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1. Spatiotemporal Estimation of TROPOMI NO2 Column with Depthwise Partial Convolutional Neural Network

Author

Lops, Yannic, Ghahremanloo, Masoud, Pouyaei, Arman, Choi, Yunsoo, Jung, Jia, Mousavinezhad, Seyedali, Salman, Ahmed Khan, and Hammond, Davyda

Subjects
Physics - Atmospheric and Oceanic Physics, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

Satellite-derived measurements are negatively impacted by cloud cover and surface reflectivity. These biases must be discarded and significantly increase the amount of missing data within remote sensing images. This paper expands the application of a partial convolutional neural network (PCNN) to incorporate depthwise convolution layers, conferring temporal dimensionality to the imputation process. The addition of a temporal dimension to the imputation process adds a state of successive existence within the dataset which spatial imputation cannot capture. The depthwise convolution process enables the PCNN to independently convolve the data for each channel. The deep learning system is trained with the Community Multiscale Air Quality model-simulated tropospheric column density of Nitrogen Dioxide (TCDNO2) to impute TROPOspheric Monitoring Instrument TCDNO2. The depthwise PCNN model achieves an index of agreement of 0.82 and outperforms the default PCNN models, with and without temporal dimensionality of data, and conventional data imputation methods such as inverse distance weighting by 3-11% and 8-15% in the index of agreement and correlation, respectively. The model demonstrates more consistency in the reconstruction of TROPOspheric Monitoring Instrument tropospheric column density of NO2 images. The model has also demonstrated the accurate imputation of remote sensing images with over 95% of the data missing. PCNN enables the accurate imputation of remote sensing data with large regions of missing data and will benefit future researchers conducting data assimilation for numerical models, emission studies, and human health impact analyses from air pollution., Comment: Keywords: Partial Convolution, Depthwise, TROPOMI, Kriging, Spatiotemporal Imputation, CMAQ. 12 pages & 6 figures

Published
2022

4. A Deep Convolutional Neural Network Model for improving WRF Forecasts

Author

Sayeed, Alqamah, Choi, Yunsoo, Jung, Jia, Lops, Yannic, Eslami, Ebrahim, and Salman, Ahmed Khan

Subjects
Physics - Atmospheric and Oceanic Physics, Computer Science - Machine Learning
Abstract

Advancements in numerical weather prediction models have accelerated, fostering a more comprehensive understanding of physical phenomena pertaining to the dynamics of weather and related computing resources. Despite these advancements, these models contain inherent biases due to parameterization and linearization of the differential equations that reduce forecasting accuracy. In this work, we investigate the use of a computationally efficient deep learning method, the Convolutional Neural Network (CNN), as a post-processing technique that improves mesoscale Weather and Research Forecasting (WRF) one day forecast (with a one-hour temporal resolution) outputs. Using the CNN architecture, we bias-correct several meteorological parameters calculated by the WRF model for all of 2018. We train the CNN model with a four-year history (2014-2017) to investigate the patterns in WRF biases and then reduce these biases in forecasts for surface wind speed and direction, precipitation, relative humidity, surface pressure, dewpoint temperature, and surface temperature. The WRF data, with a spatial resolution of 27 km, covers South Korea. We obtain ground observations from the Korean Meteorological Administration station network for 93 weather station locations. The results indicate a noticeable improvement in WRF forecasts in all station locations. The average of annual index of agreement for surface wind, precipitation, surface pressure, temperature, dewpoint temperature and relative humidity of all stations are 0.85 (WRF:0.67), 0.62 (WRF:0.56), 0.91 (WRF:0.69), 0.99 (WRF:0.98), 0.98 (WRF:0.98), and 0.92 (WRF:0.87), respectively. While this study focuses on South Korea, the proposed approach can be applied for any measured weather parameters at any location., Comment: CNN, weather forecast, WRF, Artificial Intelligence, Machine Learning, wind speed forecast, rainfall forecast

Published
2020
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5. A Novel CMAQ-CNN Hybrid Model to Forecast Hourly Surface-Ozone Concentrations Fourteen Days in Advance

