TY - GEN
T1 - On Board-Level Failure Localization in Optical Transport Networks Using Graph Neural Network
AU - Jiao, Yan
AU - Ho, Pin Han
AU - Lu, Xiangzhu
AU - Tapolcai, Janos
AU - Peng, Limei
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - This paper investigates a novel framework for board-level failure localization in the Optical Transport Networks (OTN), dubbed Board-Alarm Propagation Tree based Failure Localization (BAPT-FL). Foremost, a collection of functional graphs (FGs) is garnered by iteratively tagging each board in the network topology, serving as the ground of the proposed framework. Concretely, BAPT-FL is designed to build a range of BAPTs by correlating the tagged boards and alarms involved in the FGs, where each BAPT deems a failed board and its corre-lated alarms as the root and leaves, respectively. To evaluate the edge weights of potential BAPTs induced by FGs, a graph neural network (GNN) with the graph transformer operator is employed as an edge classifier, which characterizes each vertex/edge from diverse dimensions including time, traffic distribution, network topology, and board/alarm attributes. Subsequently, we frame an integer linear programming (ILP) problem to construct the best possible BAPT(s). Extensive case studies are conducted to showcase BAPT-FL's advantage over its counterparts in terms of the metrics assessing the identified failed boards/root alarms. We also delve into its performance in volatile environmental variations such as diverse failure scenarios, network topologies, traffic distributions, and noise alarms.
AB - This paper investigates a novel framework for board-level failure localization in the Optical Transport Networks (OTN), dubbed Board-Alarm Propagation Tree based Failure Localization (BAPT-FL). Foremost, a collection of functional graphs (FGs) is garnered by iteratively tagging each board in the network topology, serving as the ground of the proposed framework. Concretely, BAPT-FL is designed to build a range of BAPTs by correlating the tagged boards and alarms involved in the FGs, where each BAPT deems a failed board and its corre-lated alarms as the root and leaves, respectively. To evaluate the edge weights of potential BAPTs induced by FGs, a graph neural network (GNN) with the graph transformer operator is employed as an edge classifier, which characterizes each vertex/edge from diverse dimensions including time, traffic distribution, network topology, and board/alarm attributes. Subsequently, we frame an integer linear programming (ILP) problem to construct the best possible BAPT(s). Extensive case studies are conducted to showcase BAPT-FL's advantage over its counterparts in terms of the metrics assessing the identified failed boards/root alarms. We also delve into its performance in volatile environmental variations such as diverse failure scenarios, network topologies, traffic distributions, and noise alarms.
KW - board-level failure localization
KW - graph neural network (GNN)
KW - integer linear programming (ILP)
KW - Optical Trans-port Networks (OTN)
UR - http://www.scopus.com/inward/record.url?scp=85195549030&partnerID=8YFLogxK
U2 - 10.1109/DRCN60692.2024.10539167
DO - 10.1109/DRCN60692.2024.10539167
M3 - Conference contribution
AN - SCOPUS:85195549030
T3 - 20th International Conference on the Design of Reliable Communication Networks, DRCN 2024
SP - 54
EP - 61
BT - 20th International Conference on the Design of Reliable Communication Networks, DRCN 2024
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 20th International Conference on the Design of Reliable Communication Networks, DRCN 2024
Y2 - 6 May 2024 through 9 May 2024
ER -