Performance evaluation of remote sensing data with machine learning technique to determine soil color

Laleh Parviz

Abstract


The aim of the present research is the determination of soil color by spectral bands and indices obtained from MODIS images. For this purpose, soil samples were collected from East Azerbaijan Province (Iran) and their color and texture were investigated through Munsell color system and hydrometer method, respectively. Stepwise regression, principle component analysis and sensitivity function methods were employed to find the dominant indices and bands using artificial neural network (ANN) as one of the machine learning techniques. The improved indices as the model input had better performance, for example, the calculation of correlation coefficient between indices and hue showed 51.48% increase of correlation coefficient with comparison of the normalized difference vegetation index (NDVI) to modified soil adjustment vegetation index (MSAVI) and 54.54% correlation enhancement of soil adjustment vegetation index (SAVI) compared to MSAVI. Stepwise regression method along with error criteria decline may enhance the performance of soil color model. In comparison with multivariate regression, ANN model exhibited better performance (with a 12.61% mean absolute error [MAE] decline). Temporal variation of modified perpendicular drought index (MPDI) as well as band 31 could justify the Munsell soil color components variations specifically chroma and hue. MPDI and thermal bands could be employed as a precise indicator in soil color analysis. Thus, remote sensing data combined with machine learning technique can clarify the procedure potential for soil color determination.


Keywords


soil color, Munsell chart, stepwise regression, ANN, MPDI

Full Text:

PDF

References


Abdi, H., Williams, L.J., 2010. Principal component analysis. WIREs: Computational Statistics, 2: 433–459.

Agapiou, A., Hadjimitsis, D.G., Alexakis, D.D., 2012. Evaluation of broadband and narrowband vegetation indices for the identification of archaeological crop marks. Remote Sensing, 4(12): 3892–3919.

Akhtar, M.K., Corzo, G.A., Van Ande, S.J., Jonoski, A., 2009. River flow forecasting with artificial neural networks using satellite observed precipitation pre-processed with flow length and travel time information: case study of the Ganges river basin. Hydrology and Earth System Sciences, 13: 1607–1618.

Baret, F., Guyot, G., 1991. Potentials and limits of vegetation indices for LAI and APAR assessment. Remote Sensing of Environment, 35(2-3): 161–173.

Bijaber, N., El Hadani, D., Saidi, M., Svoboda, M.D., Wardlow, B.D., Hain, C.R., Christian, P., Yessef, M., Rochdi, A., 2018. Developing a Remotely Sensed Drought Monitoring Indicator for Morocco. Geosciences, 8(5): 1–18.

Du, L., Tian, Q., Yu, T., Meng, Q., Jancso, T., Udvardy, P., Huanga, Y., 2013. A comprehensive drought monitoring method integrating MODIS and TRMM data. International Journal of Applied Earth Observation and Geoinformation, 23: 245–253.

Escadafal, R., Girard, M.C., Courault, D., 1989. Munsell soil color and soil reflectance in the visible spectral bands of landsat MSS and TM data. Remote Sensing of Environment, 27(1): 37–46.

Ghulam, A., Qin, Q., Teyip, T., Li, Z.L., 2007. Modified perpendicular drought index (MPDI): a real-time drought monitoring method. ISPRS Journal of Photogrammetry and Remote Sensing, 62: 150–164.

Gilabert, M.A., Gonza´lez-Piqueras, J., Garcı´a-Haro, F.J., Melia, J., 2002. A generalized soil-adjusted vegetation index. Remote Sensing of Environment, 82: 303–310.

Gunal, H., Ersahin, S., Yetgin, B., Kutlu, T., 2008. Use of chromameter‐measured color parameters in estimating color‐related soil variables. Communications in Soil Science and Plant Analysis, 39: 726–740.

Han, P., Dong, D., Zhao, X., Jiao, L., Lang, Y., 2016. A smartphone-based soil color sensor: for soil type classification. Computers and Electronics in Agriculture, 123: 232–241.

