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Vegetation index

February 16, 2023

A vegetation index (VI) is a spectral imaging transformation of two or more image bands designed to enhance the contribution of vegetation properties and allow reliable spatial and temporal inter-comparisons of terrestrial photosynthetic activity and canopy structural variations.[2]

6- monthly NDVI average for Australia, 1 Dec 2012 to 31 May 2013[1]

There are many VIs, with many being functionally equivalent. Many of the indices make use of the inverse relationship between red and near-infrared reflectance associated with healthy green vegetation. Since the 1960s scientists have used satellite remote sensing to monitor fluctuation in vegetation at the Earth's surface. Measurements of vegetation attributes include leaf area index (LAI), percent green cover, chlorophyll content, green biomass and absorbed photosynthetically active radiation (APAR).

VIs have been historically classified based on a range of attributes, including the number of spectral bands (2 or greater than 2); the method of calculations (ratio or orthogonal), depending on the required objective; or by their historical development (classified as first generation VIs or second generation VIs).[3] For the sake of comparison of the effectiveness of different VIs, Lyon, Yuan et al. (1998)[4] classified 7 VIs based on their computation methods (Subtraction, Division or Rational Transform). Due to advances in hyperspectral remote sensing technology, high-resolution reflectance spectrums are now available, which can be used with traditional multispectral VIs. In addition, VIs have been developed to be used specifically with hyperspectral data, such as the use of Narrow Band Vegetation Indices.

Uses

Vegetation indices have been used to:

Types of vegetation index

Multispectral Vegetation Index

 
NDVI through Landsat 8 applied to the urban area of Ponta Grossa, southern Brazil
  • Ratio Vegetation Index (RVI): Defined as the ratio between the Red and Near Infrared lights of multispectral images [17]
  • Normalised Difference Vegetation Index (NDVI): The most commonly used remote sensing index [18] that calculates the ratio of the difference and sum between the Near Infrared and Red bands of multispectral images. It normally takes values between -1 and +1. It is mostly used in vegetation dynamics monitoring,[19] including biomass quantification.
  • Kauth-Thomas Tasseled Cap Transformation: A spectral enhancement index that transforms the spectral information of a satellite data into spectral features [20][21][22]
  • Infrared Index
  • Perpendicular Vegetation Index
  • Greenness Above Bare Soil
  • Moisture Stress Index: A spectral index that measures the level of moisture stress in leaves [23]
  • Leaf Water Content Index (LWCI) [24]
  • MidIR Index
  • Soil-Adjusted Vegetation Index (SAVI): An adjusted form of NDVI developed to minimize the effects of soil brightness on spectral vegetation indices, particularly in areas of high soil composition [25]
  • Modified SAVI: Mostly applied in to areas with low NDVI measures.
  • Atmospherically Resistant Vegetation Index
  • Soil and Atmospherically Resistant Vegetation Index
  • Enhanced Vegetation Index (EVI): Very similar to NDVI. The only difference is that it corrects atmospheric and canopy background noise, particularly in regions with high biomass
  • New Vegetation Index
  • Aerosol Free Vegetation Index
  • Triangular Vegetation Index
  • Reduced Simple Ratio
  • Visible Atmospherically Resistant Index
  • Normalised Difference Built-Up Index
  • Weighted Difference Vegetation Index (WDVI)
  • Fraction of absorbed photosynthetically active radiation (FAPAR)
  • Normalised Difference Greenness index (NDGI)
  • Temperature Vegetation Water Stress Index (TVWSI)[26]

Hyperspectral Vegetation Index

With the advent of hyperspectral data, vegetation index have been developed specifically for hyperspectral data.

  • Discrete-Band Normalised Difference Vegetation Index
  • Yellowness Index
  • Photochemical Reflectance Index
  • Descrete-Band Normalised Difference Water Index
  • Red Edge Position Determination
  • Crop Chlorophyll Content Prediction
  • Moment distance index (MDI)

Advanced Vegetation Indices

With the emergence of machine learning, certain algorithms can be used to determine vegetation indices from data. This allows to take into account all spectral bands and to discover hidden parameters that can be useful to strengthen these vegetation indices. Thus, they can be more robust against light variations, shadows or even uncalibrated images if these artifacts exist in the training data.