Author

Sayeed, Alqamah, Choi, Yunsoo, Eslami, Ebrahim, Jung, Jia, Lops, Yannic, and Salman, Ahmed Khan

Subjects
Physics - Atmospheric and Oceanic Physics, Computer Science - Machine Learning, Statistics - Applications
Abstract

Issues regarding air quality and related health concerns have prompted this study, which develops an accurate and computationally fast, efficient hybrid modeling system that combines numerical modeling and machine learning for forecasting concentrations of surface ozone. Currently available numerical modeling systems for air quality predictions (e.g., CMAQ, NCEP EMP) can forecast 24 to 48 hours in advance. In this study, we develop a modeling system based on a convolutional neural network (CNN) model that is not only fast but covers a temporal period of two weeks with a resolution as small as a single hour for 255 stations. The CNN model uses forecasted meteorology from the Weather Research and Forecasting model (processed by the Meteorology-Chemistry Interface Processor), forecasted air quality from the Community Multi-scale Air Quality Model (CMAQ), and previous 24-hour concentrations of various measurable air quality parameters as inputs and predicts the following 14-day hourly surface ozone concentrations. The model achieves an average accuracy of 0.91 in terms of the index of agreement for the first day and 0.78 for the fourteenth day while the average index of agreement for one day ahead prediction from the CMAQ is 0.77. Through this study, we intend to amalgamate the best features of numerical modeling (i.e., fine spatial resolution) and a deep neural network (i.e., computation speed and accuracy) to achieve more accurate spatio-temporal predictions of hourly ozone concentrations. Although the primary purpose of this study is the prediction of hourly ozone concentrations, the system can be extended to various other pollutants., Comment: 15 pages, 4 main figures and supplemantary figures and tables

Published
2020
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6. A real-time hourly ozone prediction system using deep convolutional neural network

Author

Eslami, Ebrahim, Choi, Yunsoo, Lops, Yannic, and Sayeed, Alqamah

Subjects
Physics - Atmospheric and Oceanic Physics
Abstract

This study uses a deep learning approach to forecast ozone concentrations over Seoul, South Korea for 2017. We employ a deep convolutional neural network (CNN). We apply this method to predict the hourly ozone concentration on each day for the entire year using several predictors from the previous day, including the wind fields, temperature, relative humidity, pressure, and precipitation, along with in-situ ozone and NO2 concentrations. We refer to a history of all observed parameters between 2014 and 2016 for training the predictive models. Model-measurement comparisons for the 25 monitoring sites for the year 2017 report average indexes of agreement (IOA) of 0.84-0.89 and a Pearson correlation coefficient of 0.74-0.81, indicating reasonable performance for the CNN forecasting model. Although the CNN model successfully captures daily trends as well as yearly high and low variations of the ozone concentrations, it notably underpredicts high ozone peaks during the summer. The forecasting results are generally more accurate for the stations located in the southern regions of the Han River, the result of more stable topographical and meteorological conditions. Furthermore, through two separate daytime and nighttime forecasts, we find that the monthly IOA of the CNN model is 0.05-0.30 higher during the daytime, resulting from the unavailability of some of the input parameters during the nighttime. While the CNN model can predict the next 24 hours of ozone concentrations within less than a minute, we identify several limitations of deep learning models for real-time air quality forecasting for further improvement.

Published
2019

23. Spatiotemporal estimation of TROPOMI NO2 column with depthwise partial convolutional neural network.

Author

Lops, Yannic, Ghahremanloo, Masoud, Pouyaei, Arman, Choi, Yunsoo, Jung, Jia, Mousavinezhad, Seyedali, Salman, Ahmed Khan, and Hammond, Davyda

Subjects
*CONVOLUTIONAL neural networks, *DEEP learning, *MISSING data (Statistics), *CLOUDINESS, *AIR pollution, *NITROGEN dioxide
Abstract