Henry, D.F., 1991. Fundamentals of soil science, 8th ed. Wiley Publication, pp.354. https://www.wiley.com/en-us/9780471522799.

Huesca, M., Litago, J., Merino-de-Miguel, S., Cicuendez-López-Ocaña, V., Palacios-Orueta, A., 2014. Modeling and forecasting MODIS-based Fire Potential Index on a pixel basis using time series models. International Journal of Applied Earth Observation and Geoinformation, 26: 363–376.

Huete, A.R., 1988. A soil-adjusted vegetation index (SAVI). Remote Sensing of Environment, 25: 295–309.

Hurst, V.J., 1977. Visual estimation of iron in saprolite. Geological Society of America Bulletin, 88: 174–176.

Ibáñez-Asensio, S., Marqués-Mateu, A., Moreno-Ramón, H., Balasch, S., 2013. Statistical relationships between soil colour and soil attributes in semiarid areas. Biosystems Engineering, 116(2): 120–129.

Ji, L., Peters, A.J., 2007. Performance evaluation of spectral vegetation indices using a statistical sensitivity function. Remote Sensing of Environment, 106: 59–65.

Jiang, Z.H., Huete, A.R., Li, J., Qi, J., 2007. Interpretation of the modified soil- adjusted vegetation index isolines in red-NIR reflectance space. Journal of Applied Remote Sensing, 1: 1–12.

Khanal, S., Fulton, J., Klopfenstein, A., Douridas, N., Shearer, S., 2018. Integration of high resolution remotely sensed data and machine learning techniques for spatial prediction of soil properties and corn yield. Computers and Electronic in Agriculture, 153: 213–225.

Kone, B., Yao-Kouame, A., Ettien, J.B., Oikeh, S., Yoro, G., Diatta, S., 2009. Modelling the relationship between soil color and particle size for soil survey in Ferralsol environments. Soil & Environment, 28(2): 93–105.

Leone, A.P., Escadafal, R., 2001. Statistical analysis of soil colour and spectroradiometric data for hyperspectral remote sensing of soil properties (example in a southern Italy Mediterranean ecosystem). International Journal of Remote Sensing, 22(12): 2311–2328.

Levin, N., Ben-Dor, E., Singer, A., 2005. A digital camera as a tool to measure colour indices and related properties of sandy soils in semi-arid environments. International Journal of Remote Sensing, 26(24): 5475–5492.

Mahsafar, H., Maknoon, R., Saghafian, B., 2017. The impact of climate change on water level of Urmia Lake. Research in Marine Sciences, 2(2): 83–94.

Marashi, M., Mohammadi Torkashvand, A., Ahmadi, A., Esfandyari, M., 2017. Estimation of soil aggregate stability indices using artificial neural network and multiple linear regression models. Spanish Journal of Soil Science, 7(2): 122–132.

Marqués-Mateu, A., Moreno-Ramón, H., Balasch, S., Ibáñez-Asensio, S., 2018. Quantifying the uncertainty of soil colour measurements with Munsell charts using a modified attribute agreement analysis. Catena, 171: 44–53.

Matinfar, H.R., Alavi Panah, S.K., Rafiei Emam, A., 2010. Remotely sensed data evaluation on soil spectral properties in arid regions. Iranian Journal of Range and Desert Research, 16(4): 560–573.

Mohamed, E.S., Saleh, A.M., Belal, A.B., Gad, A.A., 2018. Application of near-infrared reflectance for quantitative assessment of soil properties. The Egyptian Journal of Remote Sensing and Space Sciences, 21(1): 1–14.

Moustris Kostas, P., Larissi Ioanna, K., Nastos Panagiotis, T., Paliatsos Athanasios, G., 2011. Precipitation forecast using artificial neural networks in specific regions of Greece. Water Resources Management, 25: 1979–1993.

