Your search keyword '"Khorsandi, Ehsan"' showing total 20 results

1. Global Air Pollution Data for Health Risk Assessments in Lombardy, Italy

Author

Gilardi, Lorenza, primary, Khorsandi, Ehsan, additional, and Erbertseder, Thilo, additional

Published

2023

2. Detecting Moving Trucks on Roads Using Sentinel-2 Data

Author

Fisser, Henrik, primary, Khorsandi, Ehsan, additional, Wegmann, Martin, additional, and Baier, Frank, additional

Published

2022

3. Detecting moving trucks on roads using Sentinel-2 data

Author

Fisser, Henrik, Khorsandi, Ehsan, Wegmann, Martin, and Baier, Frank

Subjects

ddc:380, machine learning, road traffic, truck detection, Sentinel-2, ddc:526

Abstract

In most countries, freight is predominantly transported by road cargo trucks. We present a new satellite remote sensing method for detecting moving trucks on roads using Sentinel-2 data. The method exploits a temporal sensing offset of the Sentinel-2 multispectral instrument, causing spatially and spectrally distorted signatures of moving objects. A random forest classifier was trained (overall accuracy: 84%) on visual-near-infrared-spectra of 2500 globally labelled targets. Based on the classification, the target objects were extracted using a developed recursive neighbourhood search. The speed and the heading of the objects were approximated. Detections were validated by employing 350 globally labelled target boxes (mean F\(_1\) score: 0.74). The lowest F\(_1\) score was achieved in Kenya (0.36), the highest in Poland (0.88). Furthermore, validated at 26 traffic count stations in Germany on in sum 390 dates, the truck detections correlate spatio-temporally with station figures (Pearson r-value: 0.82, RMSE: 43.7). Absolute counts were underestimated on 81% of the dates. The detection performance may differ by season and road condition. Hence, the method is only suitable for approximating the relative truck traffic abundance rather than providing accurate absolute counts. However, existing road cargo monitoring methods that rely on traffic count stations or very high resolution remote sensing data have limited global availability. The proposed moving truck detection method could fill this gap, particularly where other information on road cargo traffic are sparse by employing globally and freely available Sentinel-2 data. It is inferior to the accuracy and the temporal detail of station counts, but superior in terms of spatial coverage.

Published

2022

4. An improved tropospheric NO2 research product from TROPOMI over Europe

Author

Seo, Sora, Valks, Pieter, Liu, Song, Pinardi, Gaia, Xu, Jian, Chan, Ka Lok, Argyrouli, Athina, Lutz, Ronny, Beirle, Steffen, Khorsandi, Ehsan, Baier, Frank, Roozendael, M. Van, and Loyola, Diego

Subjects

Sentinel-5P, TROPOMI, NO2, retrieval

Published

2022

5. A tropospheric NO2 research product from TROPOMI for air quality applications in Europe

Author

Seo, Sora, Valks, Pieter, Liu, Song, Pinardi, Gaia, Xu, Jian, Chan, Ka Lok, Argyrouli, Athina, Lutz, Ronny, Beirle, Steffen, Khorsandi, Ehsan, Baier, Frank, Dammers, E., Roozendael, M. Van, and Loyola, Diego

Subjects

Sentitnel-5P, TROPOMI, NO2, retrieval

Published

2022

6. Evaluation of Air Pollution Trend Using GIS and RS Applications in South West of Iran

Author

Moradi Dashtpagerdi, Mostafa, Sadatinejad, Seyed Javad, Zare Bidaki, Rafat, and Khorsandi, Ehsan

Published

2014

7. An improved TROPOMI tropospheric NO2 research product over Europe

Author

Liu, Song, Valks, Pieter, Pinardi, Gaia, Xu, Jian, Chan, Ka Lok, Argyrouli, Athina, Lutz, Ronny, Beirle, Steffen, Khorsandi, Ehsan, Baier, Frank, Huijnen, Vincent, Bais, Alkiviadis, Donner, Sebastian, Dörner, Steffen, Gratsea, M., Hendrick, Francoise, Karagkiozidis, D., Lange, Kezia, Piters, Ankie, Remmers, J., Richter, A., Van Roozendael, M., Wagner, T., Wenig, M., and Loyola, Diego

