nodes , 2008, IEEE Transactions on Wireless Communications.

[15]  Joseph A. Paradiso,et al.  Energy scavenging for mobile and wireless electronics , 2005, IEEE Pervasive Computing.

[16]  Anthony Ephremides,et al.  The stability region of random multiple access under stochastic energy harvesting , 2011, 2011 IEEE International Symposium on Information Theory Proceedings.

[17]  Michael L. Honig,et al.  Resource allocation for multiple classes of DS-CDMA traffic , 2000, IEEE Trans. Veh. Technol..

[18]  Leandros Tassiulas,et al.  Control of wireless networks with rechargeable batteries [transactions papers] , 2010, IEEE Transactions on Wireless Communications.

[19]  Chandra R. Murthy,et al.  Duty cycling and power management with a network of energy harvesting sensors , 2011, 2011 4th IEEE International Workshop on Computational Advances in Multi-Sensor Adaptive Processing (CAMSAP).