Spatial variability of coffee plant water consumption based on the SEBAL algorithm

Costa, Jéfferson de Oliveira; Coelho, Rubens Duarte; Wolff, Wagner; José, Jefferson Vieira; Folegatti, Marcos Vinicius; Ferraz, Silvio Frosini de Barros

doi:10.1590/1678-992X-2017-0158

ABSTRACT:

Awareness of evapotranspiration (ET) and crop coefficient (K_c) is necessary for irrigation management in coffee crops. ET and K_c spatial variabilities are disregarded in traditional methods. Methods based on radiometric measurements have potential to obtain these spatialized variables. The K_c curve and spatial variability of actual evapotranspiration (ET_a) were determined using images from Landsat 8 satellite. We used images of young and adult coffee plantations from OLI (Operational Land Imager) and TIRS (Thermal Infrared Sensor) sensors over a two-year period. Evapotranspiration was estimated using the Surface Energy Balance Algorithm for Land (SEBAL). Moreover, the reference evapotranspiration (ET_o) was estimated through the Penman-Monteith method. We obtained the values for the evapotranspiration fraction (ET_f), analogous to K_c, according to ET and ET_o values. The study was conducted in Buritis, Minas Gerais State, Brazil, in areas cropped with Coffea arabica irrigated by central pivots. A comparative analysis was made using different statistical indices. Average ET_a was 2.17 mm d⁻¹ for young coffee plantations, , and the K_c mean value was 0.6. For adult coffee plantations, average ET_a was 3.95 mm d⁻¹, , and the K mean value was 0.85. The ET and K data obtained based on the SEBAL algorithm displayed similar values to studies that used traditional methods. This model has huge potential to estimate ET of different stages of coffee plantation for the region studied.

Keywords:
evapotranspiration; crop coefficient; satellite

Introduction

Crop evapotranspiration (ET_c) in non-deficit cultivation areas is determined by the crop coefficient (K_c) level, which correlates ET_c and the referential evapotranspiration (ET_o). However, evapotranspiration (ET) is a complex function of soil properties, atmospheric conditions, soil use, vegetation and topography, and is influenced by these parameters in space and time (Navarro et al., 2016Navarro, A.; Rolim, J.; Miguel, I.; Catalao, J.; Painho, M.; Vekerdy, Z. 2016. Crop monitoring based on SPOT-5 Take-5 and Sentinel-1A data for the estimation of crop water requirements. Remote Sensing 8: 525-544.).

In the field, ET_c can be measured along a homogeneous surface, using conventional techniques such as the Bowen ratio, Eddy covariance, soil water balance and lysimetric procedure. However, in situ measurements are limited in generating area estimates in terms of cost and accuracy, because of natural heterogeneity (Allen et al., 2011Allen, R.G.; Pereira, L.S.; Howell, T.A.; Jensen, M. E. 2011. Evapotranspiration information reporting. I. Factors governing measurement accuracy. Agricultural Water Management 98: 899-920.; Kiptala et al., 2013Kiptala, J.K.; Mohamed, Y.; Mul, M.L.; Zaag, P. 2013. Mapping evapotranspiration trends using MODIS and SEBAL model in a data scarce and heterogeneous landscape in Eastern Africa. Water Resources Research 49: 8495-8510.). Thus, estimating or measuring the variable on a regional scale is difficult.

With the advent of satellites for Earth observation (Navarro et al., 2016Navarro, A.; Rolim, J.; Miguel, I.; Catalao, J.; Painho, M.; Vekerdy, Z. 2016. Crop monitoring based on SPOT-5 Take-5 and Sentinel-1A data for the estimation of crop water requirements. Remote Sensing 8: 525-544.), numerous ET-based remote sensing algorithms have been developed and validated (Paul et al., 2013Paul, G.; Gowda, P.H.; Prasad, P.V.; Howell, T.A.; Staggenborg, S.A.; Neale, C.M. 2013. Lysimetric evaluation of SEBAL using high resolution airborne imagery from BEAREX 08. Advances in Water Resources 59: 157-168.). One of these methods is the SEBAL (Surface Energy Balance Algorithm for Land) (Bastiaanssen et al., 1998aBastiaanssen, W.G.; Menenti, M.; Feddes, R.A.; Holtslag, A.A.M. 1998a. A remote sensing surface energy balance algorithm for land (SEBAL). 1. Formulation. Journal of Hydrology 212: 198-212., bBastiaanssen, W.G.; Pelgrum, H.; Wang, J.; Ma, Y.; Moreno, J. F.; Roerink, G. J.; Van der Wal, T. 1998b. A remote sensing surface energy balance algorithm for land (SEBAL). Part 2. Validation. Journal of Hydrology 212: 213-229.), developed in the 1990s. The main advantage of remote sensing is that ET can be calculated on a large scale, on a pixel-to-pixels basis, in a consistent set of equations (Teixeira et al., 2009Teixeira, A.D.C.; Bastiaanssen, W.G.M.; Ahmad, M.U.D.; Bos, M. G. 2009. Reviewing SEBAL input parameters for assessing evapotranspiration and water productivity for the Low-Middle Sao Francisco river basin, Brazil. Part A. Calibration and validation. Agricultural and Forest Meteorology 149: 462-476.).

This method has demonstrated great potential in estimating ET of several crops in large areas and in different regions worldwide, using limited meteorological data (Bala et al., 2016Bala, A.; Rawat, K.S.; Misra, A.K.; Srivastava, A. 2016. Assessment and validation of evapotranspiration using SEBAL algorithm and Lysimeter data of IARI agricultural farm, India. Geocarto International 31: 739-764.; Bastiaanssen et al., 2005Bastiaanssen, W.G.M.; Noordman, E.J.M.; Pelgrum, H.; Davids, G.; Thoreson, B.P.; Allen, R.G. 2005. SEBAL model with remotely sensed data to improve water-resources management under actual field conditions. Journal of Irrigation and Drainage Engineering 131: 85-93.; Kiptala et al., 2013Kiptala, J.K.; Mohamed, Y.; Mul, M.L.; Zaag, P. 2013. Mapping evapotranspiration trends using MODIS and SEBAL model in a data scarce and heterogeneous landscape in Eastern Africa. Water Resources Research 49: 8495-8510.; Li et al., 2008Li, H.; Zheng, L.; Lei, Y.; Li, C.; Liu, Z.; Zhang, S. 2008. Estimation of water consumption and crop water productivity of winter wheat in North China Plain using remote sensing technology. Agricultural Water Management 95: 1271-1278.; Mkhwanazi et al., 2015Mkhwanazi, M.; Chávez, J.L.; Andales, A.A. 2015. SEBAL-A: a remote sensing ET algorithm that accounts for advection with limited data. Part I. Development and validation. Remote Sensing 7: 15046-15067.; Paul et al., 2013Paul, G.; Gowda, P.H.; Prasad, P.V.; Howell, T.A.; Staggenborg, S.A.; Neale, C.M. 2013. Lysimetric evaluation of SEBAL using high resolution airborne imagery from BEAREX 08. Advances in Water Resources 59: 157-168.; Rawat et al., 2017Rawat, K.S.; Bala, A.; Singh, S.K.; Pal, R.K. 2017. Quantification of wheat crop evapotranspiration and mapping: a case study from Bhiwani District of Haryana, India. Agricultural Water Management 187: 200-209.; Ruhoff et al., 2012Ruhoff, A.L.; Paz, A.R.; Collischonn, W.; Aragao, L.E.; Rocha, H.R.; Malhi, Y.S. 2012. A MODIS-based energy balance to estimate evapotranspiration for clear-sky days in Brazilian tropical savannas. Remote Sensing 4: 703-725.; Sari et al., 2013Sari, D.K.; Ismullah, I.H.; Sulasdi, W.N.; Harto, A.B. 2013. Estimation of water consumption of lowland rice in tropical area based on heterogeneous cropping calendar using remote sensing technology. Procedia Environmental Sciences 17: 298-307.; Teixeira et al., 2009Teixeira, A.D.C.; Bastiaanssen, W.G.M.; Ahmad, M.U.D.; Bos, M. G. 2009. Reviewing SEBAL input parameters for assessing evapotranspiration and water productivity for the Low-Middle Sao Francisco river basin, Brazil. Part A. Calibration and validation. Agricultural and Forest Meteorology 149: 462-476.).

