بهبود دقت مکانی تصاویر حرارتی با تکنیک SFIM و T-Sharp-Dis-Trade جهت بررسی تغییرات دمای سطح زمین

زارعی, سجاد; کابلی زاده, مصطفی; نوارباف, فاطمه

doi:10.22034/jargs.2024.437508.1088

بهبود دقت مکانی تصاویر حرارتی با تکنیک SFIM و T-Sharp-Dis-Trade جهت بررسی تغییرات دمای سطح زمین

نوع مقاله : مقاله پژوهشی

نویسندگان

سجاد زارعی ¹

مصطفی کابلی زاده ²

فاطمه نوارباف ³

¹ گروه سنجش از دو ر و GIS، دانشکده علوم زمین، دانشگاه شهید چمران اهواز، اهواز، ایران

² گروه سنجش از دور وGIS، دانشکده علوم زمین، دانشگاه شهید چمران اهواز، اهواز، ایران

³ گروه سنجش از دور و GIS، دانشکده علوم زمین، دانشگاه شهید چمران اهواز، اهواز، ایران

10.22034/jargs.2024.437508.1088

چکیده

هدف: بررسی رابطه بین دمای سطح زمین و کاربری‌های شهری می‌تواند در مدیریت شهری مورد استفاده قرار بگیرد؛ اما یکی از مشکلات پیش رو، قدرت تفکیک مکانی پایین تصاویر حرارتی است. هدف این پژوهش، بررسی و انتخاب بهترین الگوریتم‌ موجود با هدف دستیابی به توان تفکیک مکانی بالای تصاویر حرارتی برای بررسی و تحلیل تغییرات دمای سطح زمین در منطقه ۴ اهواز و کشف بهترین الگوریتم در این زمینه است.
روش و داده: به همین منظور الگوریتم Split Window به عنوان یکی از متداول‌ترین الگوریتم‌های مناسب تعیین دما و الگوریتم T Sharp Dis Trade و SFIM در مناطق شهری به منظور بهبود قدرت تفکیک مکانی استفاده شده است.
یافته‌ها: نتایج نشان می‌دهد که توان تفکیک مکانی تصویر خروجی حاصل از الگوریتم Split Window ، T Sharp Dis Trade و SFIM، به ترتیب برابر با ۳۰، ۱۰۰ و ۴۵ متر است. الگوریتم T Sharp Dis Trade توان تفکیک بسیار مناسبی برای تصویر خروجی نشان داد به گونه‌ای که بر اساس آن تفکیک کاربری‌های مختلف متناسب با دمای آن‌ها میسر شد. الگوریتم‌های Split Window و SFIM نتایج قابل قبولی در بررسی کاربری‌ها ارائه ندادند. همچنین میانگین دمای به دست آمده از الگوریتم T Sharp Dis Trade، Split Window و SFIM به ترتیب برابر با ۱۷/۵، ۲۳/۵ و ۲۸/۲۵ درجه سانتی‌گراد است. این تفاوت دمایی الگوریتم‌ها به دلیل اعمال فرآیند تلفیق است.
نتیجه‌گیری: در نتیجه الگوریتم T Sharp Dis Trade در زمینه بهبود دقت مکانی تصاویر حرارتی موثرتر عمل کرد.
نوآوری، کاربرد نتایج: نوآوری‌های پژوهش حاضر عبارتند از: استفاده همزمان سه الگوریتم ذکر شده با هدف افزایش توان تفکیک مکانی تصاویر حرارتی و کشف بهترین الگوریتم در این زمینه، که در تحقیقات قبلی تاکنون انجام نشده است، بهبود توان تفکیک مکانی تصاویر حرارتی برای ارزیابی کاربری‌های شهری با استفاده از الگوریتم T Sharp Dis Trade و بررسی دقیق تغییرات دمای سطح زمین است.

کلیدواژه‌ها

بهبود قدرت تفکیک مکانی

تصاویر حرارتی

اهواز

روش T Sharp Dis Trade

موضوعات

سنجش از دور- GIS

عنوان مقاله English

Improving the Spatial Resolution of Thermal Images by using SFIM and T-Sharp-Dis-Trade Techniques to Investigate Land Surface Temperature

نویسندگان English

Sajad Zareie ¹

Mostafa Kabolizadeh ²

Fatemeh Navarbaf ³

¹ Department of Remote Sensing and GIS, Earth Sciences faculty, Shahid Chamran University of Ahvaz, Ahvaz, Iran

² Department of Remote Sensing and GIS, Earth Sciences faculty, Shahid Chamran University of Ahvaz, Iran

³ Department of Remote Sensing and GIS, Earth Sciences faculty, Shahid Chamran University of Ahvaz, Ahvaz, Iran

