Approximating maximum integral flows in wireless sensor networks via weighted-degree constrained k-flows

Abstract: We consider the Maximum Integral Flow with Energy Constraints problem: given a directed graph G = (V, E) with edge-weights {w(e) : e ∈ E} and node battery capacities {b(v) : v ∈ V }, and two nodes r, s ∈ V , find a maximum integral rs-flow f so that for every node v its energy consumptionLet k be the maximum integral flow value. We give a polynomial time algorithm that computes a flow of value at least k/16 . As checking whether k ≥ 1 can be done in polynomial time, this gives an approximation algorithm with r… Show more

“…In the Single Topology variant, all the networks H i are identical, c.f., [6] for more details. We note that in [16] was given a constant ratio approximation algorithm for the case when each H i should be an st-path, for given s, t ∈ V . Here we consider the case when each H i is an arborescence rooted from/to the root r.…”

Improved Approximation Algorithms for Maximum Lifetime Problems in Wireless Networks

“…In the Single Topology variant, all the networks H i are identical, c.f., [6] for more details. We note that in [16] was given a constant ratio approximation algorithm for the case when each H i should be an st-path, for given s, t ∈ V . Here we consider the case when each H i is an arborescence rooted from/to the root r.…”

Improved Approximation Algorithms for Maximum Lifetime Problems in Wireless Networks

Improved Approximation Bounds for Maximum Lifetime Problems in Wireless Ad-Hoc Network

Approximation Bounds on the Number of Mixedcast Rounds in Wireless Ad-Hoc Networks