Bayesian Topology Learning and noise removal from network data

Bayesian Topology Learning and noise removal from network data

Learning the topology of a graph from available data is of great interest in many emerging applications. Some examples are social networks, internet of things networks (intelligent IoT and industrial IoT), biological connection networks, sensor networks and traffic network patterns. In this paper, a...

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Bibliographic Details
Published in:Discover Internet of things Vol. 1; no. 1
Main Authors: Ramezani Mayiami, Mahmoud, Hajimirsadeghi, Mohammad, Skretting, Karl, Dong, Xiaowen, Blum, Rick S., Poor, H. Vincent
Format: Journal Article
Language:English
Published: Cham Springer International Publishing 01-12-2021
Springer Nature B.V
Subjects:
Algorithms
Computer Science
Cyber-physical systems
Electrical Engineering
Information Systems Applications (incl.Internet)
Internet of Things
IoT
Optimization
Random variables
Sensors
Signal processing
Topology learning
Internet of things
Signal representation
Bayesian inference
Graph signal processing
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Summary:Learning the topology of a graph from available data is of great interest in many emerging applications. Some examples are social networks, internet of things networks (intelligent IoT and industrial IoT), biological connection networks, sensor networks and traffic network patterns. In this paper, a graph topology inference approach is proposed to learn the underlying graph structure from a given set of noisy multi-variate observations, which are modeled as graph signals generated from a Gaussian Markov Random Field (GMRF) process. A factor analysis model is applied to represent the graph signals in a latent space where the basis is related to the underlying graph structure. An optimal graph filter is also developed to recover the graph signals from noisy observations. In the final step, an optimization problem is proposed to learn the underlying graph topology from the recovered signals. Moreover, a fast algorithm employing the proximal point method has been proposed to solve the problem efficiently. Experimental results employing both synthetic and real data show the effectiveness of the proposed method in recovering the signals and inferring the underlying graph.
ISSN:2730-7239
2730-7239
DOI:10.1007/s43926-021-00011-w