  • Synthesis of Vegetation Indices Using Genetic Programming[27]
  • A soft computing approach for selecting and combining spectral bands [28]
  • DeepIndices: Remote Sensing Indices Based on Approximation of Functions through Deep-Learning[29]

References

  1. ^ Data downloaded from "Australian Bureau of Meteorology". on 13 June 2018, mapped in R 14 June 2018
  2. ^ Huete, A.; Didan, K.; Miura, T.; Rodriguez, E.P; Gao, X.; Ferreira, L.G (2002). "Overview of the radiometric and biophysical performance of the MODIS vegetation indices". Remote Sensing of Environment. 83 (1–2): 195–213. Bibcode:2002RSEnv..83..195H. doi:10.1016/S0034-4257(02)00096-2.
  3. ^ Bannari, A.; Morin, D.; Bonn, F.; Huete, A. R. (1995-08-01). "A review of vegetation indices". Remote Sensing Reviews. 13 (1–2): 95–120. doi:10.1080/02757259509532298. ISSN 0275-7257.
  4. ^ Lyon, John G (1998). "A change detection experiment using vegetation indices". Photogrammetric Engineering and Remote Sensing: 143–150. CiteSeerX 10.1.1.462.2056.
  5. ^ Eklundh, L.; Olsson, L. (2003). "Vegetation index trends for the African Sahel 1982-1999". Geophysical Research Letters. 30 (8): 1430. Bibcode:2003GeoRL..30.1430E. doi:10.1029/2002GL016772. ISSN 0094-8276. S2CID 129096989.
  6. ^ Gillies, R. R.; Kustas, W. P.; Humes, K. S. (1997). "A verification of the 'triangle' method for obtaining surface soil water content and energy fluxes from remote measurements of the Normalized Difference Vegetation Index (NDVI) and surface e". International Journal of Remote Sensing. 18 (15): 3145–3166. Bibcode:1997IJRS...18.3145G. doi:10.1080/014311697217026. ISSN 0143-1161.
  7. ^ Sandholt, Inge; Rasmussen, Kjeld; Andersen, Jens (2002). "A simple interpretation of the surface temperature/vegetation index space for assessment of surface moisture status". Remote Sensing of Environment. 79 (2–3): 213–224. Bibcode:2002RSEnv..79..213S. doi:10.1016/S0034-4257(01)00274-7. ISSN 0034-4257.
  8. ^ Peters, A.J.; Walter-Shea, E.A.; Ji, L.; Vliia, A.; Hayes, M.; Svoboda, M.D. (2002). "Drought Monitoring with NDVI-Based Standardized Vegetation Index" (PDF). Photogrammetric Engineering & Remote Sensing. 68 (1): 71–75. Retrieved 16 May 2018.
  9. ^ Kogan, F.N. (1995). "Application of vegetation index and brightness temperature for drought detection". Advances in Space Research. 15 (11): 91–100. Bibcode:1995AdSpR..15k..91K. doi:10.1016/0273-1177(95)00079-T. ISSN 0273-1177.
  10. ^ Wan, Z.; Wang, P.; Li, X. (2004). "Using MODIS Land Surface Temperature and Normalized Difference Vegetation Index products for monitoring drought in the southern Great Plains, USA". International Journal of Remote Sensing. 25 (1): 61–72. Bibcode:2004IJRS...25...61W. doi:10.1080/0143116031000115328. ISSN 0143-1161. S2CID 129234540.
  11. ^ Jones, H. G. (2004). "Irrigation scheduling: advantages and pitfalls of plant-based methods". Journal of Experimental Botany. 55 (407): 2427–2436. doi:10.1093/jxb/erh213. ISSN 1460-2431. PMID 15286143.
  12. ^ Pinter, Jr., Paul J.; Hatfield, Jerry L.; Schepers, James S.; Barnes, Edward M.; Moran, M. Susan; Daughtry, Craig S.T.; Upchurch, Dan R. (2003). "Remote Sensing for Crop Management". Photogrammetric Engineering & Remote Sensing. 69 (6): 647–664. doi:10.14358/PERS.69.6.647. ISSN 0099-1112.
  13. ^ Kustas, W. P.; Norman, J. M. (2009). "Use of remote sensing for evapotranspiration monitoring over land surfaces". Hydrological Sciences Journal. 41 (4): 495–516. doi:10.1080/02626669609491522. ISSN 0262-6667.
  14. ^ Pettorelli, Nathalie; Ryan, Sadie; Mueller, Thomas; Bunnefeld, Nils; Jędrzejewska, Bogumiła; Lima, Mauricio; Kausrud, Kyrre (2011). "The Normalized Difference Vegetation Index (NDVI): unforeseen successes in animal ecology" (PDF). Climate Research. 46 (1): 15–27. Bibcode:2011ClRes..46...15P. doi:10.3354/cr00936. ISSN 0936-577X. JSTOR 24872307.