چکیده English

Aim: Investigating the relationship between land surface temperature and urban land uses can be used for urban management. However, one of the main problems in this field is the low spatial resolution of thermal images. This research aims to evaluate and select the best existing algorithm for achieving a high spatial resolution of thermal images to investigate and analyze changes in land surface temperature in Region 4 of Ahvaz.
Material & method: For this purpose, the split window algorithm was used as one of the most common suitable algorithms to calculate land surface temperature, and SFIM and T sharp DisTrade algorithms in urban areas were applied to improve spatial resolution.
Finding: Results show that the spatial resolution of the output image obtained by Split Window, T Sharp DisTrade, and SFIM algorithms is 30, 100, and 45 meters, respectively. The T Sharp DisTrade algorithm presented the output images with very good resolution so that different land uses could be separated according to their surface temperature. Split Window and SFIM algorithms did not provide acceptable results in land use evaluation. Also, the average land surface temperature values obtained from T Sharp DisTrade, Split Window algorithm, and SFIM are equal to 17.5, 23.5, and 28.25 degrees Celsius, respectively. This temperature difference of these algorithms is due to utilizing the fusion process.
Conclusion: As a result, T Sharp DisTrade algorithm was more effective in improving the spatial resolution of thermal images.
Innovation: Innovations of this research are: - simultaneous use of three mentioned algorithms for increasing spatial resolution of thermal images and discovering the best algorithm in this field, which has not been investigated in previous research, - improving spatial resolution of thermal images for evaluating urban land uses by using T Sharp DisTrade algorithm, and detail investigation of surface temperature changes.

کلیدواژه‌ها English

Improving spatial resolution

Thermal images

Ahvaz

T Sharp Dis Trade method

Extended Abstract

1- Introduction

Thermal satellite images have low spatial resolution compared to optical images, which are not suitable for evaluating urban land use. Therefore, it is necessary to increase the spatial resolution of these images. Agam et al. (2007) and Hardie and Eismann (2004) used the T Sharp Dis Trade algorithm and vegetation indices to estimate thermal bands with appropriate spatial resolution. Nuo et al. (2021) prepared 30 30-meter land surface temperature map by reducing the image scale using the Random Forest algorithm. The general goal of this research is to investigate the efficiency of three T Sharp Dis Trade, Split Window, and SFIM algorithms point by point in horizontal profiles drawn in Region 4 of Ahvaz and to select the best existing algorithm to achieve a high spatial resolution of thermal images for evaluation of land surface temperature changes.

2- Materials and methods

In this research, a Landsat 8 image dated August 28, 2021, was used. Meteorological data were used to assess the results accurately. T Sharp Dis Trade, Split Window, and smoothing filter-based intensity modulation (SFIM) algorithms were used. SFIM uses a ratio between panchromatic and low-pass filter images to modulate low-resolution multispectral images. A split window algorithm was used to calculate land surface temperature from the thermal data of the TIRS sensor. T Sharp Dis Trade was calculated to improve the spatial resolution of thermal images using vegetation indices. Then, in the T Sharp Dis Trade chart, the output of the profiles obtained from SFIM and Split Window methods was evaluated. Finally, in order to find a relationship between land use and surface temperature, field visits were used to assess the accuracy of temperature differences of these three methods.

3- Discussion and results

After obtaining brightness temperature and NDVI, 30 and 100-meter versions were fused, and a 30-meter image was produced. By fusion of two input images of NDVI and LST, an image with a spatial resolution of 45 meters was extracted in order to improve spatial resolution using the SFIM method. After performing these steps, outputs of SFIM with a spatial resolution of 45 meters, split window algorithm with a spatial resolution of 100 meters, and T Sharp Dis Trade method with a spatial resolution of 30 meters were obtained. Also, land surface temperature was obtained by implementing these three algorithms. In the next step, places with high temperatures were evaluated. The output profiles of SFIM and Split Window methods were analyzed based on visual observation in the T Sharp Dis Trade chart. In this research, profile number 14, due to the diversity of its uses, including vegetation cover, commercial and industrial use, residential use, the highway, grass field, and horse racing track, have been selected as samples from 30 available profiles for analysis and evaluation. In points 1, 3, 4, 5, 10, 12, 13, and 14 of this profile, T Sharp Dis Trade was more efficient, but in points 2 and 6, T Sharp Dis Trade and SFIM were more efficient. In points 7, 8, 9, 11, and 15, T Sharp Dis Trade and Split Window were more effective.