Ozgür, K., 2005. Daily river flow forecasting using artificial neural networks and auto-regressive models. Turkish Journal of Engineering and Environmental Science, 29: 9–20.

Park, J., Baik, J., Choi, M., 2017. Satellite-based crop coefficient and evapotranspiration using surface soil moisture and vegetation indices in Northeast Asia. Catena, 156: 305–314.

Peng, Y., Zhang, Y.J., Liu, D.T., Liu, L.S., 2018. Degradation estimation using feature increment stepwise linear regression for PMW inverter of electro-mehanical actuator. Microelectronics Reliability, 88-90: 514–518.

Price, J.C., 1984. Land surface temperature measurements from the split window channel of the NOAA 7 advanced very high resolution radiometer. Journal of Geophysical Research, 89: 7231–7237.

Raghavendra, B.R., Mohammad Aslam, M.A., 2017. Sensitivity of vegetation indices of MODIS data for the monitoring of rice crops in Raichur district, Karnataka, India. The Egyptian Journal of Remote Sensing and Space Sciences, 20: 187–195.

Rymuza, K., Turska, E., Wielogórska, G., Bombik, A., 2012. Use of principal component analysis for the assessment of spring wheat characteristics. Acta Scientiarum Polonorum seria Agricultura, 11(1): 79–90.

Shabani, A., Norouzi, M., 2015. Predicting cation exchange capacity by artificial neural network and multiple linear regression using terrain and soil characteristics. Indian Journal of Science and Technology, 8(28): 1–10.

Shahabfar, A., Ghulam, A., Eitzinger, J., 2012. Drought monitoring in Iran using the perpendicular drought indices. International Journal of Applied Earth Observation and Geoinformation, 18: 119–127.

Sharma, M.J., Jin, Y.S., 2015. Stepwise regression data envelopment analysis for variable reduction. Applied Mathematics and Computation, 253: 126–134.

Singh, D., Herlin, I., Berroir, J.P., Silva, E.F., Simoes Meirelles, M., 2004. An approach to correlate NDVI with soil colour for erosion process using NOAA/AVHRR data. Advances in Space Research, 33: 328–332.

Stiglitz, R., Mikhailova, E., Post, C., Schlautman, M., Sharp, J., 2016. Evaluation of an inexpensive sensor to measure soil color. Computers and Electronics in Agriculture, 121: 141–148.

Stiglitz, R., Mikhailova, E., Post, C., Schlautman, M., Sharp, J., Pargas, R., Glover, B., Mooney, J., 2017. Soil color sensor data collection using a GPS-enabled Smartphone application. Geoderma, 296: 108–114.

Thompson, J., Pollio, A., Turk, P., 2013. Comparison of Munsell soil color charts and the GLOBE soil color book. Soil Science Society of America Journal, 77: 2089–2093.

Wang, Y., Woodcock, C.E., Buermann, W., Stenberg, P., Voipio, P., Smolander, H., Häme, T., Tian, Y., Hu, J., Knyazikhin, Y., Myneni, R.B., 2004. Evaluation of the MODIS LAI Algorithm at a Coniferous Forest Site in Finland. Remote Sensing of Environment, 91: 114–127.

Wuttichaikitcharoen, P., Babel, M.S., 2014. Principal component and multiple regression analyses for the estimation of suspended sediment yield in ungauged basins of northern Thailand. Water, 6: 2412–2435.

Yang, X., Guo, X., 2014. Quantifying responses of spectral vegetation indices to dead materials in mixed grassland. Remote Sensing, 2: 4289–4304.




DOI: http://dx.doi.org/10.17951/pjss.2020.53.1.97
Date of publication: 2020-06-22 04:38:05
Date of submission: 2019-02-27 17:34:09


Statistics


Total abstract view - 1199
Downloads (from 2020-06-17) - PDF - 1072

Indicators



Refbacks

  • There are currently no refbacks.


Copyright (c) 2020 Laleh Parviz

Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.