  15. ^ Lloyd, Daniel (1990). "A phenological classification of terrestrial vegetation cover using shortwave vegetation index imagery". International Journal of Remote Sensing. 11 (12): 2269–2279. Bibcode:1990IJRS...11.2269L. doi:10.1080/01431169008955174. ISSN 0143-1161.
  16. ^ Mahlein, A. K.; Rumpf, T.; Welke, P.; Dehne, H.W.; Plümer, L.; Steiner, U.; Oerke, E.C. (January 2013). "Development of spectral indices for detecting and identifying plant diseases". Remote Sensing of Environment. 128: 21–30. doi:10.1016/j.rse.2012.09.019.
  17. ^ Jordan, Carl F. (July 1969). "Derivation of Leaf-Area Index from Quality of Light on the Forest Floor". Ecology. 50 (4): 663–666. doi:10.2307/1936256. ISSN 0012-9658. JSTOR 1936256.
  18. ^ Bhandari, A.K.; Kumar, A.; Singh, G.K. (2012). "Feature Extraction using Normalized Difference Vegetation Index (NDVI): A Case Study of Jabalpur City". Procedia Technology. 6: 612–621. doi:10.1016/j.protcy.2012.10.074. ISSN 2212-0173.
  19. ^ Vrieling, Anton; de Leeuw, Jan; Said, Mohammed (2013-02-22). "Length of Growing Period over Africa: Variability and Trends from 30 Years of NDVI Time Series". Remote Sensing. 5 (2): 982–1000. Bibcode:2013RemS....5..982V. doi:10.3390/rs5020982. ISSN 2072-4292.
  20. ^ Siwe, Rene Ngamabou; Koch, Barbara (2008-01-12). "Change vector analysis to categorise land cover change processes using the tasselled cap as biophysical indicator". Environmental Monitoring and Assessment. 145 (1–3): 227–235. doi:10.1007/s10661-007-0031-6. ISSN 0167-6369. PMID 18193332. S2CID 189913689.
  21. ^ Yousuf, Reem; AL-Khakani, Ebtihal (2021). "Assessing Degree of Desertification Using Tasselled Cap Transformation and Spectral Indicators Techniques: Iraq". Basic and Applied Sciences - Scientific Journal of King Faisal University. doi:10.37575/b/sci/0019. ISSN 1658-0311.
  22. ^ Kauth R. J. & G. S. Thomas (1976): The tasseled Cap - A Graphic Description of the Spectral-Temporal Development of Agricultural Crops as Seen by LANDSAT. Proceedings of the Symposium on Machine Processing of Remotely Sensed Data
  23. ^ Rock, B. N.; Vogelmann, J. E.; Williams, D. L.; Vogelmann, A. F.; Hoshizaki, T. (July 1986). "Remote Detection of Forest Damage". BioScience. 36 (7): 439–445. doi:10.2307/1310339. ISSN 1525-3244. JSTOR 1310339.
  24. ^ LWCI entry in the Index Database, https://www.indexdatabase.de/db/i-single.php?id=129
  25. ^ Huete, A.R (August 1988). "A soil-adjusted vegetation index (SAVI)". Remote Sensing of Environment. 25 (3): 295–309. Bibcode:1988RSEnv..25..295H. doi:10.1016/0034-4257(88)90106-X.
  26. ^ Joshi, R.C.; Ryu, D.; Sheridan, G.J.; Lane, P.N.J. (2021). "Modeling Vegetation Water Stress over the Forest from Space: Temperature Vegetation Water Stress Index (TVWSI)". Remote Sens. 13 (22:4635): 4635. doi:10.3390/rs13224635.
  27. ^ Puente, Cesar; Olague, Gustavo; Trabucchi, Mattia; Arjona-Villicaña, P. David; Soubervielle-Montalvo, Carlos (January 2019). "Synthesis of Vegetation Indices Using Genetic Programming for Soil Erosion Estimation". Remote Sensing. 11 (2): 156. doi:10.3390/rs11020156. ISSN 2072-4292.
  28. ^ Albarracín, Juan F. H.; Oliveira, Rafael S.; Hirota, Marina; dos Santos, Jefersson A.; Torres, Ricardo da S. (January 2020). "A Soft Computing Approach for Selecting and Combining Spectral Bands". Remote Sensing. 12 (14): 2267. doi:10.3390/rs12142267. ISSN 2072-4292.
  29. ^ Vayssade, Jehan-Antoine; Paoli, Jean-Noël; Gée, Christelle; Jones, Gawain (January 2021). "DeepIndices: Remote Sensing Indices Based on Approximation of Functions through Deep-Learning, Application to Uncalibrated Vegetation Images". Remote Sensing. 13 (12): 2261. doi:10.3390/rs13122261. ISSN 2072-4292.