Some studies on ET were conducted in coffee growing areas (Flumignan et al., 2011Flumignan, D.L.; Faria, R.T.; Prete, C.E.C. 2011. Evapotranspiration components and dual crop coefficients of coffee trees during crop production. Agricultural Water Management 98: 791-800.; Marin et al., 2005Marin, F.R.; Angelocci, L.R.; Righi, E.Z.; Sentelhas, P.C. 2005. Evapotranspiration and irrigation requirements of a coffee plantation in southern Brazil. Experimental Agriculture 41: 187-197.); however, estimation of water consumption using SEBAL algorithm in coffee cultivation should be better studied, since remote sensing can improve irrigation management considering the spatial variability of cultivated areas.

This study aimed to estimate spatial distribution of ET_c and K_c curve of coffee plantation, using Landsat 8 sensor and SEBAL algorithm. It also aimed validate spatial estimates of ET_c using FAO guidelines and other reference studies for K_c of coffee plantations in Brazil.

Materials and Methods

Location and characterization of the study site

The study was carried out in coffee crops from the northwestern regions of the state of Minas Gerais (MG), Brazil (Brazilian Cerrado). The farms are located in the municipality of Buritis and neighboring municipalities (15°48'S lat., 46°30’W long. and elevation of 600 m), totaling approximately two thousand irrigated hectares of Coffea arabica (Figure 1). The irrigation systems used in the area are central pivot-type, equipped with LEPA (Low Energy Precise Application) emitters.

Figure 1
Location of the study site, with image obtained by the Operational Land Imager (OLI) sensor - Landsat 8 on 28 July 2015. Note the central pivots in the young and adult coffee crops and the weather station.

The local weather is type Aw (Alvares et al., 2013Alvares, C.A.; Stape, J.L.; Sentelhas, P.C.; Gonçalves, J.L.M.; Sparovek, G. 2013. Köppen's climate classification map for Brazil. Meteorologische Zeitschrift 22: 711-728.), tropical with dry season in the winter. The average annual temperature is 24.3 °C and the average annual rainfall is 1,815 mm. The terrain is flat and the predominant soils were classified as Oxisol (Typic Ustox).

Satellite imaging

Images of young and adult coffee crops, from OLI (Operational Land Imager) and TIRS (Thermal Infrared Sensor), from the Landsat 8 satellite, were used during a two-year period (2014-2015) (Table 1). Regarding selection, images without clouds were prioritized and regularly distributed throughout the study period for a better evaluation of the variables (evapotranspiration and crop coefficient) according to the different phenological stages of coffee plants. An image of the ASTER GEDEM V2 satellite was also applied, referring to the digital terrain model (DTM).

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Table 1
Satellite transits date referring to Operational Land Imager (OLI)-Thermal Infrared Sensor (TIRS) imagery used in the study.

Landsat 8 satellite images were re-routed into the Universal Transverse Mercator (UTM) coordinate system, Zone 23 South and Datum Sirgas 2000, using the EPSG 31983 code. In addition, the images were converted from digital numbers to reflectance values at the top of the atmosphere. These data preprocessing procedures were performed in the geographic information systems (GIS) Gdal (Geospatial Data Abstraction Library, version 2.0) and QGIS (QGIS Development Team, version 2.8.3), the latter using the GRASS GIS program (GRASS Development Team, version 7.0) plugin, which enables the interaction between both GISs.

Evapotranspiration estimation (SEBAL algorithm)

Following image preprocessing, ET_a was estimated by the SEBAL algorithm (Bastiaanssen et al., 1998aBastiaanssen, W.G.; Menenti, M.; Feddes, R.A.; Holtslag, A.A.M. 1998a. A remote sensing surface energy balance algorithm for land (SEBAL). 1. Formulation. Journal of Hydrology 212: 198-212.). To estimate ET at different temporal and spatial scales, SEBAL algorithm uses the residual approaches of surface energy balance. The net energy from the sun and atmosphere in the form of short and long-wave radiation is transformed and used for: (i) heating the soil (soil heat flux into the ground); (ii) heating the surface environment (sensible heat flux to the atmosphere), and; (iii) transforming water into vapor (latent heat flux from the crop/soil surfaces). All the energy involved in the soil-plant-atmosphere system can be given as the energy balance equation:

(1)

R_{n} = G + H + λ E T

where: R_n is the net radiation, (W m⁻²); G is the soil hear flux, (W m⁻²); H is the sensible hear flux, (W m⁻²), and; λ ET is the latent head flux, (W m⁻²). Therefore, adjusting the energy balance equation and considering the λ ET as the “residual” energy, the ET is estimated as:

(2)

λ E T = R_{n} - G - H

The latent heat is expressed as hourly ET (mm) by dividing LE by the latent heat of vaporization and water density, multiplying by 3600 s h⁻¹.

Net radiation (R_n) represents the balance between input and output flux radiation, expressed as:

(3)

R_{n} = R_{S} ↓ - α R_{S} ↓ + R_{L} ↓ - R_{L} ↑ - (1 - εO) R_{L} ↓

where: R_S↓ is incoming shortwave radiation, (W m⁻²); α is surface albedo, (decimal); R_L↓ is incoming longwave radiation, (W m⁻²); ε0 is broadband surface thermal emissivity, (decimal), and; R_L↑ is outgoing longwave radiation, (W m⁻²). The term αR_s↓ corresponds to fraction of incoming longwave radiation reflected from the surface.

Net shortwave radiation available on Earth surface depends on R_s↓ and α, which was calculated from spectral radiance for each infrared and visible band, following the mathematical expressions for spectral integration and atmospheric correction given by Silva et al. (2016)Silva, B.B.; Braga, A.C.; Braga, C.C.; Oliveira, L.M.M.D.; Montenegro, S.M.G.L.; Barbosa Junior, B. 2016. Procedures for calculation of the albedo with OLI-Landsat 8 images: application to the Brazilian semi-arid. Revista Brasileira de Engenharia Agrícola e Ambiental 20: 3-8.. R_S↓ was estimated from the theoretical radiation on top of atmosphere (R_TOA) and from atmosphere transmissivity (τ_SW), both expressions are found in Allen et al. (1998)Allen, R.G.; Pereira, L.S.; Raes, D.; Smith, M. 1998. Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements. FAO, Rome, Italy. (Irrigation and Drainage Paper, 56)..

