Wireless Network Scheduling With Discrete Propagation Delays: Theorems and Algorithms

The literature provides evidence that considering signal propagation delays can significantly enhance the scheduling rate region of wireless networks. This paper focuses on the link scheduling problem in networks where signal delays between nodes are multiples of a time interval. To model such netwo...

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Bibliographic Details
Published inIEEE transactions on information theory Vol. 70; no. 3; pp. 1852 - 1875
Main Authors Yang, Shenghao, Ma, Jun, Liu, Yanxiao
Format Journal Article
LanguageEnglish
Published New York IEEE 01.03.2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Algorithms
Apexes
Collision avoidance
Convexity
Delays
Enumeration
Graph theory
Graphs
network scheduling
OFDM
Propagation delay
Scheduling
Symbols
Underwater acoustics
Wireless network
Wireless networks
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Summary:The literature provides evidence that considering signal propagation delays can significantly enhance the scheduling rate region of wireless networks. This paper focuses on the link scheduling problem in networks where signal delays between nodes are multiples of a time interval. To model such networks, a directed hypergraph is employed, along with an integer matrix that specifies the delays. The link scheduling problem is closely connected to the independent sets of the periodic hypergraph induced by the network model. However, due to the infinite number of vertices, it is impractical to enumerate the independent sets of the periodic hypergraph using generic graph algorithms. To tackle this challenge, a graphical approach is proposed in this paper. The link scheduling rate region is characterized using a finite directed graph called a scheduling graph, which is derived from the network model. A collision-free schedule of the network corresponds to a path in the scheduling graph, and the rate region is determined by the convex hull of the rate vectors associated with the cycles in the scheduling graph. Although existing cycle enumeration algorithms can be employed to calculate the rate region, their computational complexity becomes prohibitively high as the size of the scheduling graph grows exponentially with the number of network links. To address this issue, the dominance property of a special scheduling graph called the step-<inline-formula> <tex-math notation="LaTeX">T </tex-math></inline-formula> scheduling graph is investigated. This property allows the utilization of specific subgraphs of the step-<inline-formula> <tex-math notation="LaTeX">T </tex-math></inline-formula> scheduling graph to characterize the scheduling rate region, achieving a reduction in both the number of cycles and their lengths. For common problems such as calculating the rate region and maximizing a weighted sum of the scheduling rates, algorithms leveraging the dominance property are developed. These algorithms can be more efficient than using generic graph algorithms directly on the scheduling graphs.
ISSN:0018-9448
1557-9654
DOI:10.1109/TIT.2023.3324180