Satellite-derived measurements are negatively impacted by cloud cover and surface reflectivity. These biases must be discarded and significantly increase the amount of missing data within remote sensing images. This paper expands the application of a partial convolutional neural network (PCNN) to incorporate depthwise convolution layers, conferring temporal dimensionality to the imputation process. The addition of a temporal dimension to the imputation process adds a state of successive existence within the dataset, which spatial imputation cannot capture. The depthwise convolution process enables the PCNN to independently convolve the data for each channel. The deep learning system is trained with the Community Multiscale Air Quality model-simulated tropospheric column density of Nitrogen Dioxide (TCDNO2) to impute TROPOspheric Monitoring Instrument TCDNO2. The depthwise PCNN model achieves an index of agreement of 0.88 and outperforms the default PCNN models, with and without temporal dimensionality of data, and conventional data imputation methods such as inverse distance weighting by 4–7 and 10–15% in the index of agreement and correlation, respectively. The model demonstrates more consistency in the reconstruction of TROPOspheric Monitoring Instrument tropospheric column density of NO2 images. The model has also demonstrated the accurate imputation of remote sensing images with over 95% of the data missing. PCNN enables the accurate imputation of remote sensing data with large regions of missing data and will benefit future researchers conducting data assimilation for numerical models, emission studies, and human health impact analyses from air pollution. [ABSTRACT FROM AUTHOR]

Published
2023
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26. A Coupled Deep Learning Model for Estimating Surface NO2 Levels From Remote Sensing Data: 15‐Year Study Over the Contiguous United States.

Author

Ghahremanloo, Masoud, Lops, Yannic, Choi, Yunsoo, Mousavinezhad, Seyedali, and Jung, Jia

Subjects
DEEP learning, REMOTE sensing, CONVOLUTIONAL neural networks, STANDARD deviations, REMOTE-sensing images, INDEPENDENT variables
Abstract

This study proposes a novel two‐step deep learning (DL) model for estimating surface NO2 concentrations using satellite data over the contiguous United States (CONUS) from 2005 to 2019. The first phase of the model uses partial convolutional neural network (PCNN), an advanced DL model that accurately imputes gaps between surface NO2 stations and creates 5,478 daily‐mean NO2 grids (PCNN‐NO2) of the 2005–2019 period over the study area. We then feed the PCNN‐NO2, along with other predictor variables, into a deep neural network (DNN) to estimate surface NO2 levels, achieving exceptional performance with a correlation coefficient of 0.975–0.978, a mean absolute bias of 0.99–1.38 ppb, and a root mean square error of 1.47–1.97 ppb. Spatial cross‐validation results also indicate strong spatial performance of PCNN‐DNN surface NO2 estimates. In addition to its accurate estimates, the PCNN‐DNN model consistently generates estimated NO2 grids without any missing values, improving the quality of various applications such as emission reduction strategies and public health studies. Between 2005 and 2019, the 5,478 daily estimated NO2 grids over the CONUS reveal significant reductions in NO2 levels in 14 major urban environments: Washington D.C. (−43%), New York (−45%), Los Angeles (−38%), Chicago (−25%), Boston (−43%), Houston (−34%), Dallas (−40%), Philadelphia (−41%), Phoenix (−38%), Detroit (−20%), Denver (−23%), Atlanta (−0.7%), Cincinnati (−38%), and Pittsburgh (−56%). Furthermore, the study shows that the denser urban regions that in‐situ stations are installed in, the higher the difference between in‐situ observations and regional‐mean NO2 levels. Plain Language Summary: Despite the significance of NO2 monitoring stations, their number and spatial coverage is limited, leaving many regions with no NO2 observations. This limitation calls for the development of advanced models to fill the gaps between NO2 stations and create gap‐free spatiotemporally‐consistent grids of surface NO2 concentrations. Recent advances in deep learning (DL) algorithms have enabled them to fill the gaps in various images, such as those representing the human face, nature, etc. with plausible contents. This technology can also be applied to fill the gaps between surface NO2 stations when the model is trained on datasets such as satellite tropospheric column density of NO2 images, available in almost all regions. In this study, we introduce a novel DL model to construct daily gap‐free grids of estimated NO2 levels over the contiguous United States from 2005 to 2019, obtaining exceptional performance with a correlation coefficient of 0.975–0.978. The first phase of the model uses a partial convolutional neural network, trained mainly by satellite images, to fill the gaps between surface NO2 stations, and the second phase utilizes a deep neural network to bias correct the output of the first phase. Key Points: A novel two‐step deep learning model is used to estimate surface NO2 levels, with exceptional accuracy, over the contiguous United StatesThe partial convolutional neural network used satellite images to fill the gaps between surface NO2 stationsNO2 levels decreased significantly in most urban environments in the United States from 2005 to 2019 [ABSTRACT FROM AUTHOR]

