Experimental Validation of Fully Quantum Fluctuation Theorems Using Dynamic Bayesian Networks

Pyroelectric infrared (PIR) sensors can detect the presence of human without the need to carry any device, which are widely used for human presence detection in home/office automation systems in order to improve energy efficiency. However, PIR detection is based on the movement of occupants. For occupancy detection, PIR sensors have inherent limitation when occupants remain relatively still. Multisensor fusion technology takes advantage of redundant, complementary, or more timely information from different modal sensors, which is considered an effective approach for solving the uncertainty and unreliability problems of sensing. In this paper, we proposed a simple multimodal sensor fusion algorithm, which is very suitable to be manipulated by the sensor nodes of wireless sensor networks. The inference algorithm was evaluated for the sensor detection accuracy and compared to the multisensor fusion using dynamic Bayesian networks. The experimental results showed that a detection accuracy of 97% in room occupancy can be achieved. The accuracy of occupancy detection is very close to that of the dynamic Bayesian networks.

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An anomaly detection technique for business processes based on extended dynamic bayesian networks

Proceedings of the 34th ACM/SIGAPP Symposium on Applied Computing - SAC '19 ◽

10.1145/3297280.3297326 ◽

2019 ◽

Cited By ~ 6

Author(s):

Stephen Pauwels ◽

Toon Calders

Keyword(s):

Anomaly Detection ◽

Bayesian Networks ◽

Business Processes ◽

Dynamic Bayesian Networks ◽

Detection Technique ◽

Extended Dynamic

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A dynamic Bayesian network approach for prognosis computations on discrete state systems

Proceedings of the Institution of Mechanical Engineers Part O Journal of Risk and Reliability ◽

10.1177/1748006x17712661 ◽

2017 ◽

Vol 231 (5) ◽

pp. 516-533 ◽

Cited By ~ 3

Author(s):

Josquin Foulliaron ◽

Laurent Bouillaut ◽

Patrice Aknin ◽

Anne Barros

Keyword(s):

Complex Systems ◽

Bayesian Networks ◽

Bayesian Network ◽

Multicomponent System ◽

Dynamic Bayesian Network ◽

Dynamic Bayesian Networks ◽

Remaining Useful Life ◽

Predictive Maintenance ◽

Discrete State ◽

Virtual Maintenance

The maintenance optimization of complex systems is a key question. One important objective is to be able to anticipate future maintenance actions required to optimize the logistic and future investments. That is why, over the past few years, the predictive maintenance approaches have been an expanding area of research. They rely on the concept of prognosis. Many papers have shown how dynamic Bayesian networks can be relevant to represent multicomponent complex systems and carry out reliability studies. The diagnosis and maintenance group from French institute of science and technology for transport, development and networks (IFSTTAR) developed a model (VirMaLab: Virtual Maintenance Laboratory) based on dynamic Bayesian networks in order to model a multicomponent system with its degradation dynamic and its diagnosis and maintenance processes. Its main purpose is to model a maintenance policy to be able to optimize the maintenance parameters due to the use of dynamic Bayesian networks. A discrete state-space system is considered, periodically observable through a diagnosis process. Such systems are common in railway or road infrastructure fields. This article presents a prognosis algorithm whose purpose is to compute the remaining useful life of the system and update this estimation each time a new diagnosis is available. Then, a representation of this algorithm is given as a dynamic Bayesian network in order to be next integrated into the Virtual Maintenance Laboratory model to include the set of predictive maintenance policies. Inference computation questions on the considered dynamic Bayesian networks will be discussed. Finally, an application on simulated data will be presented.

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Adaptive learning of dynamic Bayesian networks with changing structures by detecting geometric structures of time series

Knowledge and Information Systems ◽

10.1007/s10115-008-0175-x ◽

2008 ◽

Vol 17 (2) ◽

pp. 263-263

Author(s):

Kaijun Wang ◽

Junying Zhang ◽

Fengshan Shen ◽

Lingfeng Shi

Keyword(s):

Time Series ◽

Bayesian Networks ◽

Adaptive Learning ◽

Dynamic Bayesian Networks ◽

Geometric Structures

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Assessment of Safety Integrity Level by simulation of Dynamic Bayesian Networks considering test duration

Journal of Loss Prevention in the Process Industries ◽

10.1016/j.jlp.2018.11.002 ◽

2019 ◽

Vol 57 ◽

pp. 101-113 ◽

Cited By ~ 2

Author(s):

Christophe Simon ◽

Walid Mechri ◽

Guillaume Capizzi

Keyword(s):

Bayesian Networks ◽

Dynamic Bayesian Networks ◽

Test Duration ◽

Safety Integrity Level

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The engineering skills training process modeling using dynamic bayesian nets

RADIOELECTRONIC AND COMPUTER SYSTEMS ◽

10.32620/reks.2021.2.08 ◽

2021 ◽

pp. 87-96

Author(s):

Andrey Chukhray ◽

Olena Havrylenko

Keyword(s):

Bayesian Networks ◽

Bayesian Network ◽

Learning Process ◽

Probabilistic Inference ◽

Dynamic Bayesian Network ◽

Computer Training ◽

Skills Training ◽

Dynamic Bayesian Networks ◽

Competence Level ◽

Intelligent Computer

The subject of research in the article is the process of intelligent computer training in engineering skills. The aim is to model the process of teaching engineering skills in intelligent computer training programs through dynamic Bayesian networks. Objectives: To propose an approach to modeling the process of teaching engineering skills. To assess the student competence level by considering the algorithms development skills in engineering tasks and the algorithms implementation ability. To create a dynamic Bayesian network structure for the learning process. To select values for conditional probability tables. To solve the problems of filtering, forecasting, and retrospective analysis. To simulate the developed dynamic Bayesian network using a special Genie 2.0-environment. The methods used are probability theory and inference methods in Bayesian networks. The following results are obtained: the development of a dynamic Bayesian network for the educational process based on the solution of engineering problems is presented. Mathematical calculations for probabilistic inference problems such as filtering, forecasting, and smoothing are considered. The solution of the filtering problem makes it possible to assess the current level of the student's competence after obtaining the latest probabilities of the development of the algorithm and its numerical calculations of the task. The probability distribution of the learning process model is predicted. The number of additional iterations required to achieve the required competence level was estimated. The retrospective analysis allows getting a smoothed assessment of the competence level, which was obtained after the task's previous instance completion and after the computation of new additional probabilities characterizing the two checkpoints implementation. The solution of the described probabilistic inference problems makes it possible to provide correct information about the learning process for intelligent computer training systems. It helps to get proper feedback and to track the student's competence level. The developed technique of the kernel of probabilistic inference can be used as the decision-making model basis for an automated training process. The scientific novelty lies in the fact that dynamic Bayesian networks are applied to a new class of problems related to the simulation of engineering skills training in the process of performing algorithmic tasks.

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