February 16, 2023
vegetation, index, vegetation, index, spectral, imaging, transformation, more, image, bands, designed, enhance, contribution, vegetation, properties, allow, reliable, spatial, temporal, inter, comparisons, terrestrial, photosynthetic, activity, canopy, structu. A vegetation index VI is a spectral imaging transformation of two or more image bands designed to enhance the contribution of vegetation properties and allow reliable spatial and temporal inter comparisons of terrestrial photosynthetic activity and canopy structural variations 2 6 monthly NDVI average for Australia 1 Dec 2012 to 31 May 2013 1 There are many VIs with many being functionally equivalent Many of the indices make use of the inverse relationship between red and near infrared reflectance associated with healthy green vegetation Since the 1960s scientists have used satellite remote sensing to monitor fluctuation in vegetation at the Earth s surface Measurements of vegetation attributes include leaf area index LAI percent green cover chlorophyll content green biomass and absorbed photosynthetically active radiation APAR VIs have been historically classified based on a range of attributes including the number of spectral bands 2 or greater than 2 the method of calculations ratio or orthogonal depending on the required objective or by their historical development classified as first generation VIs or second generation VIs 3 For the sake of comparison of the effectiveness of different VIs Lyon Yuan et al 1998 4 classified 7 VIs based on their computation methods Subtraction Division or Rational Transform Due to advances in hyperspectral remote sensing technology high resolution reflectance spectrums are now available which can be used with traditional multispectral VIs In addition VIs have been developed to be used specifically with hyperspectral data such as the use of Narrow Band Vegetation Indices Contents 1 Uses 2 Types of vegetation index 2 1 Multispectral Vegetation Index 2 2 Hyperspectral Vegetation Index 2 3 Advanced Vegetation Indices 3 ReferencesUses EditVegetation indices have been used to examine climate trends 5 estimate water content of soils remotely 6 7 monitor drought 8 9 10 schedule crop irrigation 11 crop management 12 monitor evaporation and plant transpiration 13 assess changes in biodiversity 14 classify vegetation 15 detection and quantification of crop diseases 16 Types of vegetation index EditMultispectral Vegetation Index Edit NDVI through Landsat 8 applied to the urban area of Ponta Grossa southern Brazil Ratio Vegetation Index RVI Defined as the ratio between the Red and Near Infrared lights of multispectral images 17 Normalised Difference Vegetation Index NDVI The most commonly used remote sensing index 18 that calculates the ratio of the difference and sum between the Near Infrared and Red bands of multispectral images It normally takes values between 1 and 1 It is mostly used in vegetation dynamics monitoring 19 including biomass quantification Kauth Thomas Tasseled Cap Transformation A spectral enhancement index that transforms the spectral information of a satellite data into spectral features 20 21 22 Infrared Index Perpendicular Vegetation Index Greenness Above Bare Soil Moisture Stress Index A spectral index that measures the level of moisture stress in leaves 23 Leaf Water Content Index LWCI 24 MidIR Index Soil Adjusted Vegetation Index SAVI An adjusted form of NDVI developed to minimize the effects of soil brightness on spectral vegetation indices particularly in areas of high soil composition 25 Modified SAVI Mostly applied in to areas with low NDVI measures Atmospherically Resistant Vegetation Index Soil and Atmospherically Resistant Vegetation Index Enhanced Vegetation Index EVI Very similar to NDVI The only difference is that it corrects atmospheric and canopy background noise particularly in regions with high biomass New Vegetation Index Aerosol Free Vegetation Index Triangular Vegetation Index