Ozone Modeling Using Neural Networks

Ramesh Narasimhan Department of Chemical Engineering, University of Tulsa, Tulsa, Oklahoma

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Joleen Keller Department of Chemical Engineering, University of Tulsa, Tulsa, Oklahoma

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Ganesh Subramaniam Department of Chemical Engineering, University of Tulsa, Tulsa, Oklahoma

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Eric Raasch Department of Chemistry, University of Tulsa, Tulsa, Oklahoma

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Brandon Croley Department of Chemistry, University of Tulsa, Tulsa, Oklahoma

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Kathleen Duncan Department of Biological Sciences, University of Tulsa, Tulsa, Oklahoma

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William T. Potter Department of Chemistry, University of Tulsa, Tulsa, Oklahoma

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Abstract

Ozone models for the city of Tulsa were developed using neural network modeling techniques. The neural models were developed using meteorological data from the Oklahoma Mesonet and ozone, nitric oxide, and nitrogen dioxide (NO2) data from Environmental Protection Agency monitoring sites in the Tulsa area. An initial model trained with only eight surface meteorological input variables and NO2 was able to simulate ozone concentrations with a correlation coefficient of 0.77. The trained model was then used to evaluate the sensitivity to the primary variables that affect ozone concentrations. The most important variables (NO2, temperature, solar radiation, and relative humidity) showed response curves with strong nonlinear codependencies. Incorporation of ozone concentrations from the previous 3 days into the model increased the correlation coefficient to 0.82. As expected, the ozone concentrations correlated best with the most recent (1-day previous) values. The model’s correlation coefficient was increased to 0.88 by the incorporation of upper-air data from the National Weather Service’s Nested Grid Model. Sensitivity analysis for the upper-air variables indicated unusual positive correlations between ozone and the relative humidity from 500 hPa to the tropopause in addition to the other expected correlations with upper-air temperatures, vertical wind velocity, and 1000–500-hPa layer thickness. The neural model results are encouraging for the further use of these systems to evaluate complex parameter cosensitivities, and for the use of these systems in automated ozone forecast systems.

* Current affiliation: Clean Air Action Corporation, Tulsa, Oklahoma.

Corresponding author address: Dr. William T. Potter, Chemistry Dept., 600 S. College Ave., Tulsa, OK 74104.

Abstract

Ozone models for the city of Tulsa were developed using neural network modeling techniques. The neural models were developed using meteorological data from the Oklahoma Mesonet and ozone, nitric oxide, and nitrogen dioxide (NO2) data from Environmental Protection Agency monitoring sites in the Tulsa area. An initial model trained with only eight surface meteorological input variables and NO2 was able to simulate ozone concentrations with a correlation coefficient of 0.77. The trained model was then used to evaluate the sensitivity to the primary variables that affect ozone concentrations. The most important variables (NO2, temperature, solar radiation, and relative humidity) showed response curves with strong nonlinear codependencies. Incorporation of ozone concentrations from the previous 3 days into the model increased the correlation coefficient to 0.82. As expected, the ozone concentrations correlated best with the most recent (1-day previous) values. The model’s correlation coefficient was increased to 0.88 by the incorporation of upper-air data from the National Weather Service’s Nested Grid Model. Sensitivity analysis for the upper-air variables indicated unusual positive correlations between ozone and the relative humidity from 500 hPa to the tropopause in addition to the other expected correlations with upper-air temperatures, vertical wind velocity, and 1000–500-hPa layer thickness. The neural model results are encouraging for the further use of these systems to evaluate complex parameter cosensitivities, and for the use of these systems in automated ozone forecast systems.

* Current affiliation: Clean Air Action Corporation, Tulsa, Oklahoma.

Corresponding author address: Dr. William T. Potter, Chemistry Dept., 600 S. College Ave., Tulsa, OK 74104.

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