R_L↑ was computed according to the Stefan-Boltzman equation (Boltzmann, 1884Boltzmann, L. 1884. Derivation of Stefan's law, concerning the dependence of thermal radiation on temperature from the electromagnetic theory of light = Ableitung des Stefan'schen Gesetzes, betreffend die Abhängigkeit der Wärmestrahlung von der Temperatur aus der electromagnetischen Lichttheorie. Annalen der Physik 258: 291-294 (in German).), which expresses a theoretical quantity of radiation emitted by the surface with the surface temperature on the fourth power. After the atmospheric correction and using the thermal band 10, the surface temperature (T_s) was assigned by Weng et al. (2004)Weng, Q.; Lu, D.; Schubring, J. 2004. Estimation of land surface temperature vegetation abundance relation-ship for urban heat island studies. Remote Sensing of Environment 89: 467-483.. In turn, ε0 was estimated through the Soil-Adjusted Vegetation Index (SAVI) and Leaf Area Index (LAI) according to Allen et al. (2007)Allen, R.G.; Tasumi, M.; Trezza, R. 2007. Satellite-based energy balance for mapping evapotranspiration with internalized calibration (METRIC)-model. Journal of Irrigation and Drainage Engineering 133: 380-394..

As noted for R_L↑, R_L↓ is estimated by the Stefan-Boltzman equation Boltzmann (1884)Boltzmann, L. 1884. Derivation of Stefan's law, concerning the dependence of thermal radiation on temperature from the electromagnetic theory of light = Ableitung des Stefan'schen Gesetzes, betreffend die Abhängigkeit der Wärmestrahlung von der Temperatur aus der electromagnetischen Lichttheorie. Annalen der Physik 258: 291-294 (in German)., which is related to the empirical emissivity of the atmosphere (ε_A) and the fourth power of air temperature, as demonstrated by boundary conditions given by Allen et al. (2007)Allen, R.G.; Tasumi, M.; Trezza, R. 2007. Satellite-based energy balance for mapping evapotranspiration with internalized calibration (METRIC)-model. Journal of Irrigation and Drainage Engineering 133: 380-394..

R_n was obtained after the incoming and outgoing radiation fluxes of soil-plant-atmosphere system were calculated. Soil heat flux (G) was calculated through the ratio G/R_n adopted by Bastiaanssen (2000)Bastiaanssen, W. 2000. SEBAL-based sensible and latent heat fluxes in the irrigated Gediz Basin, Turkey. Journal of Hydrology 229: 87-100. and Allen et al. (2007)Allen, R.G.; Tasumi, M.; Trezza, R. 2007. Satellite-based energy balance for mapping evapotranspiration with internalized calibration (METRIC)-model. Journal of Irrigation and Drainage Engineering 133: 380-394., expressed as:

(4)

\frac{G}{R_{n}} = \frac{(T_{S} - 273.15)}{α} 0.0038 α + 0.0074 α^{2}) (1 - 0.98 N D V I^{4})

where: T_s is surface temperature, (K); NDVI is Normalized Difference Vegetation Index, (dimensionless). For water surfaces, where the NDVI value is negative, the ratio G/R_n is defined as 0.5.

Sensible heat flux (H) is estimated from the near surface temperature gradient given by the aerodynamic equation:

(5)

H = ρ c_{p} (\frac{α + b T_{S}}{r_{a h}})

where: ρ is the air density, (kg m⁻³); c_p is the specific heat of air at constant pressure, (≈ 1004 J kg⁻¹ K⁻¹); r_ah is the aerodynamic resistance to head transfer, (s m⁻¹), and; a and b are empirical coefficients determined through an internal calibration for each satellite image.

The term (a + bT_S) is an equation represented by the near surface temperature gradient and air temperature, for heights 0.1 m and 2 m above surface. Determining rah requires iterative calculus for stability correction of atmosphere using the Monin-Obukhov length (L) (Bastiaanssen, 2000Bastiaanssen, W. 2000. SEBAL-based sensible and latent heat fluxes in the irrigated Gediz Basin, Turkey. Journal of Hydrology 229: 87-100.; Koloskov et al., 2007Koloskov, G.; Mukhamejanov, K.; Tanton, T. 2007. Monin-Obukhov length as a cornerstone of the SEBAL calculations of evapotranspiration. Journal of Hydrology 335: 170-179.).

The iteration of internal calibration is carried out to assign two evapotranspiration extreme conditions. One when H is equal to zero called “cold” pixel, and another for the latent heat flux (λΕΤ) equal to zero called “hot” pixel.

The “cold” pixel is selected on well-irrigated agricultural surfaces covered by vegetation, representing the maximum quantity of energy available that was consumed by the evapotranspiration process. The “hot” pixel is selected in fields with dry bare soil, where evapotranspiration is assumed zero (λΕΤ = 0) or H = Rn - G. The selection of the pixels is described in Allen et al. (2007)Allen, R.G.; Tasumi, M.; Trezza, R. 2007. Satellite-based energy balance for mapping evapotranspiration with internalized calibration (METRIC)-model. Journal of Irrigation and Drainage Engineering 133: 380-394.. In this study, “hot” and “cold” pixels were selected manually.

The last stage of the SEBAL algorithm is the evapotranspiration estimate. Once calculating the energy balance fluxes, the instantaneous evapotranspiration (ET.) at satellite overpass time is calculated as follow:

(6)

E T_{i} = 3600 \frac{λ E T}{λ}

where: ET is the instantaneous evapotranspiration, (mm h⁻¹); 3600 is the number of seconds at one hour, and; λ is the latent heat of vaporization, (J kg⁻¹) stated by Allen et al. (2007)Allen, R.G.; Tasumi, M.; Trezza, R. 2007. Satellite-based energy balance for mapping evapotranspiration with internalized calibration (METRIC)-model. Journal of Irrigation and Drainage Engineering 133: 380-394. as:

(7)

λ = [2.501 - 0.00236 (T_{S} - 273.15)] 10^{6}

Therefore, daily (ET_o) and hourly (ET_oi) reference evapotranspirations were calculated through the Penman-Monteith method (Allen et al.,1998Allen, R.G.; Pereira, L.S.; Raes, D.; Smith, M. 1998. Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements. FAO, Rome, Italy. (Irrigation and Drainage Paper, 56).). After estimating the values of ET_i, from SEBAL, and ET_oi, the ratio between these variables provides a coefficient called reference evapotranspiration fraction (ET_of). When obtained on agricultural surfaces, this coefficient is similar to crop coefficient (K_c) (Tasumi et al., 2005Tasumi, M.; Allen, R.G.; Trezza, R.; Wright, J.L. 2005. Satellite-based energy balance to assess within-population variance of crop coefficient curves. Journal of Irrigation and Drainage Engineering 131: 94-109.).

ET_of at hour of satellite overpass is relatively constant during the day, as highlighted by Allen et al. (2007)Allen, R.G.; Tasumi, M.; Trezza, R. 2007. Satellite-based energy balance for mapping evapotranspiration with internalized calibration (METRIC)-model. Journal of Irrigation and Drainage Engineering 133: 380-394.. The daily or actual evapotranspiration (ET_a) is calculated as:

(8)

E T_{a} = E T_{o f} E T_{o}

where: ET_a is the actual evapotranspiration, (mm d⁻¹); ET_of reference evapotranspiration fraction, (decimal), and; ET_o is the reference of daily evapotranspiration (mm d⁻¹).

The calculation steps of the SEBAL algorithm were performed using a Python script SEBAL GRASS (Wolff, 2016Wolff, W. 2016. Script to calculate daily evapotranspiration for Landsat 8 images in GRASS GIS. Available at: http://doi.org/10.5281/zenodo.167350 [Accessed Sept 11, 2016]
http://doi.org/10.5281/zenodo.167350... ), at GRASS GIS (GRASS Development Team, version 7.0).