Published
2023
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33. Real-time 7-Day Forecast of Pollen Counts Using Deep Convolutional Neural Network

Author

Lops, Yannic, Eslami, Ebrahim, Yunsoo Choi, and Alqamah Sayeed

Abstract

This study implements a deep convolutional neural network with the great potential to recognize patterns of pollen phenomena that enable the prediction of pollen concentrations. We trained the model using data from 2009 to 2015 from multiple meteorological data sets, satellite data, and processed data reflecting pollen flux as input for the model. The model forecasts pollen counts one to seven days ahead for the entire year of 2016. Comparison of daily forecasts to observations, the algorithm obtains a relatively high index of agreement and Pearson correlation coefficient of up to 0.90 and 0.88 respectively. An evaluation of categorical statistics based on defined threshold levels shows satisfactory results. Critical Success Index of the model forecasts is as high as 0.887 for weed pollen, 0.646 for tree pollen, and 0.294 for grass pollen. Compared to the conventional modeling approaches, the convolutional neural network shows a promising ability to predict pollen for multiple days. This poster was presented at the Earth Science Information Partners (ESIP) Winter Meeting in January 2019.

Published
2019
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34. Can Deep Learning Improve CMAQ Performance?

Author

Eslami, Ebrahim, Alqamah Sayeed, Yunsoo Choi, and Lops, Yannic

Abstract

Three-dimensional Eulerian chemical transport models such as CMAQ often report a significant model-measurement error due to uncertainties in the treatment of physical processes and require higher run-time. Machine models are more computationally efficient and are currently used widely for forecasting purposes. Deep Neural network (DNN) techniques comprise a popular class of machine learning methods. Predicting hourly air quality, especially ozone, is challenging due to its highly varying and complex behavior in the atmosphere. Here, we used modeled meteorological parameters (by MCIP) along with selected modeled gaseous species (by CMAQ) as our inputs for predicting future ozone concentrations. A timely-efficient 1D deep convolutional neural network (ConvNet 1D), called CMAQ-CNN, was implemented and trained on using CMAQ outputs as inputs to predict hourly ozone concentration in real-time across the continental US (1081 AQS stations in 48 states). The CMAQ-CNN model significantly improved the performance of the CMAQ model in term of both accuracy (IOA) and bias (maximum daily ozone). IOA improved around 0.06 in average and up to 0.3 across the United States by using CMAQ-CNN model. The CMAQ-CNN model shows mediocre performance on capturing very high ozone peaks (over 90 ppb). This poster was presented at the Earth Science Information Partners (ESIP) Winter Meeting in January 2019.

Published
2019
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35. Ebrahim_Eslami_Hurricane.pdf

Author

Eslami, Ebrahim, Yunsoo Choi, Lops, Yannic, and Alqamah Sayeed

Abstract

Tracking the path and forecasting the intensity of hurricanes are challenging. Dynamical models produce a significant model-measurement error. Accurate forecasting is very difficult to achieve after landfall. For track forecasting (where the storm is going to go), dynamical models are generally the best. For intensity forecasting, statistical models generally perform better. We can combine the advantages of both models using a machine learning ensemble approach. Machine learning models are computationally efficient and are currently used widely for forecasting and ensemble purposes. Deep Neural network (DNN) techniques comprise a popular and powerful class of machine learning methods. We developed a three-step DNN-based ensemble hurricane forecasting model using the output of eight dynamical hurricane models being used in ATCF system for forecasting hurricane track and intensity. We used all tropical cyclones in Atlantic Ocean from 2003-2016 and tested the model for those in 2017. The preliminary results of our model show statistical advantages over NHC official forecasts. This poster was presented at the Earth Science Information Partners (ESIP) Winter Meeting in January 2019.

