Bayesian networks based rare event prediction with sensor data

A Bayesian network is a powerful graphical model. It is advantageous for real-world data analysis and finding relations among variables. Knowledge presentation and rule generation, based on a Bayesian approach, have been studied and reported in many research papers across various fields. Since a Bayesian network has both causal and probabilistic semantics, it is regarded as an ideal representation to combine background knowledge and real data. Rare event predictions have been performed using several methods, but remain a challenge. We design and implement a Bayesian network model to forecast daily ozone states. We evaluate the proposed Bayesian network model, comparing it to traditional decision tree models, to examine its utility.

[1]  Steen Andreassen,et al.  MUNIN - A Causal Probabilistic Network for Interpretation of Electromyographic Findings , 1987, IJCAI.

[2]  J. Ross Quinlan,et al.  C4.5: Programs for Machine Learning , 1992 .

[3]  Michael J. A. Berry,et al.  Data mining techniques - for marketing, sales, and customer support , 1997, Wiley computer publishing.

[4]  Seong Sin Kim,et al.  A Neuro-Fuzzy Approach to Integration and Control of Industrial Processes : Part I , 1998 .

[5]  David J. Spiegelhalter,et al.  Local computations with probabilities on graphical structures and their application to expert systems , 1990 .

[6]  Seong-Pyo Cheon,et al.  Directed Knowledge Discovery Methodology for the Prediction of Ozone Concentration , 2005, FSKD.

[7]  J. Seinfeld,et al.  Atmospheric Chemistry and Physics: From Air Pollution to Climate Change , 1997 .

[8]  T. Davies,et al.  Surface ozone concentrations in Europe: Links with the regional‐scale atmospheric circulation , 1992 .

[9]  Theodore Johnson,et al.  Exploratory Data Mining and Data Cleaning , 2003 .

[10]  D. Heckerman,et al.  Toward Normative Expert Systems: Part I The Pathfinder Project , 1992, Methods of Information in Medicine.

[11]  David Heckerman,et al.  A Tutorial on Learning with Bayesian Networks , 1999, Innovations in Bayesian Networks.

[12]  David Heckerman,et al.  Causal independence for probability assessment and inference using Bayesian networks , 1996, IEEE Trans. Syst. Man Cybern. Part A.

[13]  Duc Truong Pham,et al.  Neural Networks for Identification, Prediction and Control , 1995 .

[14]  Gavin C. Cawley,et al.  A rigorous inter-comparison of ground-level ozone predictions , 2003 .

[15]  S L Zeger,et al.  Air pollution and mortality in Philadelphia, 1974-1988. , 1997, American journal of epidemiology.

[16]  I. J. Good,et al.  Amount of Deciding and Decisionary Effort , 1961, Inf. Control..

[17]  W. Youden,et al.  Index for rating diagnostic tests , 1950, Cancer.

[18]  Judea Pearl,et al.  Convince: A Conversational Inference Consolidation Engine , 1987, IEEE Transactions on Systems, Man, and Cybernetics.

[19]  E. Mantilla,et al.  Meteorology and photochemical air pollution in Southern Europe: Experimental results from EC research projects , 1996 .

[20]  Robert L. Heath,et al.  Forest decline and ozone. A comparison of controlled chamber and field experiments. , 1997 .

[21]  J D Spengler,et al.  Acute effects of summer air pollution on respiratory symptom reporting in children. , 1994, American journal of respiratory and critical care medicine.

[22]  J. Mason,et al.  Efficacy and cost of cardiac monitoring in patients receiving doxorubicin , 1982, Cancer.

[23]  R. Burnett,et al.  Association between ozone and hospitalization for acute respiratory diseases in children less than 2 years of age. , 2001, American journal of epidemiology.

[24]  D. O. Lee Trends in summer visibility in London and Southern England 1962–1979 , 1983 .