Reference evapotranspiration (ET_o) and crop coefficient (K_c)

The reference evapotranspiration for the satellite days of passage was estimated using the Penman-Monteith method, according to the methodology described by Allen et al. (1998)Allen, R.G.; Pereira, L.S.; Raes, D.; Smith, M. 1998. Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements. FAO, Rome, Italy. (Irrigation and Drainage Paper, 56)., using the REF-ET software (Reference Evapotranspiration Calculation, version 2.01.14). Solar radiation, relative humidity, wind speed and precipitation are required to estimate ET in REF-ET and a dataset of maximum and minimum temperatures.

The meteorological data used in ET_o estimates were obtained from the automatic meteorological station in the study site. This station was installed at 2 m above ground and recorded the time data, storing them in a data acquisition system. After obtaining ET_o, the K_c value was obtained from the ratio between actual and reference evapotranspiration.

The term crop coefficient (K_c) was applied throughout the study representing K_c multiplied by the soil water stress coefficient (K_s) (Allen et al., 1998Allen, R.G.; Pereira, L.S.; Raes, D.; Smith, M. 1998. Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements. FAO, Rome, Italy. (Irrigation and Drainage Paper, 56).). If K_c includes K_s and K_c, it influences the comparison with theoretical K_c values of FAO 56. In other words, the soil was considered to be at field capacity on the assessed days.

The K_c values obtained from the images were only considered for the following study stages in adult and young coffee crops. The mean K_c for young coffee plants was calculated using values from areas of four central pivots that cover an area of 2,250,000 m², corresponding to 2,491 pixels (30 m × 30 m). The mean K_c for adult coffee plants, on the other hand, was calculated using values from the areas of 13 central pivots, which cover an area of 12,840,000 m², corresponding to 14,267 pixels (30 m × 30 m).

Coffee crops were considered young with less than three years and adult with three years or more. The polygon delimitation of young and adult coffee crops considered edge pixels that entered neighboring fields. However, the ET_c values of these edge pixels were only considered to calculate the averages when more than 50 % of their coverage area was within a certain pivot.

Data analyses

The monthly mean and standard deviation calculations were performed for each situation considering ET_a and K_c values obtained through the SEBAL method. ET monthly average was calculated based on data from 2014 and 2015. For young coffee crops, we used mean values of four pivots and for adult coffee plantations, 13 pivots were used to calculate mean values.

ET_a values of young and adult coffee crops based on the SEBAL algorithm were compared to ET (mm d⁻¹) calculated from observed data. The measured ET_c was obtained by multiplying the estimated ET_o in the Penman-Monteith (PM) method by the K_c of recommendations from the FAO-56 bulletin and reference studies in Brazil (Table 2).

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Table 2
Conditions for the development of coffee crop coefficient (K_c) studies and values used in comparison of the coffee K_c estimated by the SEBAL model with the K_c recommended by the reference studies.

Statistical analyses were performed to determine differences between ET_c measured and estimated: Root Mean Square Error (MBE), Mean Bias Error (MBE), Normalized Root Mean Square Error (NRMSE) and Index of Agreement (d) to know the significance between measured and estimated values.

Results and Discussion

Figure 2 shows some steps applied in the SEBAL algorithm to estimate actual evapotranspiration and coffee crop coefficient. For this satellite date of passage (28 July 2015), the NDVI (index of vegetation that varies in a scale from −1 to 1) negative values correspond to water surfaces and positive values represent surfaces, low values for less vegetated and high values for more vegetated) displayed a maximum value of 0.87 and a minimum value of −0.88.

Figure 2
Spatial distribution of the variables used in the Surface Energy Balance Algorithm for Land (SEBAL). Normalized Difference Vegetation Index (NDVI), Soil Adjusted Vegetation Index (SAVI), Leaf Area Index (LAI), Surface temperature (T_s), Surface albedo (a_S) and Radiation balance (R_n). Variables were calculated based on images obtained on 28 July 2015.

The SAVI varied between −0.42 and 0.83, and the LAI was between 0 and 6. Surface temperature exhibited a maximum value of 39.05 °C and a minimum value of 5.5 °C (average maximum surface temperature in July in the study site is 29.1 °C). The surface albedo was between 0.03 and 0.94 and the radiation balance varied from 34.41 W m⁻² to 598 W m⁻².

Figure 3 shows examples of the spatial distribution ET annual and the K_c, estimated using the SEBAL algorithm. The annual evapotranspiration ranged from 0.0 to 960.30 mm, and vegetation areas displayed the highest values of ET annual. Areas with bare soil were showed the lowest values of ET annual and areas with rivers and lakes showed average values of the variable.

Figure 3
Spatial distribution of annual evapotranspiration (ET annual) and crop coefficient (K_c) in the studied areas. K_c was calculated based on images obtained on 28 July 2015 and ET annual was calculated with the average evapotranspiration in 2014 and 2015.

Regarding the crop coefficient, a variation between 0.0 and 1.20 was observed and, as expected, the vegetation areas had the highest values, while areas with bare soil, had the lowest. The central pivot areas with adult coffee plants can be easily identified since they retain high K_c values. The areas with adult coffee crops present a higher percentage of vegetated surface when compared to the areas with young coffee plantations planted with 3.5 m spacing between rows in the study site. Furthermore, the SEBAL method is calibrated based on the “hot” and “cold” pixels that are selected according to the vegetal cover percentage. Thus, ET_c estimated by SEBAL is higher in areas with higher vegetated surface, if the pixel is chosen properly, resulting in higher K_c values.

Table 3 shows the monthly average values of ET_a and K_c of young and adult coffee plantations based on the SEBAL algorithm. For young coffee crops, the ET_a was 2.17 mm d⁻¹, on average, with a standard deviation 0.7 mm d⁻¹, on average. The mean value K_c was 0.6 for coffee plants in the same phase, with a standard deviation 0.43, on average.

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Table 3
Monthly average values of actual evapotranspiration (ET_a) and crop coefficient (K_c) of young and adult coffee plantations based on the SEBAL algorithm and the respective standard deviation (SD).

Regarding the adult coffee plantation, the ET_a was 3.95 mm d⁻¹, on average, with a standard deviation 0.78 mm d⁻¹, on average. The low standard deviation values observed among the pixels are indicative of a uniform water supply by the central pivots, which enables homogeneous growth of coffee plants, resulting in a smaller difference between the K_c values at different points of the plantation. The mean K_c value was 0.85 for coffee plants in the same phase, with a mean standard deviation 0.48. On average, the K_c for adult coffee plants was higher in the final phase and lower in the initial phase, with median value during the intermediate phase.

Figure 4 (A, B, C, D and E) show values of ET_c of young coffee plantations based on the SEBAL algorithm and ET_c calculated with observed data. Comparing ET_c obtained by the SEBAL algorithm with ET_c calculated and recommended by Lima and Silva (2008)Lima, E.P.; Silva, E.L. 2008. Base temperature, crop coefficients and degrees-day for arabic coffee plants in the implantation phase. Revista Brasileira de Engenharia Agrícola e Ambiental 12: 266-273 (in Portuguese, with abstract in English). using the variety Rubi MG 1192 (Figure 4A) and Acaiá Cerrado (Figure 4B), the Index of Agreement (d) described exhibited values below 0.44, regardless of the variety, indicating low accuracy of the model in these situations. The Root Mean Square Error (RMSE) was below 0.94, the Mean Bias Error (MBE) was below 0.82 and the Normalized Root Mean Square Error (NRMSE) was below 0.75, indicating a rather unacceptable precision of the ET estimate, based on the SEBAL method.