Published
2019
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36. Deep Learning Estimation of Daily Ground‐Level NO2 Concentrations From Remote Sensing Data.

Author

Ghahremanloo, Masoud, Lops, Yannic, Choi, Yunsoo, and Yeganeh, Bijan

Subjects
NITROGEN dioxide, MACHINE learning, SUPPORT vector machines, RANDOM forest algorithms, AIR quality
Abstract

The limited number of nitrogen dioxide (NO2) surface measurements calls for the development of highly accurate approaches to estimating surface NO2 concentrations. In this study, we leverage a new satellite instrument, the TROPOspheric Monitoring Instrument (TROPOMI), along with other predictor variables, to estimate daily surface NO2 concentrations over Texas in 2019. We use the deep convolutional neural network (Deep‐CNN), an advanced deep learning algorithm, to obtain estimates and achieve a correlation coefficient (R) of 0.91, an index of agreement (IOA) of 0.95, and a mean absolute bias (MAB) of 1.75 ppb in surface NO2 estimation. Additionally, we leverage a novel approach, shapley additive explanations (SHAP), to describe how Deep‐CNN understands each predictor variable. The SHAP results show that the Deep‐CNN model has an advanced understanding of the data set, revealing that TROPOMI closely captures levels of NO2. In addition, we show the superiority of our Deep‐CNN model at estimating surface NO2 over other well‐known machine learning and regression models in the field, including the support vector machines (SVM), random forest (RF), and multiple linear regression (MLR). Although SVM and RF show strong capabilities at estimating surface NO2 concentrations, their accuracy is inferior to that of the Deep‐CNN model, ranking second and third in model accuracy in this study. The MLR, however, shows a poor ability at NO2 estimation and ranks last among all models. Testing the impact of sample size on model performance, we also show that, compared to other models, Deep‐CNN needs more samples to trigger its strength at surface NO2 estimation. Plain Language Summary: While relatively low in concentrations, nitrogen dioxide (NO2) is an air pollutant that has severe health and environmental impacts. Although air quality ground stations can accurately measure NO2 concentrations, they have low spatial coverage owing to land accessibility, budget limitations, and other factors. Accurately estimating surface NO2 concentrations requires new approaches that address these spatial coverage limitations. Recent advances in satellite instruments have enabled the monitoring of various atmospheric constituents such as NO2 over entire regions. As a result, instead of using conventional means of estimating surface pollutants such as model simulations or statistical methods, scientists have developed deep learning (DL) algorithms to improve the accuracy of estimates. For the first time, this study leverages the deep convolutional neural network (Deep‐CNN) and the TROPOspheric Monitoring Instrument (TROPOMI), together with other environmental predictor variables, to produce accurate estimates of surface NO2 concentrations over Texas in 2019. One problem with DL models is the difficultly of interpreting their behavior concerning the data set. In response, we use a novel approach, the shapley additive explanations, to explain how the Deep‐CNN model understands the data set. We also compare the performance of our Deep‐CNN model with other well‐known models in the field. Moreover, we test the impact of sample size on performance of various models to better analyze capability of Deep‐CNN and other commonly‐used models for surface NO2 estimation. Key Points: Deep‐CNN is highly capable of estimating surface NO2 concentrations (CV‐R: 0.91)The shapley additive explanations approach shows that the deep convolutional neural network has an advanced understanding of the data setTROPOMI, a new accurate satellite instrument, plays an essential role in ground‐level NO2 estimation [ABSTRACT FROM AUTHOR]

Published
2021
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37. Efficient PM2.5 forecasting using geographical correlation based on integrated deep learning algorithms.