Reduced Simple Ratio Visible Atmospherically Resistant Index Normalised Difference Built Up Index Weighted Difference Vegetation Index WDVI Fraction of absorbed photosynthetically active radiation FAPAR Normalised Difference Greenness index NDGI Temperature Vegetation Water Stress Index TVWSI 26 Hyperspectral Vegetation Index Edit With the advent of hyperspectral data vegetation index have been developed specifically for hyperspectral data Discrete Band Normalised Difference Vegetation Index Yellowness Index Photochemical Reflectance Index Descrete Band Normalised Difference Water Index Red Edge Position Determination Crop Chlorophyll Content Prediction Moment distance index MDI Advanced Vegetation Indices Edit With the emergence of machine learning certain algorithms can be used to determine vegetation indices from data This allows to take into account all spectral bands and to discover hidden parameters that can be useful to strengthen these vegetation indices Thus they can be more robust against light variations shadows or even uncalibrated images if these artifacts exist in the training data Synthesis of Vegetation Indices Using Genetic Programming 27 A soft computing approach for selecting and combining spectral bands 28 DeepIndices Remote Sensing Indices Based on Approximation of Functions through Deep Learning 29 References Edit Data downloaded from Australian Bureau of Meteorology on 13 June 2018 mapped in R 14 June 2018 Huete A Didan K Miura T Rodriguez E P Gao X Ferreira L G 2002 Overview of the radiometric and biophysical performance of the MODIS vegetation indices Remote Sensing of Environment 83 1 2 195 213 Bibcode 2002RSEnv 83 195H doi 10 1016 S0034 4257 02 00096 2 Bannari A Morin D Bonn F Huete A R 1995 08 01 A review of vegetation indices Remote Sensing Reviews 13 1 2 95 120 doi 10 1080 02757259509532298 ISSN 0275 7257 Lyon John G 1998 A change detection experiment using vegetation indices Photogrammetric Engineering and Remote Sensing 143 150 CiteSeerX 10 1 1 462 2056 Eklundh L Olsson L 2003 Vegetation index trends for the African Sahel 1982 1999 Geophysical Research Letters 30 8 1430 Bibcode 2003GeoRL 30 1430E doi 10 1029 2002GL016772 ISSN 0094 8276 S2CID 129096989 Gillies R R Kustas W P Humes K S 1997 A verification of the triangle method for obtaining surface soil water content and energy fluxes from remote measurements of the Normalized Difference Vegetation Index NDVI and surface e International Journal of Remote Sensing 18 15 3145 3166 Bibcode 1997IJRS 18 3145G doi 10 1080 014311697217026 ISSN 0143 1161 Sandholt Inge Rasmussen Kjeld Andersen Jens 2002 A simple interpretation of the surface temperature vegetation index space for assessment of surface moisture status Remote Sensing of Environment 79 2 3 213 224 Bibcode 2002RSEnv 79 213S doi 10 1016 S0034 4257 01 00274 7 ISSN 0034 4257 Peters A J Walter Shea E A Ji L Vliia A Hayes M Svoboda M D 2002 Drought Monitoring with NDVI Based Standardized Vegetation Index PDF Photogrammetric Engineering amp Remote Sensing 68 1 71 75 Retrieved 16 May 2018 Kogan F N 1995 Application of vegetation index and brightness temperature for drought detection Advances in Space Research 15 11 91 100 Bibcode 1995AdSpR 15k 91K doi 10 1016 0273 1177 95 00079 T ISSN 0273 1177 Wan Z Wang P Li X 2004 Using MODIS Land Surface Temperature and Normalized Difference Vegetation Index products for monitoring drought in the southern Great Plains USA International Journal of Remote Sensing 25 1 61 72 Bibcode 2004IJRS 25 61W doi 10 1080 0143116031000115328 ISSN 0143 1161 S2CID 129234540 Jones H G 2004 Irrigation scheduling advantages and pitfalls of plant based methods Journal of Experimental Botany 55 407 2427 2436 doi 10 1093 jxb erh213 ISSN 1460 2431 PMID 15286143 Pinter Jr Paul J Hatfield Jerry L Schepers James S Barnes Edward M Moran M Susan Daughtry Craig S T Upchurch Dan R 2003 Remote Sensing for Crop Management Photogrammetric Engineering amp Remote Sensing 69 6 647 664 doi 10 