Figure 4
Crop evapotranspiration (ET_c) of young coffee plantations based on the SEBAL algorithm compared to ET_c (mm d⁻¹) calculated with observed data. ET_c observed was obtained by multiplying the reference evapotranspiration (ET_o) calculated by the Penman-Monteith (PM) method by the crop coefficient (K_c) of reference studies in Brazil. Lima and Silva (2008)Lima, E.P.; Silva, E.L. 2008. Base temperature, crop coefficients and degrees-day for arabic coffee plants in the implantation phase. Revista Brasileira de Engenharia Agrícola e Ambiental 12: 266-273 (in Portuguese, with abstract in English). using the variety Rubi MG 1192 (A) and Acaiá Cerrado (B) and Santinato et al. (2008)Santinato, R.; Fernandes, A.L.; Fernandes, D.R. 2008. Irrigation in Coffee Culture = Irrigação na Cultura do Café. O Lutador, Uberaba, MG, Brazil (in Portuguese). with crop density of 2500 (C), 3300 (D) and 6700 plants ha⁻¹ (E).

This may have occurred because crop coefficients show little or no variation throughout the year, recommended by the reference studies. This issue differs from the other estimation studies, carried out using the SEBAL model, which obtained a different crop coefficient value for each month. Furthermore, sites of young coffee plantations present a higher rate of soil without vegetation cover, reducing accuracy of the estimation model. For future studies in these conditions, changes are suggested in the algorithm including correction factors for estimates in young coffee plantations.

In the validation of the ET_c obtained by the SEBAL algorithm with the values of the ET_c calculated by observed data and recommended by Santinato et al. (2008)Santinato, R.; Fernandes, A.L.; Fernandes, D.R. 2008. Irrigation in Coffee Culture = Irrigação na Cultura do Café. O Lutador, Uberaba, MG, Brazil (in Portuguese). using the crop density of 2500 (Figure 4C), 3300 (Figure 4D) and 6700 plants ha⁻¹ (Figure 4E), the index d described exhibited values lower than 0.50, regardless of the crop density, indicating low accuracy of the model in these situations. The RMSE was below 0.79, the MBE was below 0.67 and the NRMSE was below 0.63, also indicating unacceptable precision of the ET_c estimate, based on the SEBAL method.

The comparison of ET_c values of the adult coffee plantations based on the SEBAL method with values of ET_c calculated is shown in Figures 5A, B, C, D, E, F, G, and H. In the validation of the ET_c obtained by the SEBAL algorithm with the ET_c calculated through observed data and recommended by Allen et al. (1998)Allen, R.G.; Pereira, L.S.; Raes, D.; Smith, M. 1998. Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements. FAO, Rome, Italy. (Irrigation and Drainage Paper, 56). with (Figure 5A) and without (Figure 5B) plant covering, index d presents values higher than 0.62, regardless of plant cover, indicating relatively high accuracy of the model in these situations. The RMSE was below 0.51, the MBE was below 0.43 and the NRMSE was below 0.50, also indicating reasonable precision of the ET estimate, based on the SEBAL method.

Figure 5
Crop evapotranspiration (ET_c) of adult coffee plantations based on the SEBAL algorithm compared to ET_c (mm d⁻¹) calculated with observed data. ET_c observed was obtained by multiplying the reference evapotranspiration (ET_o) calculated by the Penman-Monteith (PM) method by the crop coefficient (K_c) of recommendations from the FAO-56 bulletin and reference studies in Brazil. Allen et al. (1998)Allen, R.G.; Pereira, L.S.; Raes, D.; Smith, M. 1998. Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements. FAO, Rome, Italy. (Irrigation and Drainage Paper, 56). with (A) and without (B) plant covering, Villa Nova et al. (2002)Villa Nova, N.A.; Favarin, J.L.; Angelocci, L.R.; Dourado-Neto, D. 2002. Estimative of the coffee crop coefficient as function of the weather and plant parameters. Bragantia 61: 81-88 (in Portuguese, with abstract in English). with (C) and without (D) plant covering and with crop density of 2500 (E), 3300 (F) and 4000 plants ha⁻¹ (G) and Sato et al. (2007)Sato, F.A.; Silva, A.M.D.; Coelho, G.U.; Silva, A.C.; Carvalho, L.G.D. 2007. Crop coefficient (Kc) for coffee (Coffea L.) during the winter-fall seasons in Lavras region-MG, Brazil. Engenharia Agrícola 27: 383-391 (in Portuguese, with abstract in English). (H).

Rawat et al. (2017)Rawat, K.S.; Bala, A.; Singh, S.K.; Pal, R.K. 2017. Quantification of wheat crop evapotranspiration and mapping: a case study from Bhiwani District of Haryana, India. Agricultural Water Management 187: 200-209. estimated the ET_c of wheat crop by the SEBAL and standardized FAO-PM methods in Bhiwani District of Haryana, India, and the results obtained were evaluated through statistical performance measure tests. The statistical parameters found (RMSE = 0.56, NRMSE = 0.20 and d = 0.87) showed a good agreement between SEBAL ET and PM ET. The findings of this work suggested that the SEBAL model shows a good potential to estimate spatial ET_c for the region studied.

In the validation of the ET_c obtained by the SEBAL algorithm with the values of the ET_c calculated with observed data and recommended by Villa Nova et al. (2002)Villa Nova, N.A.; Favarin, J.L.; Angelocci, L.R.; Dourado-Neto, D. 2002. Estimative of the coffee crop coefficient as function of the weather and plant parameters. Bragantia 61: 81-88 (in Portuguese, with abstract in English). with (Figure 5C) and without (Figure 5D) plant covering and with crop density of 2500 (Figure 5E), 3300 (Figure 5F) and 4000 plants ha⁻¹ (Figure 5G), the index d described exhibited values higher than 0.40, regardless of the plant covering and the crop density, indicating relatively high accuracy of the model in these situations. The RMSE was below 1.20, the MBE was below 1.12 and the NRMSE was below 1.17, also indicating reasonable precision of the ET_c estimate, based on the SEBAL method.

In the comparison of the ET_c obtained by the SEBAL algorithm with the values of the ET_c calculated with observed data and recommended by Sato et al. (2007)Sato, F.A.; Silva, A.M.D.; Coelho, G.U.; Silva, A.C.; Carvalho, L.G.D. 2007. Crop coefficient (Kc) for coffee (Coffea L.) during the winter-fall seasons in Lavras region-MG, Brazil. Engenharia Agrícola 27: 383-391 (in Portuguese, with abstract in English). (Figure 5H), the index d presents exhibited value 0.50, indicating low accuracy of the model in this situation. The RMSE was 0.77, the MBE was 0.69 and the NRMSE was 0.75, also indicating reasonable accuracy of the ET_c estimate, based on the SEBAL method.

Bala et al. (2016)Bala, A.; Rawat, K.S.; Misra, A.K.; Srivastava, A. 2016. Assessment and validation of evapotranspiration using SEBAL algorithm and Lysimeter data of IARI agricultural farm, India. Geocarto International 31: 739-764. also estimated the ET_c of wheat crop by SEBAL and compared it to ET from lysimetric technique by using statistical parameters. The authors found RMSE values equal to 0.19 and NRMSE 0.21 mm d⁻¹. The errors or deviations found in the comparisons between estimated and measured values may come from the estimation model itself or from the way these data are compared. The comparison methodology using fixed K_c values for long periods of the year can also result in unexpected values of certain statistical parameters.