Author

Yeo, Inchoon, Choi, Yunsoo, Lops, Yannic, and Sayeed, Alqamah

Subjects
DEEP learning, MACHINE learning, AIR quality indexes, AUTOMATIC meteorological stations, CONVOLUTIONAL neural networks, RECURRENT neural networks, PEARSON correlation (Statistics), POLYGONS
Abstract

This paper proposes a deep learning model that integrates a convolutional neural network and a gated recurrent unit with groups of neighboring stations to accurately predict PM2.5 concentrations at 25 stations in Seoul, South Korea. The deep learning model uses observations obtained from one Korea Meteorological Administration (KMA) station, 25 National Institute of Environmental Research (NIER) stations, and 28 automatic weather stations (AWSs) throughout Seoul. To train the deep learning model, we use all available meteorological and air quality data observed between 2015 and 2017. With the trained model, we predict PM2.5 concentrations at all 25 NIER stations in Seoul for 2018. This study also proposes a geographical polygon group model that determines the optimal number of neighboring NIER stations required to increase the accuracy of PM2.5 concentration predictions at the target station. Comparing the model measures for each of the 25 monitoring sites in 2018, we find that the geographical polygon group model achieves an index of agreement of 0.82–0.89 and a Pearson correlation coefficient of 0.70–0.83. Compared to the method using only meteorological and air quality data from one target station (average IOA = 0.77) to predict PM2.5 concentrations at the 25 stations in Seoul, the proposed method using geographical correlation-based neighboring NIER stations as polygonal groups (average IOA = 0.85) improves the PM2.5 prediction accuracy by an average of about 10%. This approach, based on deep learning, can be updated to predict air pollution or air quality indices up to several days in advance. [ABSTRACT FROM AUTHOR]

Published
2021
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40. A Coupled Deep Learning Model for Estimating Surface NO2Levels From Remote Sensing Data: 15‐Year Study Over the Contiguous United States

Author

Ghahremanloo, Masoud, Lops, Yannic, Choi, Yunsoo, Mousavinezhad, Seyedali, and Jung, Jia

Abstract

This study proposes a novel two‐step deep learning (DL) model for estimating surface NO2concentrations using satellite data over the contiguous United States (CONUS) from 2005 to 2019. The first phase of the model uses partial convolutional neural network (PCNN), an advanced DL model that accurately imputes gaps between surface NO2stations and creates 5,478 daily‐mean NO2grids (PCNN‐NO2) of the 2005–2019 period over the study area. We then feed the PCNN‐NO2, along with other predictor variables, into a deep neural network (DNN) to estimate surface NO2levels, achieving exceptional performance with a correlation coefficient of 0.975–0.978, a mean absolute bias of 0.99–1.38 ppb, and a root mean square error of 1.47–1.97 ppb. Spatial cross‐validation results also indicate strong spatial performance of PCNN‐DNN surface NO2estimates. In addition to its accurate estimates, the PCNN‐DNN model consistently generates estimated NO2grids without any missing values, improving the quality of various applications such as emission reduction strategies and public health studies. Between 2005 and 2019, the 5,478 daily estimated NO2grids over the CONUS reveal significant reductions in NO2levels in 14 major urban environments: Washington D.C. (−43%), New York (−45%), Los Angeles (−38%), Chicago (−25%), Boston (−43%), Houston (−34%), Dallas (−40%), Philadelphia (−41%), Phoenix (−38%), Detroit (−20%), Denver (−23%), Atlanta (−0.7%), Cincinnati (−38%), and Pittsburgh (−56%). Furthermore, the study shows that the denser urban regions that in‐situ stations are installed in, the higher the difference between in‐situ observations and regional‐mean NO2levels. Despite the significance of NO2monitoring stations, their number and spatial coverage is limited, leaving many regions with no NO2observations. This limitation calls for the development of advanced models to fill the gaps between NO2stations and create gap‐free spatiotemporally‐consistent grids of surface NO2concentrations. Recent advances in deep learning (DL) algorithms have enabled them to fill the gaps in various images, such as those representing the human face, nature, etc. with plausible contents. This technology can also be applied to fill the gaps between surface NO2stations when the model is trained on datasets such as satellite tropospheric column density of NO2images, available in almost all regions. In this study, we introduce a novel DL model to construct daily gap‐free grids of estimated NO2levels over the contiguous United States from 2005 to 2019, obtaining exceptional performance with a correlation coefficient of 0.975–0.978. The first phase of the model uses a partial convolutional neural network, trained mainly by satellite images, to fill the gaps between surface NO2stations, and the second phase utilizes a deep neural network to bias correct the output of the first phase. A novel two‐step deep learning model is used to estimate surface NO2levels, with exceptional accuracy, over the contiguous United StatesThe partial convolutional neural network used satellite images to fill the gaps between surface NO2stationsNO2levels decreased significantly in most urban environments in the United States from 2005 to 2019 A novel two‐step deep learning model is used to estimate surface NO2levels, with exceptional accuracy, over the contiguous United States The partial convolutional neural network used satellite images to fill the gaps between surface NO2stations NO2levels decreased significantly in most urban environments in the United States from 2005 to 2019