14358 PERS 69 6 647 ISSN 0099 1112 Kustas W P Norman J M 2009 Use of remote sensing for evapotranspiration monitoring over land surfaces Hydrological Sciences Journal 41 4 495 516 doi 10 1080 02626669609491522 ISSN 0262 6667 Pettorelli Nathalie Ryan Sadie Mueller Thomas Bunnefeld Nils Jedrzejewska Bogumila Lima Mauricio Kausrud Kyrre 2011 The Normalized Difference Vegetation Index NDVI unforeseen successes in animal ecology PDF Climate Research 46 1 15 27 Bibcode 2011ClRes 46 15P doi 10 3354 cr00936 ISSN 0936 577X JSTOR 24872307 Lloyd Daniel 1990 A phenological classification of terrestrial vegetation cover using shortwave vegetation index imagery International Journal of Remote Sensing 11 12 2269 2279 Bibcode 1990IJRS 11 2269L doi 10 1080 01431169008955174 ISSN 0143 1161 Mahlein A K Rumpf T Welke P Dehne H W Plumer L Steiner U Oerke E C January 2013 Development of spectral indices for detecting and identifying plant diseases Remote Sensing of Environment 128 21 30 doi 10 1016 j rse 2012 09 019 Jordan Carl F July 1969 Derivation of Leaf Area Index from Quality of Light on the Forest Floor Ecology 50 4 663 666 doi 10 2307 1936256 ISSN 0012 9658 JSTOR 1936256 Bhandari A K Kumar A Singh G K 2012 Feature Extraction using Normalized Difference Vegetation Index NDVI A Case Study of Jabalpur City Procedia Technology 6 612 621 doi 10 1016 j protcy 2012 10 074 ISSN 2212 0173 Vrieling Anton de Leeuw Jan Said Mohammed 2013 02 22 Length of Growing Period over Africa Variability and Trends from 30 Years of NDVI Time Series Remote Sensing 5 2 982 1000 Bibcode 2013RemS 5 982V doi 10 3390 rs5020982 ISSN 2072 4292 Siwe Rene Ngamabou Koch Barbara 2008 01 12 Change vector analysis to categorise land cover change processes using the tasselled cap as biophysical indicator Environmental Monitoring and Assessment 145 1 3 227 235 doi 10 1007 s10661 007 0031 6 ISSN 0167 6369 PMID 18193332 S2CID 189913689 Yousuf Reem AL Khakani Ebtihal 2021 Assessing Degree of Desertification Using Tasselled Cap Transformation and Spectral Indicators Techniques Iraq Basic and Applied Sciences Scientific Journal of King Faisal University doi 10 37575 b sci 0019 ISSN 1658 0311 Kauth R J amp G S Thomas 1976 The tasseled Cap A Graphic Description of the Spectral Temporal Development of Agricultural Crops as Seen by LANDSAT Proceedings of the Symposium on Machine Processing of Remotely Sensed Data Rock B N Vogelmann J E Williams D L Vogelmann A F Hoshizaki T July 1986 Remote Detection of Forest Damage BioScience 36 7 439 445 doi 10 2307 1310339 ISSN 1525 3244 JSTOR 1310339 LWCI entry in the Index Database https www indexdatabase de db i single php id 129 Huete A R August 1988 A soil adjusted vegetation index SAVI Remote Sensing of Environment 25 3 295 309 Bibcode 1988RSEnv 25 295H doi 10 1016 0034 4257 88 90106 X Joshi R C Ryu D Sheridan G J Lane P N J 2021 Modeling Vegetation Water Stress over the Forest from Space Temperature Vegetation Water Stress Index TVWSI Remote Sens 13 22 4635 4635 doi 10 3390 rs13224635 Puente Cesar Olague Gustavo Trabucchi Mattia Arjona Villicana P David Soubervielle Montalvo Carlos January 2019 Synthesis of Vegetation Indices Using Genetic Programming for Soil Erosion Estimation Remote Sensing 11 2 156 doi 10 3390 rs11020156 ISSN 2072 4292 Albarracin Juan F H Oliveira Rafael S Hirota Marina dos Santos Jefersson A Torres Ricardo da S January 2020 A Soft Computing Approach for Selecting and Combining Spectral Bands Remote Sensing 12 14 2267 doi 10 3390 rs12142267 ISSN 2072 4292 Vayssade Jehan Antoine Paoli Jean Noel Gee Christelle Jones Gawain January 2021 DeepIndices Remote Sensing Indices Based on Approximation of Functions through Deep Learning Application to Uncalibrated Vegetation Images Remote Sensing 13 12 2261 doi 10 3390 rs13122261 ISSN 2072 4292 Retrieved from https en wikipedia org w index php title Vegetation index amp oldid 1138660571, wikipedia, wiki, book, books, library,

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