Conclusion

The ET and K data obtained based on the SEBAL cc algorithm displayed similar values to studies that used traditional methods. The SEBAL algorithm is a more parsimonious alternative in K_c estimation; therefore, the K_c obtained by this method can be used directly in coffee crops.

The method of ET_a and spatialized K_c estimation allowed understanding the variability of the study site, supporting the use of precision irrigation. Therefore, this model has high potential to estimate ET of different stages of coffee plantations for the region studied. This may also help understand crop water requirement and irrigation scheduling in the region.

Acknowledgements

LANDSAT data from USGS used in this study are acknowledged. This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brazil (CAPES) - Finance Code 001. We are thank also to the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), the Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) and the Fundação de Estudos Agrários Luiz de Queiroz (FEALQ) for financial support.

References

Allen, R.G.; Pereira, L.S.; Raes, D.; Smith, M. 1998. Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements. FAO, Rome, Italy. (Irrigation and Drainage Paper, 56).
Allen, R.G.; Tasumi, M.; Trezza, R. 2007. Satellite-based energy balance for mapping evapotranspiration with internalized calibration (METRIC)-model. Journal of Irrigation and Drainage Engineering 133: 380-394.
Allen, R.G.; Pereira, L.S.; Howell, T.A.; Jensen, M. E. 2011. Evapotranspiration information reporting. I. Factors governing measurement accuracy. Agricultural Water Management 98: 899-920.
Alvares, C.A.; Stape, J.L.; Sentelhas, P.C.; Gonçalves, J.L.M.; Sparovek, G. 2013. Köppen's climate classification map for Brazil. Meteorologische Zeitschrift 22: 711-728.
Bala, A.; Rawat, K.S.; Misra, A.K.; Srivastava, A. 2016. Assessment and validation of evapotranspiration using SEBAL algorithm and Lysimeter data of IARI agricultural farm, India. Geocarto International 31: 739-764.
Bastiaanssen, W.G.; Menenti, M.; Feddes, R.A.; Holtslag, A.A.M. 1998a. A remote sensing surface energy balance algorithm for land (SEBAL). 1. Formulation. Journal of Hydrology 212: 198-212.
Bastiaanssen, W.G.; Pelgrum, H.; Wang, J.; Ma, Y.; Moreno, J. F.; Roerink, G. J.; Van der Wal, T. 1998b. A remote sensing surface energy balance algorithm for land (SEBAL). Part 2. Validation. Journal of Hydrology 212: 213-229.
Bastiaanssen, W. 2000. SEBAL-based sensible and latent heat fluxes in the irrigated Gediz Basin, Turkey. Journal of Hydrology 229: 87-100.
Bastiaanssen, W.G.M.; Noordman, E.J.M.; Pelgrum, H.; Davids, G.; Thoreson, B.P.; Allen, R.G. 2005. SEBAL model with remotely sensed data to improve water-resources management under actual field conditions. Journal of Irrigation and Drainage Engineering 131: 85-93.
Boltzmann, L. 1884. Derivation of Stefan's law, concerning the dependence of thermal radiation on temperature from the electromagnetic theory of light = Ableitung des Stefan'schen Gesetzes, betreffend die Abhängigkeit der Wärmestrahlung von der Temperatur aus der electromagnetischen Lichttheorie. Annalen der Physik 258: 291-294 (in German).
Flumignan, D.L.; Faria, R.T.; Prete, C.E.C. 2011. Evapotranspiration components and dual crop coefficients of coffee trees during crop production. Agricultural Water Management 98: 791-800.
Kiptala, J.K.; Mohamed, Y.; Mul, M.L.; Zaag, P. 2013. Mapping evapotranspiration trends using MODIS and SEBAL model in a data scarce and heterogeneous landscape in Eastern Africa. Water Resources Research 49: 8495-8510.
Koloskov, G.; Mukhamejanov, K.; Tanton, T. 2007. Monin-Obukhov length as a cornerstone of the SEBAL calculations of evapotranspiration. Journal of Hydrology 335: 170-179.
Li, H.; Zheng, L.; Lei, Y.; Li, C.; Liu, Z.; Zhang, S. 2008. Estimation of water consumption and crop water productivity of winter wheat in North China Plain using remote sensing technology. Agricultural Water Management 95: 1271-1278.
Lima, E.P.; Silva, E.L. 2008. Base temperature, crop coefficients and degrees-day for arabic coffee plants in the implantation phase. Revista Brasileira de Engenharia Agrícola e Ambiental 12: 266-273 (in Portuguese, with abstract in English).
Marin, F.R.; Angelocci, L.R.; Righi, E.Z.; Sentelhas, P.C. 2005. Evapotranspiration and irrigation requirements of a coffee plantation in southern Brazil. Experimental Agriculture 41: 187-197.
Mkhwanazi, M.; Chávez, J.L.; Andales, A.A. 2015. SEBAL-A: a remote sensing ET algorithm that accounts for advection with limited data. Part I. Development and validation. Remote Sensing 7: 15046-15067.
Navarro, A.; Rolim, J.; Miguel, I.; Catalao, J.; Painho, M.; Vekerdy, Z. 2016. Crop monitoring based on SPOT-5 Take-5 and Sentinel-1A data for the estimation of crop water requirements. Remote Sensing 8: 525-544.
Paul, G.; Gowda, P.H.; Prasad, P.V.; Howell, T.A.; Staggenborg, S.A.; Neale, C.M. 2013. Lysimetric evaluation of SEBAL using high resolution airborne imagery from BEAREX 08. Advances in Water Resources 59: 157-168.
Rawat, K.S.; Bala, A.; Singh, S.K.; Pal, R.K. 2017. Quantification of wheat crop evapotranspiration and mapping: a case study from Bhiwani District of Haryana, India. Agricultural Water Management 187: 200-209.
Ruhoff, A.L.; Paz, A.R.; Collischonn, W.; Aragao, L.E.; Rocha, H.R.; Malhi, Y.S. 2012. A MODIS-based energy balance to estimate evapotranspiration for clear-sky days in Brazilian tropical savannas. Remote Sensing 4: 703-725.
Santinato, R.; Fernandes, A.L.; Fernandes, D.R. 2008. Irrigation in Coffee Culture = Irrigação na Cultura do Café. O Lutador, Uberaba, MG, Brazil (in Portuguese).
Sari, D.K.; Ismullah, I.H.; Sulasdi, W.N.; Harto, A.B. 2013. Estimation of water consumption of lowland rice in tropical area based on heterogeneous cropping calendar using remote sensing technology. Procedia Environmental Sciences 17: 298-307.
Sato, F.A.; Silva, A.M.D.; Coelho, G.U.; Silva, A.C.; Carvalho, L.G.D. 2007. Crop coefficient (K_c) for coffee (Coffea L.) during the winter-fall seasons in Lavras region-MG, Brazil. Engenharia Agrícola 27: 383-391 (in Portuguese, with abstract in English).
Silva, B.B.; Braga, A.C.; Braga, C.C.; Oliveira, L.M.M.D.; Montenegro, S.M.G.L.; Barbosa Junior, B. 2016. Procedures for calculation of the albedo with OLI-Landsat 8 images: application to the Brazilian semi-arid. Revista Brasileira de Engenharia Agrícola e Ambiental 20: 3-8.
Tasumi, M.; Allen, R.G.; Trezza, R.; Wright, J.L. 2005. Satellite-based energy balance to assess within-population variance of crop coefficient curves. Journal of Irrigation and Drainage Engineering 131: 94-109.
Teixeira, A.D.C.; Bastiaanssen, W.G.M.; Ahmad, M.U.D.; Bos, M. G. 2009. Reviewing SEBAL input parameters for assessing evapotranspiration and water productivity for the Low-Middle Sao Francisco river basin, Brazil. Part A. Calibration and validation. Agricultural and Forest Meteorology 149: 462-476.
Villa Nova, N.A.; Favarin, J.L.; Angelocci, L.R.; Dourado-Neto, D. 2002. Estimative of the coffee crop coefficient as function of the weather and plant parameters. Bragantia 61: 81-88 (in Portuguese, with abstract in English).
Weng, Q.; Lu, D.; Schubring, J. 2004. Estimation of land surface temperature vegetation abundance relation-ship for urban heat island studies. Remote Sensing of Environment 89: 467-483.
Wolff, W. 2016. Script to calculate daily evapotranspiration for Landsat 8 images in GRASS GIS. Available at: http://doi.org/10.5281/zenodo.167350 [Accessed Sept 11, 2016]
» http://doi.org/10.5281/zenodo.167350