Published
2023
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41. Deep Learning Estimation of Daily Ground‐Level NO2Concentrations From Remote Sensing Data

Author

Ghahremanloo, Masoud, Lops, Yannic, Choi, Yunsoo, and Yeganeh, Bijan

Abstract

The limited number of nitrogen dioxide (NO2) surface measurements calls for the development of highly accurate approaches to estimating surface NO2concentrations. In this study, we leverage a new satellite instrument, the TROPOspheric Monitoring Instrument (TROPOMI), along with other predictor variables, to estimate daily surface NO2concentrations over Texas in 2019. We use the deep convolutional neural network (Deep‐CNN), an advanced deep learning algorithm, to obtain estimates and achieve a correlation coefficient (R) of 0.91, an index of agreement (IOA) of 0.95, and a mean absolute bias (MAB) of 1.75 ppb in surface NO2estimation. Additionally, we leverage a novel approach, shapley additive explanations (SHAP), to describe how Deep‐CNN understands each predictor variable. The SHAP results show that the Deep‐CNN model has an advanced understanding of the data set, revealing that TROPOMI closely captures levels of NO2. In addition, we show the superiority of our Deep‐CNN model at estimating surface NO2over other well‐known machine learning and regression models in the field, including the support vector machines (SVM), random forest (RF), and multiple linear regression (MLR). Although SVM and RF show strong capabilities at estimating surface NO2concentrations, their accuracy is inferior to that of the Deep‐CNN model, ranking second and third in model accuracy in this study. The MLR, however, shows a poor ability at NO2estimation and ranks last among all models. Testing the impact of sample size on model performance, we also show that, compared to other models, Deep‐CNN needs more samples to trigger its strength at surface NO2estimation. While relatively low in concentrations, nitrogen dioxide (NO2) is an air pollutant that has severe health and environmental impacts. Although air quality ground stations can accurately measure NO2concentrations, they have low spatial coverage owing to land accessibility, budget limitations, and other factors. Accurately estimating surface NO2concentrations requires new approaches that address these spatial coverage limitations. Recent advances in satellite instruments have enabled the monitoring of various atmospheric constituents such as NO2over entire regions. As a result, instead of using conventional means of estimating surface pollutants such as model simulations or statistical methods, scientists have developed deep learning (DL) algorithms to improve the accuracy of estimates. For the first time, this study leverages the deep convolutional neural network (Deep‐CNN) and the TROPOspheric Monitoring Instrument (TROPOMI), together with other environmental predictor variables, to produce accurate estimates of surface NO2concentrations over Texas in 2019. One problem with DL models is the difficultly of interpreting their behavior concerning the data set. In response, we use a novel approach, the shapley additive explanations, to explain how the Deep‐CNN model understands the data set. We also compare the performance of our Deep‐CNN model with other well‐known models in the field. Moreover, we test the impact of sample size on performance of various models to better analyze capability of Deep‐CNN and other commonly‐used models for surface NO2estimation. Deep‐CNN is highly capable of estimating surface NO2concentrations (CV‐R: 0.91)The shapley additive explanations approach shows that the deep convolutional neural network has an advanced understanding of the data setTROPOMI, a new accurate satellite instrument, plays an essential role in ground‐level NO2estimation Deep‐CNN is highly capable of estimating surface NO2concentrations (CV‐R: 0.91) The shapley additive explanations approach shows that the deep convolutional neural network has an advanced understanding of the data set TROPOMI, a new accurate satellite instrument, plays an essential role in ground‐level NO2estimation

Published
2021
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