On the optimality of field-line routing in massively dense wireless multi-hop networks

Hyytiä, Esa; Virtamo, Jorma

doi:10.1016/j.peva.2008.10.003

Cited by 7 publications

(7 citation statements)

References 21 publications

(70 reference statements)

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“…The forwarding load appears to correspond to the scalar sum of traffic flows of different classes. This means that the optimal solution (with respect to this objective) can be achieved by single path routes, a result obtained also in [15]. Similar problems have been also studied in [8], as well as in works doing load balancing by analogies to Electrostatics (see e.g.…”

Section: Introductionmentioning

confidence: 79%

Continuum equilibria and global optimization for routing in dense static ad hoc networks

Silva¹,

Altman²,

Bernhard³

et al. 2010

Computer Networks

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We consider massively dense ad hoc networks and study their continuum limits as the node density increases and as the graph providing the available routes becomes a continuous area with location and congestion dependent costs. We study both the global optimal solution as well as the non-cooperative routing problem among a large population of users where each user seeks a path from its origin to its destination so as to minimize its individual cost. Finally, we seek for a (continuum version of the) Wardrop equilibrium. We first show how to derive meaningful cost models as a function of the scaling properties of the capacity of the network and of the density of nodes. We present various solution methodologies for the problem: (1) the viscosity solution of the Hamilton-Jacobi-Bellman equation, for the global optimization problem, (2) a method based on Green's Theorem for the least cost problem of an individual, and (3) a solution of the Wardrop equilibrium problem using a transformation into an equivalent global optimization problem.

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Section: Introductionmentioning

confidence: 79%

Continuum equilibria and global optimization for routing in dense static ad hoc networks

Silva¹,

Altman²,

Bernhard³

et al. 2010

Computer Networks

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“…They further showed that, in the limit of massively-dense networks, multiple-path routing for optimal load balancing can be achieved by using single-path routing [Hyytiä and Virtamo 2007a]. In addition, such a single-path routing depends on destination but not source and thus may be represented as a routing field [Hyytiä and Virtamo 2009]. Altman et al [2008] examined the routing problem of massively-dense networks in the context of road traffic engineering.…”

Section: Related Workmentioning

confidence: 99%

Gauss-seidel correction algorithm

Lin

Chiang

2013

ACM Trans. Sen. Netw.

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A Gauss-Seidel correction (GSC) routing algorithm for wireless sensor networks is presented in which packets are transmitted with additional information which can be exchanged among nodes to correct the current routing paths and achieve load balancing. The problem considered here is single-class routing to one/multiple sinks with lifetime maximization as the objective. The formulation to correct the routing paths is not heuristic and takes its theoretical basis from a macroscopic model, that is, based on a set of partial differential equations iteratively solved by the Gauss-Seidel method. We then theoretically investigate the convergence of GSC. Furthermore, an initial value estimation algorithm is presented to alleviate the longpath problem during the delivery of the first several packets, thus accelerating the convergence of GSC. Simulation results show that GSC effectively achieves load balancing, particularly for regions of interest with holes.

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“…In order to analyze the floating content concept, it is important to characterize the movement, e.g., how often a node crosses a given line segment. To this end, let ϕ(r, φ) denote the so-called angular node flux at r in direction φ, which is defined as the rate of nodes moving in direction (φ, φ+dφ) across a small perpendicular line segment of ds divided by ds · dφ at the limit ds, dφ → 0 [13], [15], as illustrated in Fig. 2.…”

Section: Preliminaries a Fluxes And Stationary Distributionmentioning

confidence: 99%

“…We develop models for analyzing the feasibility of the floating content concept by using spatial modeling techniques adopted from physics [13], similarly as have been used for modeling the capacity of so-called dense wireless multihop networks, see, e.g., [14], [15]. The fundamental objective is to establish the criticality condition for the system, i.e., an explicit relation which determines when the information remains available within the anchor zone infinitely long at the fluid limit (large population).…”

Section: Introductionmentioning

confidence: 99%

When does content float? Characterizing availability of anchored information in opportunistic content sharing

Hyytiä

Virtamo

Lassila

et al. 2011

2011 Proceedings IEEE INFOCOM

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Abstract-We consider an opportunistic content sharing system designed to store and distribute local spatio-temporal "floating" information in uncoordinated P2P fashion relying solely on the mobile nodes passing through the area of interest, referred to as the anchor zone. Nodes within the anchor zone exchange the information in opportunistic manner, i.e., whenever two nodes come within each others' transmission range. Outside the anchor zone, the nodes are free to delete the information, since it is deemed relevant only for the nodes residing inside the anchor zone. Due to the random nature of the operation, there are no guarantees, e.g., for the information availability. By means of analytical models, we show that such a system, without any supporting infrastructure, can be a viable and surprisingly reliable option for content sharing as long as a certain criterion, referred to as the criticality condition, is met. The important quantity is the average number of encounters a randomly chosen node experiences during its sojourn time in the anchor zone, which again depends on the communication range and the mobility pattern. The theoretical studies are complemented with simulation experiments with various mobility models showing good agreement with the analytical results.

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On the optimality of field-line routing in massively dense wireless multi-hop networks

Cited by 7 publications

References 21 publications

Continuum equilibria and global optimization for routing in dense static ad hoc networks

Continuum equilibria and global optimization for routing in dense static ad hoc networks

Gauss-seidel correction algorithm

When does content float? Characterizing availability of anchored information in opportunistic content sharing

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