Edited by

Edited by: Lincoln Zotarelli

Publication Dates

Publication in this collection
Mar-Apr 2019

History

Received
02 May 2017
Accepted
07 Oct 2017

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Allen, R.G.; Pereira, L.S.; Raes, D.; Smith, M. 1998. Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements. FAO, Rome, Italy. (Irrigation and Drainage Paper, 56).

[2] Allen, R.G.; Tasumi, M.; Trezza, R. 2007. Satellite-based energy balance for mapping evapotranspiration with internalized calibration (METRIC)-model. Journal of Irrigation and Drainage Engineering 133: 380-394.

[3] Allen, R.G.; Pereira, L.S.; Howell, T.A.; Jensen, M. E. 2011. Evapotranspiration information reporting. I. Factors governing measurement accuracy. Agricultural Water Management 98: 899-920.

[4] Alvares, C.A.; Stape, J.L.; Sentelhas, P.C.; Gonçalves, J.L.M.; Sparovek, G. 2013. Köppen's climate classification map for Brazil. Meteorologische Zeitschrift 22: 711-728.

[5] Bala, A.; Rawat, K.S.; Misra, A.K.; Srivastava, A. 2016. Assessment and validation of evapotranspiration using SEBAL algorithm and Lysimeter data of IARI agricultural farm, India. Geocarto International 31: 739-764.

[6] Bastiaanssen, W.G.; Menenti, M.; Feddes, R.A.; Holtslag, A.A.M. 1998a. A remote sensing surface energy balance algorithm for land (SEBAL). 1. Formulation. Journal of Hydrology 212: 198-212.

[7] Bastiaanssen, W.G.; Pelgrum, H.; Wang, J.; Ma, Y.; Moreno, J. F.; Roerink, G. J.; Van der Wal, T. 1998b. A remote sensing surface energy balance algorithm for land (SEBAL). Part 2. Validation. Journal of Hydrology 212: 213-229.

[8] Bastiaanssen, W. 2000. SEBAL-based sensible and latent heat fluxes in the irrigated Gediz Basin, Turkey. Journal of Hydrology 229: 87-100.

[9] Bastiaanssen, W.G.M.; Noordman, E.J.M.; Pelgrum, H.; Davids, G.; Thoreson, B.P.; Allen, R.G. 2005. SEBAL model with remotely sensed data to improve water-resources management under actual field conditions. Journal of Irrigation and Drainage Engineering 131: 85-93.

[10] Boltzmann, L. 1884. Derivation of Stefan's law, concerning the dependence of thermal radiation on temperature from the electromagnetic theory of light = Ableitung des Stefan'schen Gesetzes, betreffend die Abhängigkeit der Wärmestrahlung von der Temperatur aus der electromagnetischen Lichttheorie. Annalen der Physik 258: 291-294 (in German).

[11] Flumignan, D.L.; Faria, R.T.; Prete, C.E.C. 2011. Evapotranspiration components and dual crop coefficients of coffee trees during crop production. Agricultural Water Management 98: 791-800.

[12] Kiptala, J.K.; Mohamed, Y.; Mul, M.L.; Zaag, P. 2013. Mapping evapotranspiration trends using MODIS and SEBAL model in a data scarce and heterogeneous landscape in Eastern Africa. Water Resources Research 49: 8495-8510.

[13] Koloskov, G.; Mukhamejanov, K.; Tanton, T. 2007. Monin-Obukhov length as a cornerstone of the SEBAL calculations of evapotranspiration. Journal of Hydrology 335: 170-179.

[14] Li, H.; Zheng, L.; Lei, Y.; Li, C.; Liu, Z.; Zhang, S. 2008. Estimation of water consumption and crop water productivity of winter wheat in North China Plain using remote sensing technology. Agricultural Water Management 95: 1271-1278.

[15] Lima, E.P.; Silva, E.L. 2008. Base temperature, crop coefficients and degrees-day for arabic coffee plants in the implantation phase. Revista Brasileira de Engenharia Agrícola e Ambiental 12: 266-273 (in Portuguese, with abstract in English).

[16] Marin, F.R.; Angelocci, L.R.; Righi, E.Z.; Sentelhas, P.C. 2005. Evapotranspiration and irrigation requirements of a coffee plantation in southern Brazil. Experimental Agriculture 41: 187-197.

[17] Mkhwanazi, M.; Chávez, J.L.; Andales, A.A. 2015. SEBAL-A: a remote sensing ET algorithm that accounts for advection with limited data. Part I. Development and validation. Remote Sensing 7: 15046-15067.

[18] Navarro, A.; Rolim, J.; Miguel, I.; Catalao, J.; Painho, M.; Vekerdy, Z. 2016. Crop monitoring based on SPOT-5 Take-5 and Sentinel-1A data for the estimation of crop water requirements. Remote Sensing 8: 525-544.

[19] Paul, G.; Gowda, P.H.; Prasad, P.V.; Howell, T.A.; Staggenborg, S.A.; Neale, C.M. 2013. Lysimetric evaluation of SEBAL using high resolution airborne imagery from BEAREX 08. Advances in Water Resources 59: 157-168.

[20] Rawat, K.S.; Bala, A.; Singh, S.K.; Pal, R.K. 2017. Quantification of wheat crop evapotranspiration and mapping: a case study from Bhiwani District of Haryana, India. Agricultural Water Management 187: 200-209.

[21] Ruhoff, A.L.; Paz, A.R.; Collischonn, W.; Aragao, L.E.; Rocha, H.R.; Malhi, Y.S. 2012. A MODIS-based energy balance to estimate evapotranspiration for clear-sky days in Brazilian tropical savannas. Remote Sensing 4: 703-725.

[22] Santinato, R.; Fernandes, A.L.; Fernandes, D.R. 2008. Irrigation in Coffee Culture = Irrigação na Cultura do Café. O Lutador, Uberaba, MG, Brazil (in Portuguese).

[23] Sari, D.K.; Ismullah, I.H.; Sulasdi, W.N.; Harto, A.B. 2013. Estimation of water consumption of lowland rice in tropical area based on heterogeneous cropping calendar using remote sensing technology. Procedia Environmental Sciences 17: 298-307.

[24] Sato, F.A.; Silva, A.M.D.; Coelho, G.U.; Silva, A.C.; Carvalho, L.G.D. 2007. Crop coefficient (K_c) for coffee (Coffea L.) during the winter-fall seasons in Lavras region-MG, Brazil. Engenharia Agrícola 27: 383-391 (in Portuguese, with abstract in English).