Subjects

troposphere, TROPOMI, NO2, Air Quality

Abstract

Launched in October 2017, the TROPOspheric Monitoring Instrument (TROPOMI) aboard Sentinel-5 Precursor provides the potential to monitor air quality over point sources across the globe with a spatial resolution as high as 5.5 km × 3.5 km (7 km × 3.5 km before 6 August 2019). The DLR nitrogen dioxide (NO2) retrieval algorithm for the TROPOMI instrument consists of three steps: the spectral fitting of the slant column, the separation of stratospheric and tropospheric contributions, and the conversion of the slant column to a vertical column using an air mass factor (AMF) calculation. In this work, an improved DLR tropospheric NO2 retrieval algorithm from TROPOMI measurements over Europe is presented. The stratospheric estimation is implemented using the STRatospheric Estimation Algorithm from Mainz (STREAM), which was developed as a verification algorithm for TROPOMI and does not require chemistry transport model data as input. A directionally dependent STREAM (DSTREAM) is developed to correct for the dependency of the stratospheric NO2 on the viewing geometry by up to 2×1014 molec./cm2. Applied to synthetic TROPOMI data, the uncertainty in the stratospheric column is 3.5×1014 molec./cm2 in the case of significant tropospheric sources. Applied to actual measurements, the smooth variation of stratospheric NO2 at low latitudes is conserved, and stronger stratospheric variation at higher latitudes is captured. For AMF calculation, the climatological surface albedo data are replaced by geometry-dependent effective Lambertian equivalent reflectivity (GE_LER) obtained directly from TROPOMI measurements with a high spatial resolution. Mesoscale-resolution a priori NO2 profiles are obtained from the regional POLYPHEMUS/DLR chemistry transport model with the TNO-MACC emission inventory. Based on the latest TROPOMI operational cloud parameters, a more realistic cloud treatment is provided by a Clouds-As-Layers (CAL) model, which treats the clouds as uniform layers of water droplets, instead of the Clouds-As-Reflecting-Boundaries (CRB) model, in which clouds are simplified as Lambertian reflectors. For the error analysis, the tropospheric AMF uncertainty, which is the largest source of NO2 uncertainty for polluted scenarios, ranges between 20 % and 50 %, leading to a total uncertainty in the tropospheric NO2 column in the 30 %–60 % range. From a validation performed with ground-based multi-axis differential optical absorption spectroscopy (MAX-DOAS) measurements, the new DLR tropospheric NO2 data show good correlations for nine European urban/suburban stations, with an average correlation coefficient of 0.78. The implementation of the algorithm improvements leads to a decrease of the relative difference from −55.3 % to −34.7 % on average in comparison with the DLR reference retrieval. When the satellite averaging kernels are used to remove the contribution of a priori profile shape, the relative difference decreases further to ∼ −20 %.

Published

2021

8. Joint Bavarian Slovenian Endeavour for innovative air quality analysis (JOSEFINA)

Author

Bittner, Michael, Baier, Frank, Khorsandi, Ehsan, and Handschuh, Jana

Subjects

Luftschadstoffkonzentrationen, Projekt JOSEFINA, Luftqualität, Spurengase, Feinstaub

Published

2021

9. An improved TROPOMI tropospheric NO<sub>2</sub> research product over Europe

Author

Liu, Song, primary, Valks, Pieter, additional, Pinardi, Gaia, additional, Xu, Jian, additional, Chan, Ka Lok, additional, Argyrouli, Athina, additional, Lutz, Ronny, additional, Beirle, Steffen, additional, Khorsandi, Ehsan, additional, Baier, Frank, additional, Huijnen, Vincent, additional, Bais, Alkiviadis, additional, Donner, Sebastian, additional, Dörner, Steffen, additional, Gratsea, Myrto, additional, Hendrick, François, additional, Karagkiozidis, Dimitris, additional, Lange, Kezia, additional, Piters, Ankie J. M., additional, Remmers, Julia, additional, Richter, Andreas, additional, Van Roozendael, Michel, additional, Wagner, Thomas, additional, Wenig, Mark, additional, and Loyola, Diego G., additional

Published

2021

10. Comparing the aggregated health risk calculated from different Earth Observation resources

Author

Houdayer, Marion, primary, Erbertseder, Thilo, additional, Khorsandi, Ehsan, additional, Baier, Frank, additional, and Handschuh, Jana, additional

Published

2021

11. An improved tropospheric NO2 column retrieval algorithm for TROPOMI over Europe

Author

Liu, Song, Valks, Pieter, Pinardi, Gaia, Xu, Jian, Chan, Ka Lok, Argyrouli, Athina, Lutz, Ronny, Beirle, Steffen, Khorsandi, Ehsan, Baier, Frank, Huijnen, Vincent, Bais, Alkiviadis, Donner, Sebastian, Dörner, Steffen, Gratsea, Myrto, Hendrick, François, Karagkiozidis, Dimitris, Lange, Kezia, Piters, Ankie J. M., Remmers, Julia, Richter, Andreas, Roozendael, Michel, Wagner, Thomas, Wenig, Mark, and Loyola, Diego G.