4- Conclusion

High-quality results with high spatial resolution were obtained, using which the boundary of thermal changes can be seen. Two algorithms, SFIM, and Split Window, have shown an increase in surface temperature in sports land use, but the T Sharp Dis Trade algorithm has been the most effective. In commercial and industrial land uses, T Sharp Dis Trade and SFIM have been the most efficient, and Split Window has shown a decreasing trend for surface temperature. SFIM and Split Window results have shown increasing surface temperature trends in mixed land use of green spaces, and T Sharp Dis Trade was more efficient. SFIM and Split Window showed the highest surface temperature in scattered vegetation, but T Sharp Dis Trade was more effective. T Sharp Dis Trade was the most efficient way to deal with dense vegetation. On horse track, the SFIM method showed the best performance. All three algorithms have had good results in highway and heavy traffic land uses. In general, SFIM in residential areas had a very poor match between surface temperature and this land use, and T Sharp Dis Trade and Split Window were the most efficient. SFIM and Split Windows have provided inappropriate results for investigating heat islands and measuring surface temperature. T Sharp Dis Trade has provided very acceptable results for surface temperature.

Aknowledgmant & Funding

The authors thank the Khuzestan Meteorological Bureau and the US Geological Survey for providing the required data. The manuscript did not receive a grant from any organization.

Conflict of Interest

Ethical principles have been fully followed in manuscript preparation. The authors declare no conflict of interest.

اکبری، داود؛ و مینا مرادی‌زاده (1396). بهبود قدرت تفکیک مکانی باند‌های حرارتی با استفاده از شاخص‌های پوشش گیاهی و سطوح غیرقابل نفوذ. سنجش از دور و GIS ایران، 9(3)، 33-44.

بیگی، شهاب الدین. (1392). بهبود قدرت تفکیک مکانی تصاویر حرارتی سنجنده مادیس جهت تهیه نقشه رطوبت خاک، پایان نامه کارشناسی ارشد، دانشکده علوم انسانی، دانشگاه تربیت مدرس.

تقی خانی، محمدحسین؛ سیما، سمیه؛ رییسی دهکردی، ایمان و کریمی، نعمت الله. (1401). تولید نقشه‌های دمای سطح زمین با قدرت تفکیک مکانی بالا از داده‌های ماهواره Sentinel-2، (مطالعه موردی: اصفهان). 53(12) . 2775-2791.

عزیزی، قاسم، ۱۳۸۳، تغییر اقلیم، انتشارات قومس، چاپ اول، تهران، 284.

علوی پناه، سید کاظم. (1397). سنجش از دور حرارتی و کاربرد آن در علوم زمین، انتشارات دانشگاه تهران، چاپ چهارم.

فرهنج، فریناز و آخوندزاده، مهدی. (1396). بهبود توان تفکیک مکانی باندهای حرارتی در تصاویر چند طیفی با استفاده از روش کانتورلت. نشریه علمی علوم و فنون نقشه برداری، 7(1)، 185-202.

Agam, N., Kustas, W. P., Anderson, M. C., Li, F., & Neale, C. M. (2007). A vegetation index based technique for spatial sharpening of thermal imagery. Remote Sensing of Environment, 107(4), 545-558. https://doi.org/10.1016/j.rse.2006.10.006

Han, L., Shi, L., Yang, Y., & Song, D. (2014). Thermal physical property-based fusion of geostationary meteorological satellite visible and infrared channel images. Sensors, 14(6), 10187-10202. https://doi.org/10.3390/s140610187

Hardie, R. C., Eismann, M. T., & Wilson, G. L. (2004). MAP estimation for hyperspectral image resolution enhancement using an auxiliary sensor. IEEE Transactions on Image Processing, 13(9), 1174-1184. DOI: 10.1109/TIP.2004.829779

Hengkai, Li., Jianying, Zhang., Yuqing, Wang., Xiaoyong, Fan., Duan. Huang. (2024). Comparison of multi-factor spatial downscaling models for high-resolution LST estimation in mountainous and hilly open-pit mines, Infrared Physics & Technology. 136, 105085. https://doi.org/10.1016/j.infrared.2023.105085.

Lestiana, H. (2018). Spatial resolution enhancement of satellite image data using fusion approach. In IOP Conference Series: Earth and Environmental Science (Vol. 118, No. 1, p. 012047). IOP Publishing.‏ DOI 10.1088/1755-1315/118/1/012047

Liao, W., Huang, X., Van Coillie, F., Gautama, S., Pižurica, A., Philips, W., ... & Tuia, D. (2015). Processing of multiresolution thermal hyperspectral and digital color data: Outcome of the 2014 IEEE GRSS data fusion contest. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 8(6), 2984-2996.‏ DOI: 10.1109/JSTARS.2015.2420582

Liu, D., & Zhu, X. (2012). An enhanced physical method for downscaling thermal infrared radiance. IEEE Geoscience and Remote Sensing Letters, 9(4), 690-694.‏ DOI: 10.1109/LGRS.2011.2178814

