A p-norm Flow Optimization Problem in Dense Wireless Sensor Networks

In a network with a high density of wireless nodes, we model flow of information by a continuous vector field known as the information flow vector field. We use a mathematical model that translates a communication network composed of a large but finite number of sensors into a continuum of nodes on which information flow is formulated by a vector field. The magnitude of this vector field is the intensity of the communication activity, and its orientation is the direction in which the traffic is forwarded. The information flow vector field satisfies a set of Neumann boundary conditions and a partial differential equation (PDE) involving the divergence of information, but the divergence constraint and Neumann boundary conditions do not specify the information flow vector field uniquely, and leave us freedom to optimize certain measures within their feasible set. Therefore, we introduce a p-norm flow optimization problem in which we minimize the p-norm of information flow vector field over the area of the network. This problem is a convex optimization problem, and we use sequential quadratic programming (SQP) to solve it. SQP is known for numerical stability and fast convergence to the optimal solution in convex optimization problems. By using standard SQP on p-norm flow optimization, we prove that the solution of each iteration of SQP is uniquely specified by an elliptic PDE with generalized Neumann boundary conditions. The p-norm flow optimization shows interesting properties for different values of p. For example, if p is close to one, the information routes resemble the geometric shortest paths of the sources and sinks, and for p = 2, the information flow shows an analogy to electrostatics. For infinitely large values of p, the problem minimizes the maximum magnitude of the information vector field over the network, and hence it achieves maximum load balancing.

[1]  Mark A. Shayman,et al.  Energy Efficient Routing in Wireless Sensor Networks , 2003 .

[2]  D K Smith,et al.  Numerical Optimization , 2001, J. Oper. Res. Soc..

[3]  Philippe Jacquet,et al.  Geometry of information propagation in massively dense ad hoc networks , 2004, MobiHoc '04.

[4]  Abtin Keshavarzian,et al.  Load balancing in ad hoc networks: single-path routing vs. multi-path routing , 2004, IEEE INFOCOM 2004.

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

[6]  Craig C. Douglas,et al.  A Tutorial on Elliptic Pde Solvers and Their Parallelization , 2003 .

[7]  Mark A. Shayman,et al.  Routing in wireless ad hoc networks by analogy to electrostatic theory , 2004, 2004 IEEE International Conference on Communications (IEEE Cat. No.04CH37577).

[8]  Stavros Toumpis,et al.  Opti{c,m}al: Optical/Optimal Routing in Massively Dense Wireless Networks , 2006, IEEE INFOCOM 2007 - 26th IEEE International Conference on Computer Communications.

[9]  Panganamala Ramana Kumar,et al.  RHEINISCH-WESTFÄLISCHE TECHNISCHE HOCHSCHULE AACHEN , 2001 .

[10]  M. Shayman,et al.  Routing in Multi-Commodity Sensor Networks Based on Partial Differential Equations , 2006, 2006 40th Annual Conference on Information Sciences and Systems.

[11]  Mark A. Shayman,et al.  Design optimization of multi-sink sensor networks by analogy to electrostatic theory , 2006, IEEE Wireless Communications and Networking Conference, 2006. WCNC 2006..

[12]  G. M.,et al.  Partial Differential Equations I , 2023, Applied Mathematical Sciences.

[13]  Jorma T. Virtamo,et al.  On Traffic Load Distribution and Load Balancing in Dense Wireless Multihop Networks , 2007, EURASIP J. Wirel. Commun. Netw..

[14]  Leandros Tassiulas,et al.  Optimal deployment of large wireless sensor networks , 2006, IEEE Transactions on Information Theory.