[25] Silva, B.B.; Braga, A.C.; Braga, C.C.; Oliveira, L.M.M.D.; Montenegro, S.M.G.L.; Barbosa Junior, B. 2016. Procedures for calculation of the albedo with OLI-Landsat 8 images: application to the Brazilian semi-arid. Revista Brasileira de Engenharia Agrícola e Ambiental 20: 3-8.

[26] Tasumi, M.; Allen, R.G.; Trezza, R.; Wright, J.L. 2005. Satellite-based energy balance to assess within-population variance of crop coefficient curves. Journal of Irrigation and Drainage Engineering 131: 94-109.

[27] Teixeira, A.D.C.; Bastiaanssen, W.G.M.; Ahmad, M.U.D.; Bos, M. G. 2009. Reviewing SEBAL input parameters for assessing evapotranspiration and water productivity for the Low-Middle Sao Francisco river basin, Brazil. Part A. Calibration and validation. Agricultural and Forest Meteorology 149: 462-476.

[28] Villa Nova, N.A.; Favarin, J.L.; Angelocci, L.R.; Dourado-Neto, D. 2002. Estimative of the coffee crop coefficient as function of the weather and plant parameters. Bragantia 61: 81-88 (in Portuguese, with abstract in English).

[29] Weng, Q.; Lu, D.; Schubring, J. 2004. Estimation of land surface temperature vegetation abundance relation-ship for urban heat island studies. Remote Sensing of Environment 89: 467-483.

[30] Wolff, W. 2016. Script to calculate daily evapotranspiration for Landsat 8 images in GRASS GIS. Available at: http://doi.org/10.5281/zenodo.167350 [Accessed Sept 11, 2016]
» http://doi.org/10.5281/zenodo.167350

2014		2015
Jan 14^th	July 9^th	Jan17^th	July 28^th
Feb 15^th	Aug 10^th	Feb 2^nd	Aug 29^th
Mar 19^th	Sept 11^th	Mar 6^th	Sept 30^th
Apr 20^th	Oct 13^th	Apr 23^th	Oct 16^th
May 22^nd	Nov 30^th	May 25^th	^* * In Dec 2014 and Nov of 2015, the available images presented many clouds and, for these months, the average crop evapotranspiration (ETc) was made based on a year only.
June 7^th	^* * In Dec 2014 and Nov of 2015, the available images presented many clouds and, for these months, the average crop evapotranspiration (ETc) was made based on a year only.	June 10^th	Dec 3^rd

Reference	Plant Covering	Dc	Variety	Irrigation systems	Country	K_c values
Reference	Plant Covering	Dc	Variety	Irrigation systems	Country	I	M	F
Allen et al. (1998)Allen, R.G.; Pereira, L.S.; Raes, D.; Smith, M. 1998. Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements. FAO, Rome, Italy. (Irrigation and Drainage Paper, 56).	no	^ general crop conditions; I = Initial phase; M = Intermediate phase; F = Final phase.	^ general crop conditions; I = Initial phase; M = Intermediate phase; F = Final phase.	^ general crop conditions; I = Initial phase; M = Intermediate phase; F = Final phase.	USA	0.90	0.95	0.95	Adult
	yes				USA	1.05	1.10	1.10
	no	4000				0.71	0.53	0.60
	yes	4000				0.93	0.91	0.83
Villa Nova et al. (2002)Villa Nova, N.A.; Favarin, J.L.; Angelocci, L.R.; Dourado-Neto, D. 2002. Estimative of the coffee crop coefficient as function of the weather and plant parameters. Bragantia 61: 81-88 (in Portuguese, with abstract in English).	^* * not specified;	2500	Mundo Novo IAC 388-17	Conventional aspersion	Brazil	0.94	0.94	0.89
	^* * not specified;	3300				0.93	0.92	0.86
	^* * not specified;	4000				0.90	0.90	0.83
Sato et al. (2007)Sato, F.A.; Silva, A.M.D.; Coelho, G.U.; Silva, A.C.; Carvalho, L.G.D. 2007. Crop coefficient (Kc) for coffee (Coffea L.) during the winter-fall seasons in Lavras region-MG, Brazil. Engenharia Agrícola 27: 383-391 (in Portuguese, with abstract in English).	^* * not specified;	3571	Catuaí vermelho IAC 44	Dripping	Brazil	1.11	0.96	0.68
Lima and Silva (2008)Lima, E.P.; Silva, E.L. 2008. Base temperature, crop coefficients and degrees-day for arabic coffee plants in the implantation phase. Revista Brasileira de Engenharia Agrícola e Ambiental 12: 266-273 (in Portuguese, with abstract in English).	^* * not specified;	3571	Rubi MG 1192 Acaiá Cerrado	Dripping	Brazil	0.39 0.33	0.46 0.42	0.32 0.28	Young
		2500				0.60	0.60	0.60
Santinato et al. (2008)Santinato, R.; Fernandes, A.L.; Fernandes, D.R. 2008. Irrigation in Coffee Culture = Irrigação na Cultura do Café. O Lutador, Uberaba, MG, Brazil (in Portuguese).	^* * not specified;	3300	^ general crop conditions; I = Initial phase; M = Intermediate phase; F = Final phase.	^ general crop conditions; I = Initial phase; M = Intermediate phase; F = Final phase.	Brazil	0.70	0.70	0.70
		6700				0.80	0.80	0.80

Phase	Month^* * Monthly average in 2014 and 2015;	Young coffee plantation^ Mean values In the four pivots analyzed;				Adult coffee plantation^* ***** Mean values In the 13 pivots analyzed; ETa = actual evapotranspiration (mm d−1); Kc = crop coefficient; SD = standard deviation.
Phase	Month^* * Monthly average in 2014 and 2015;	ET_a	SD	K_c	SD	ET_a	SD	K_c	SD
Intermediate	Jan	2.540	0.805	0.570	0.360	3.560	1.007	0.810	0.450
	Feb	2.030	0.802	0.590	0.500	3.337	0.967	0.690	0.580
	Mar	1.390	0.552	0.560	0.530	3.257	0.880	1.040	0.805
	Apr	1.640	0.542	0.570	0.410	3.220	0.620	1.010	0.460
Final	May	2.030	0.640	0.760	0.480	3.332	0.332	1.220	0.245
	June	2.020	0.835	0.850	0.700	2.710	0.332	1.000	0.280
	July	1.740	0.637	0.765	0.545	2.870	0.600	1.150	0.520
	Aug	2.250	0.252	0.650	0.145	3.095	0.470	0.820	0.275
Initial	Sept	1.280	0.802	0.310	0.395	3.292	0.980	0.680	0.475
	Oct	1.790	0.535	0.370	0.205	3.087	0.880	0.620	0.365
	Nov	2.540	1.155	0.675	0.645	2.535	1.012	0.480	0.560
	Dec	1.840	0.392	0.520	0.197	2.837	1.217	0.720	0.725

Brasil

Brasil

Spatial variability of coffee plant water consumption based on the SEBAL algorithm

ABSTRACT:

Introduction

Materials and Methods

Location and characterization of the study site

Satellite imaging

Evapotranspiration estimation (SEBAL algorithm)

Reference evapotranspiration (ETo) and crop coefficient (Kc)

Data analyses

Results and Discussion

Conclusion

Acknowledgements

References

Edited by

Publication Dates

History

Reference evapotranspiration (ET_o) and crop coefficient (K_c)