Abstract

Launched in October 2017, the TROPOspheric Monitoring Instrument (TROPOMI) aboard Sentinel-5 Precursor provides the potential to monitor air quality over point sources across the globe with a spatial resolution as high as 5.5 km × 3.5 km (7 km × 3.5 km before 6 August 2019). The nitrogen dioxide (NO2) retrieval algorithm for the TROPOMI instrument consists of three steps: the spectral fitting of the slant column, the separation of stratospheric and tropospheric contributions, and the conversion of the slant column to a vertical column using an air mass factor (AMF) calculation. In this work, an improved tropospheric NO2 retrieval algorithm from TROPOMI measurements over Europe is presented. The stratospheric estimation is implemented using the STRatospheric Estimation Algorithm from Mainz (STREAM), which was developed as a verification algorithm for TROPOMI and does not require chemistry transport model data as input. A directionally dependent STREAM (DSTREAM) is developed to correct for the dependency of the stratospheric NO2 on the viewing geometry by up to 2 × 1014 molec/cm2. Applied to synthetic TROPOMI data, the uncertainty in the stratospheric column is 3.5 × 1014 molec/cm2 for polluted conditions. Applied to actual measurements, the smooth variation of stratospheric NO2 at low latitudes is conserved, and stronger stratospheric variation at higher latitudes are captured. For AMF calculation, the climatological surface albedo data is replaced by geometry-dependent effective Lambertian equivalent reflectivity (GE_LER) obtained directly from TROPOMI measurements with a high spatial resolution. Mesoscale-resolution a priori NO2 profiles are obtained from the regional POLYPHEMUS/DLR chemistry transport model with the TNO-MACC emission inventory. Based on the latest TROPOMI operational cloud parameters, a more realistic cloud treatment is provided by a clouds-as-layers (CAL) model, which treats the clouds as uniform layers of water droplets, instead of the clouds-as-reflecting-boundaries (CRB) model, in which clouds are simplified as Lambertian reflectors. For the error analysis, the tropospheric AMF uncertainty, which is the largest source of NO2 uncertainty for polluted scenarios, ranges between 20 % and 50 %, leading to a total uncertainty in the tropospheric NO2 column in the 30–60 % range. From a validation performed with ground-based multi-axis differential optical absorption spectroscopy (MAX-DOAS) measurements, the improved tropospheric NO2 data shows good correlations for nine European urban/suburban stations with an average correlation coefficient of 0.78. The implementation of the algorithm improvements leads to a decrease of the relative difference from −55.3 % to −34.7 % on average.

Published

2021

12. An improved TROPOMI tropospheric NO2 research product over Europe

Author

Liu, Song, Valks, Pieter, Pinardi, Gaia, Xu, Jian, Chan, Ka Lok, Argyrouli, Athina, Lutz, Ronny, Beirle, Steffen, Khorsandi, Ehsan, Baier, Frank, Huijnen, Vincent, Bais, Alkiviadis, Donner, Sebastian, Dörner, Steffen, Gratsea, Myrto, Hendrick, François, Karagkiozidis, Dimitris, Lange, Kezia, Piters, Ankie J. M., Remmers, Julia, Richter, Andreas, Van Roozendael, Michel, Wagner, Thomas, Wenig, Mark, and Loyola, Diego G.

Subjects

ddc

Published

2020

13. Satellite-based remote sensing of the urban atmosphere: examples from German cities

Author

Erbertseder, Thilo, Khorsandi, Ehsan, Roiger, Anke, Fiehn, Alina, and Baier, Frank

Subjects

Pollution, Urban agglomeration, biology, Meteorology, Climate Change, media_common.quotation_subject, Mesoscale meteorology, biology.organism_classification, Air Quality, Remote Sensing, Atmosphere, Polyphemus, Urban climate, Earth Observation, Environmental science, Satellite, Air quality index, Urban Climate, media_common