Marques Junior, A., De Souza, E. M., Müller, M., Brum, D., Zanotta, D. C., Horota, R. K. & Cazarin, C. L. (2020). Improving Spatial Resolution of Multispectral Rock Outcrop Images Using RGB Data and Artificial Neural Networks. Sensors, 20(12), 3559. https://doi.org/10.3390/s20123559

Namratha, H. N., & Raghu, M. T. (2013). Remote Sensing Satellite Image Fusion Using Fast Curvelet Transforms. International Journal of Science and Research (IJSR) ISSN (Online), 2319-7064. https://www.ijsr.net/archive/v4i4/SUB153344.pdf

Nuo, Xu., Fan, Deng., Bingqi, Liu., Caixia, Li., Hancong, Fu., Huan, Yang., Jiahua, Zhang. (2021). Changes in the Urban Surface Thermal Environment of a Chinese Coastal City Revealed by Downscaling MODIS LST with Random Forest Algorithm. Journal of Meteorological Research. 35, 759–774. https://doi.org/10.1007/s13351-021-0023-4

Pohl, C., and Van Genderen, J., 2016, Remote sensing image: A practical guide, Crc press.

Ruchi, Bala., Rajendra, Prasad. & Vijay Pratap. Yadav. (2020). Thermal sharpening of MODIS land surface temperature using statistical downscaling technique in urban areas. Theor Appl Climatol, 141, 935–946. https://doi.org/10.1007/s00704-020-03253-w.

Saleem, A., Awange, J. L., & Corner, R. (2021). Exploiting a texture framework and high spatial resolution properties of panchromatic images to generate enhanced multi layer products: Examples of Pleiades and historical CORONA space photographs. International Journal of Remote Sensing, 42(3), 929-963.‏ https://doi.org/10.1080/01431161.2020.1820617

Sandip, Mukherjee., P.K. Joshi., & R.D. Garg. (2017). Downscaling of Coarse Resolution Satellite Remote Sensing Thermal Data. In: Hazra, S., Mukhopadhyay, A., Ghosh, A., Mitra, D., Dadhwal, V. (eds) Environment and Earth Observation. Springer Remote Sensing/Photogrammetry. Springer, Cham. https://doi.org/10.1007/978-3-319-46010-9_3

Shao-gang, LEI., Zheng-fu, BIAN., John, L. DANIELS., Dong-lie, LIU. (2014). Improved spatial resolution in soil moisture retrieval at arid mining area using apparent thermal inertia. Transactions of Nonferrous Metals Society of China, 24, 6. https://doi.org/10.1016/S1003-6326(14)63265-9.

Shi, Z., Chen, C., Xiong, Z., Liu, D., Zha, Z. J. & Wu, F. (2018). Deep residual attention network for spectral image super-resolution. In Proceedings of the European Conference on Computer Vision (ECCV) Workshops (pp. 0-0).‏ https://openaccess.thecvf.com/content_ECCVW_2018/papers/11133/Shi_Deep_Residual_Attention_Network_for_Spectral_Image_Super-Resolution_ECCVW_2018_paper.pdf

Skokovic, D., Sobrino, J. A., Jiménez Muñoz, J. C., Soria, G., Julien, Y., Mattar, C., & Cristóbal, J. (2014). Calibration and Validation of land surface temperature for Landsat8-TIRS sensor TIRS LANDSAT-8 CHARACTERISTICS. L Prod Valid Evol ESA/ESRIN, 27. https://earth.esa.int/eogateway/documents/20142/37627/ESA_Lpve_Sobrino_2014a.pdf/e8538039-27e4-8764-bfbb-6cb76dca97fb

Solmaz, Fathololoumi., Mohammad, Karimi., Firozjaei Asim, Biswas. (2022). Improving spatial resolution of satellite soil water index (SWI) maps under clear-sky conditions using a machine learning approach. Journal of Hydrology, 615, A, 128709. https://doi.org/10.1016/j.jhydrol.2022.128709.

Taleghani, M. (2018). Outdoor thermal comfort by different heat mitigation strategies-A review. Renewable and Sustainable Energy Reviews, 81, 2011-2018. https://doi.org/10.1016/j.rser.2017.06.010

Yuan, Q., Shen, H., Li, T., Li, Z., Li, S., Jiang, Y. & Zhang, L. (2020). Deep learning in environmental remote sensing: Achievements and challenges. Remote Sensing of Environment, 241, 111716.‏ DOI:10.1016/j.rse.2020.111716

Zareie, S., Rangzan, K., Khosravi, H. et al. Comparison of split window algorithms to derive land surface temperature from satellite TIRS data. Arab J Geosci 11, 391 (2018). https://doi.org/10.1007/s12517-018-3732-y