Graph-based conflict-free MAC protocol and conflict analysis for a two-layer ultraviolet communication network

Yuchen Pan; Guanchu Wang; Yubo Zhang; Jingyin Tang; Chen Gong; Zhengyuan Xu

doi:10.1364/JOCN.489307

Journal of Optical Communications and Networking
Vol. 15,
Issue 6,
pp. 381-392
(2023)
•https://doi.org/10.1364/JOCN.489307

Graph-based conflict-free MAC protocol and conflict analysis for a two-layer ultraviolet communication network

Yuchen Pan, Guanchu Wang, Yubo Zhang, Jingyin Tang, Chen Gong, and Zhengyuan Xu

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Yuchen Pan, Guanchu Wang, Yubo Zhang, Jingyin Tang, Chen Gong, and Zhengyuan Xu, "Graph-based conflict-free MAC protocol and conflict analysis for a two-layer ultraviolet communication network," J. Opt. Commun. Netw. 15, 381-392 (2023)

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Abstract

To efficiently exploit the space division multiplexing of ultraviolet (UV) communication, we apply link coverage characteristics to construct a conflict graph and design conflict-free protocols for a two-layer UV communication network. The network is divided into two layers: the first-layer network forms a backbone and the second-layer network serves as local access. We construct a routing model and medium-access control (MAC) model. Then we propose Routing-MAC joint scheduling for the first-layer network based on the conflict graph. We investigate the system throughput and delay of joint scheduling under different node intensities. For second-layer networks, we propose a multi-link conflict-free protocol adopting protocol frames of carrier sense multiple access with collision avoidance (CSMA/CA). Numerical results show that the multi-link conflict-free protocol can improve the system throughput by more than 100% compared with CSMA/CA. Moreover, we perform a conflict analysis on the proposed protocols to investigate the influence of conflict intensity. According to the conflict analysis, we optimize the path planning of Routing-MAC joint scheduling to reduce the average delay of the network. Numerical results show that the optimized Routing-MAC joint scheduling leads to larger system throughput and lower delay.

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Equations (23)

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Symbol	Physical Meaning
$\vec{b}$	Vector of the backoff value for $N$ nodes
$\vec{n}$	Vector of the node index corresponding to the minimum backoff value
${\vec{d}}_{n}$	Vector of the destination for $N$ nodes
Idle	Indicator of an idle channel for a DIFS

Symbol	Physical Meaning	Value/Unit
$S$	Simulation area size	$0.5 {k m}^{2}$
$α$	Directional antenna elevation angle	10°–30°
$λ$	Node intensity	10–40
$P_{t}$	Given power per node	0.2 W
$P_{min}^{r}$	Minimum reception power threshold	$10^{- 10} W$
$P_{min}^{c}$	Minimum conflict power threshold	$5 \times 10^{- 11} W$

Symbol	Physical Meaning
$\vec{b}$	Vector of the backoff value for $N$ nodes
$\vec{n}$	Vector of the node index corresponding to the minimum backoff value
${\vec{d}}_{n}$	Vector of the destination for $N$ nodes
Idle	Indicator of an idle channel for a DIFS

Symbol	Physical Meaning	Value/Unit
$S$	Simulation area size	$0.5 {k m}^{2}$
$α$	Directional antenna elevation angle	10°–30°
$λ$	Node intensity	10–40
$P_{t}$	Given power per node	0.2 W
$P_{min}^{r}$	Minimum reception power threshold	$10^{- 10} W$
$P_{min}^{c}$	Minimum conflict power threshold	$5 \times 10^{- 11} W$

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Equations (23)

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