Abstract

The major goal of the German research project “Urban Climate Under Change” [UC]² is the development and evaluation of an innovative urban climate model that should be able to simulate atmospheric processes on spatial scales of 10 m or finer for entire cities like Berlin and Stuttgart. This will enable interdisciplinary analyzes for the planning of measures to improve the urban climate and air quality. For the evaluation of urban climate models and mesoscale chemical-transport models and the three-dimensional processes represented therein, reference measurements are usually only available in the lowest meters of the boundary layer. In addition, an evaluation of city-wide mass balances (e.g. of air pollutants) with point measurements at the surface is only possible under many assumptions, the uncertainties remain high. Satellite and aircraft-based observations are therefore an inevitable addition to the analysis of the urban climate and the evaluation of three-dimensional urban climate models and chemical-transport models, especially if they cover entire cities or agglomerations. The objective of the work presented here is the analysis of atmospheric and chemical parameters by satellite and airborne measurements in order to examine the variability of the urban atmosphere and thereby contribute to the evaluation of the urban climate model PALM-4U and the mesoscale chemical-transport model POLYPHEMUS/DLR. In addition of long-term observations, results from the new instrument Sentinel-5P/TROPOMI will be shown. The capability of the instrument to monitor urban pollution plumes and urban pollution islands is examined. Airborne in-situ measurements were carried out with the DLR Cessna during two intensive measurement campaigns (IOP) in Berlin and Stuttgart.

Published

2020

14. Estimation of Surface NO2 Concentrations over Germany from TROPOMI Satellite Observations Using a Machine Learning Method

Author

Chan, Ka Lok, primary, Khorsandi, Ehsan, additional, Liu, Song, additional, Baier, Frank, additional, and Valks, Pieter, additional

Published

2021

15. Supplementary material to "An improved tropospheric NO<sub>2</sub> column retrieval algorithm for TROPOMI over Europe"

Author

Liu, Song, primary, Valks, Pieter, additional, Pinardi, Gaia, additional, Xu, Jian, additional, Chan, Ka Lok, additional, Argyrouli, Athina, additional, Lutz, Ronny, additional, Beirle, Steffen, additional, Khorsandi, Ehsan, additional, Baier, Frank, additional, Huijnen, Vincent, additional, Bais, Alkiviadis, additional, Donner, Sebastian, additional, Dörner, Steffen, additional, Gratsea, Myrto, additional, Hendrick, François, additional, Karagkiozidis, Dimitris, additional, Lange, Kezia, additional, Piters, Ankie J. M., additional, Remmers, Julia, additional, Richter, Andreas, additional, Van Roozendael, Michel, additional, Wagner, Thomas, additional, Wenig, Mark, additional, and Loyola, Diego G., additional

Published

2021

16. An improved tropospheric NO2 column retrieval algorithm for TROPOMI over Europe

Author

Liu, Song, primary, Valks, Pieter, additional, Pinardi, Gaia, additional, Xu, Jian, additional, Chan, Ka Lok, additional, Argyrouli, Athina, additional, Lutz, Ronny, additional, Beirle, Steffen, additional, Khorsandi, Ehsan, additional, Baier, Frank, additional, Huijnen, Vincent, additional, Bais, Alkiviadis, additional, Donner, Sebastian, additional, Dörner, Steffen, additional, Gratsea, Myrto, additional, Hendrick, François, additional, Karagkiozidis, Dimitris, additional, Lange, Kezia, additional, Piters, Ankie J. M., additional, Remmers, Julia, additional, Richter, Andreas, additional, Van Roozendael, Michel, additional, Wagner, Thomas, additional, Wenig, Mark, additional, and Loyola, Diego G., additional

Published

2021

17. An improved tropospheric NO2 column retrieval algorithm for TROPOMI over Europe.

Author

Liu, Song, Valks, Pieter, Pinardi, Gaia, Xu, Jian, Chan, Ka Lok, Argyrouli, Athina, Lutz, Ronny, Beirle, Steffen, Khorsandi, Ehsan, Baier, Frank, Huijnen, Vincent, Bais, Alkiviadis, Donner, Sebastian, Dörner, Steffen, Gratsea, Myrto, Hendrick, François, Karagkiozidis, Dimitris, Lange, Kezia, Piters, Ankie J. M., and Remmers, Julia

Subjects

AIR quality monitoring, EMISSION inventories, WATER vapor, AIR masses, OPTICAL spectroscopy, NITROGEN dioxide, CHEMICAL models

Abstract

Launched in October 2017, the TROPOspheric Monitoring Instrument (TROPOMI) aboard Sentinel-5 Precursor provides the potential to monitor air quality over point sources across the globe with a spatial resolution as high as 5.5 km × 3.5 km (7 km × 3.5 km before 6 August 2019). The nitrogen dioxide (NO2) retrieval algorithm for the TROPOMI instrument consists of three steps: the spectral fitting of the slant column, the separation of stratospheric and tropospheric contributions, and the conversion of the slant column to a vertical column using an air mass factor (AMF) calculation. In this work, an improved tropospheric NO2 retrieval algorithm from TROPOMI measurements over Europe is presented. The stratospheric estimation is implemented using the STRatospheric Estimation Algorithm from Mainz (STREAM), which was developed as a verification algorithm for TROPOMI and does not require chemistry transport model data as input. A directionally dependent STREAM (DSTREAM) is developed to correct for the dependency of the stratospheric NO2 on the viewing geometry by up to 2 × 1014 molec/cm2. Applied to synthetic TROPOMI data, the uncertainty in the stratospheric column is 3.5 × 1014 molec/cm2 for polluted conditions. Applied to actual measurements, the smooth variation of stratospheric NO2 at low latitudes is conserved, and stronger stratospheric variation at higher latitudes are captured. For AMF calculation, the climatological surface albedo data is replaced by geometry-dependent effective Lambertian equivalent reflectivity (GE_LER) obtained directly from TROPOMI measurements with a high spatial resolution. Mesoscale-resolution a priori NO2 profiles are obtained from the regional POLYPHEMUS/DLR chemistry transport model with the TNO-MACC emission inventory. Based on the latest TROPOMI operational cloud parameters, a more realistic cloud treatment is provided by a clouds-as-layers (CAL) model, which treats the clouds as uniform layers of water droplets, instead of the clouds-as-reflecting-boundaries (CRB) model, in which clouds are simplified as Lambertian reflectors. For the error analysis, the tropospheric AMF uncertainty, which is the largest source of NO2 uncertainty for polluted scenarios, ranges between 20 % and 50 %, leading to a total uncertainty in the tropospheric NO2 column in the 30-60 % range. From a validation performed with ground-based multi-axis differential optical absorption spectroscopy (MAX-DOAS) measurements, the improved tropospheric NO2 data shows good correlations for nine European urban/suburban stations with an average correlation coefficient of 0.78. The implementation of the algorithm improvements leads to a decrease of the relative difference from −55.3 % to −34.7 % on average. [ABSTRACT FROM AUTHOR]

Published

2021

18. Air quality monitoring and simulation on urban scale over Munich

Author

Khorsandi, Ehsan, primary, Baier, Frank, primary, Erbertseder, Thilo, primary, and Bittner, Michael, primary

Published

2018

19. Evaluation of Air Pollution Trend Using GIS and RS Applications in South West of Iran

Author

Moradi Dashtpagerdi, Mostafa, primary, Sadatinejad, Seyed Javad, additional, Zare Bidaki, Rafat, additional, and Khorsandi, Ehsan, additional

Published

2013

20. Estimation of Surface NO 2 Concentrations over Germany from TROPOMI Satellite Observations Using a Machine Learning Method.

Author

Chan, Ka Lok, Khorsandi, Ehsan, Liu, Song, Baier, Frank, Valks, Pieter, and Serio, Carmine

Subjects

*MACHINE learning, *ARTIFICIAL neural networks, *COVID-19, *AIR quality monitoring, *PEARSON correlation (Statistics), *VIRAL transmission

Abstract

In this paper, we present the estimation of surface NO 2 concentrations over Germany using a machine learning approach. TROPOMI satellite observations of tropospheric NO 2 vertical column densities (VCDs) and several meteorological parameters are used to train the neural network model for the prediction of surface NO 2 concentrations. The neural network model is validated against ground-based in situ air quality monitoring network measurements and regional chemical transport model (CTM) simulations. Neural network estimation of surface NO 2 concentrations show good agreement with in situ monitor data with Pearson correlation coefficient (R) of 0.80. The results also show that the machine learning approach is performing better than regional CTM simulations in predicting surface NO 2 concentrations. We also performed a sensitivity analysis for each input parameter of the neural network model. The validated neural network model is then used to estimate surface NO 2 concentrations over Germany from 2018 to 2020. Estimated surface NO 2 concentrations are used to investigate the spatio-temporal characteristics, such as seasonal and weekly variations of NO 2 in Germany. The estimated surface NO 2 concentrations provide comprehensive information of NO 2 spatial distribution which is very useful for exposure estimation. We estimated the annual average NO 2 exposure for 2018, 2019 and 2020 is 15.53, 15.24 and 13.27 µ g/m 3 , respectively. While the annual average NO 2 concentration of 2018, 2019 and 2020 is only 12.79, 12.60 and 11.15 µ g/m 3 . In addition, we used the surface NO 2 data set to investigate the impacts of the coronavirus disease 2019 (COVID-19) pandemic on ambient NO 2 levels in Germany. In general, 10–30% lower surface NO 2 concentrations are observed in 2020 compared to 2018 and 2019, indicating the significant impacts of a series of restriction measures to reduce the spread of the virus. [ABSTRACT FROM AUTHOR]

Published

2021