USE OF ACTIVE OPTICAL SENSOR IN THE CHARACTERISTICS ANALYSIS OF THE FERTIGATED BRACHIARIA WITH TREATED SEWAGE

Santos, Gilmar O.; Rosalen, David L.; Faria, Rogério T. de

doi:10.1590/1809-4430-Eng.Agric.v37n6p1213-1221/2017

ABSTRACT

Through the use of remote sensing, the productivity and the nutritional state of the plants can be estimated in relation to the nitrogen doses due to the modification of the canopy reflectance. In this study, values of the normalized difference vegetation index (NDVI) obtained by a terrestrial optical sensor were correlated with productivity and contents of nitrogen (N) and of foliar crude protein (CP) of Brachiaria brizantha cv. Marandu, fertigated with doses of sewage treatment effluent (STE) The NDVI average rates of the forage were obtained by the active terrestrial sensor (GreenSeeker) before the harvests that were realized every 28 days in 2014. Five fertigated treatments with the following fractions of STE in water were evaluated: E5 = 1.0; E4 = 0.87; E3 = 0.60; E2 = 0.31; and E1 = 0.11. During the 12 months of experiment, the treatment E5 received 1,132 kg ha^-1 of N and the others received quantities proportional according to the application fractions defined in each treatment. The increasing application doses of STE resulted in higher yields of dry biomass and better leaf qualities in N and crude protein (CP). The productivity, the foliar N content and the NDVI index were increasing due to the gradual application of applied STE. There was a high linear correlation among the NDVI indexes and the productivity (r>0.9256) and with the N content (r>0.9570) and also for CP (r>0.8421) and leaf N (r>0.8339), demonstrating that the method can be used to estimate forage productivity and quality.

KEYWORDS:
forage production estimation; GreenSeeker; terrestrial remote sensing

INTRODUCTION

One of the applications of the geotechnologies use is the estimation of agricultural productivity and the nutritional status of the crops in a fast and precise way, due to the close relation between these variables and vegetation indices (Zerbato et al., 2016Zerbato C, Rosalen DL, Furlani CEA, Deghaid J, Voltarelli MA (2016) Agronomic characteristics associated with the normalized difference vegetation index (NDVI) in the peanut crop. Australian Journal of Crop Science 10(5):758-764.). The high correlation between biomass accumulation and vegetation indices occurs due to the high levels of chlorophyll in the plant, which varies according to the environmental conditions and crop management, such as nitrogen application, resulting in increments of leaf area and photosynthetic activity (Grohs et al., 2011Grohs DS, Bredemeier C, Poletto N, Mundstock CM (2011) Validação de modelo para predição do potencial produtivo de trigo com sensor óptico ativo. Pesquisa Agropecuária Brasileira 46(4):446-449.).

The normalized difference vegetation index (NDVI) is an indicative of vegetation activity that enables to estimate the leaf area, the percentage of green cover and grain yield (Bredemeier et al., 2013Bredemeier C, Variani C, Almeida D, Rosa AT (2013) Estimativa do potencial produtivo em trigo utilizando sensor óptico ativo para adubação nitrogenada em taxa variável. Ciência Rural 43(7): 1147-1154.). It is also possible to characterize soil chemical attributes (Zanzarini et al., 2013Zanzarini FV, Pissarra TCT, Brandão FJC, Teixeira DB (2013) Correlação espacial do índice de vegetação (NDVI) de imagem Landsat/ETM+ com atributos do solo. Revista Brasileira de Engenharia Agrícola e Ambiental 17(6):608-614.), to determine the chlorophyll content and green biomass of plants (Merotto Júnior et al., 2012Merotto Júnior A, Bredemeier C, Vidal RA, Goulart ICGR, Bortoli ED, Anderson NL (2012) Reflectance indices as a diagnostic tool for weed control performed by multipurpose equipment in precision agriculture. Planta Daninha 30(2):437-447.), to characterize temporal series of phytoplankton in ponds (Lissner & Guasselli, 2013Lissner JB, Guasselli LA (2013) Variação do índice de vegetação por diferença normalizada na lagoa Itapeva, litoral norte do Rio Grande do Sul, Brasil, a partir de análise de séries temporais. Sociologia & Natureza 25(2):427-440.) and vegetation phytophysiology (Galvanin et al., 2014Galvanin EA dos S, Neves SMA da S, Cruz CBM, Neves RJ, Jesus PHH de, Kreitlow JP (2014) Avaliação dos índices de vegetação NDVI, SR e TVI na discriminação fitofisionomias dos ambientes do Pantanal de Cáceres/MT. Ciência Florestal 24(3):707-715.), and subsidize weed control (Merotto Júnior et al., 2012Merotto Júnior A, Bredemeier C, Vidal RA, Goulart ICGR, Bortoli ED, Anderson NL (2012) Reflectance indices as a diagnostic tool for weed control performed by multipurpose equipment in precision agriculture. Planta Daninha 30(2):437-447.).

The determination of leaf quality, defined in terms of leaf nitrogen content, is an example of the potential of the application of the vegetation indices, since this variable can be readily correlated with NDVI (Bredemeier et al., 2013Bredemeier C, Variani C, Almeida D, Rosa AT (2013) Estimativa do potencial produtivo em trigo utilizando sensor óptico ativo para adubação nitrogenada em taxa variável. Ciência Rural 43(7): 1147-1154.), while most methods based on chlorophyll meters and leaf analysis require a large number of leaf samples to identify the nutritional status of the crop in the field (Povh et al., 2008Povh FP, Molin JP, Gimenez LM, Pauletti V, Molin R, Salvi JV (2008) Comportamento do NDVI obtido por sensor ótico ativo em cereais. Pesquisa Agropecuária Brasileira 43(8):1075-1083.). Therefore, the obtaining of the NDVI data through terrestrial sensors allows fast assessment of productivity and foliage quality in relation to NDVI, without causing impacts by beddings on agricultural crops (Bredemeier et al., 2013Bredemeier C, Variani C, Almeida D, Rosa AT (2013) Estimativa do potencial produtivo em trigo utilizando sensor óptico ativo para adubação nitrogenada em taxa variável. Ciência Rural 43(7): 1147-1154.).

The GreenSeeker is one of these ground sensors that has been widely used to evaluate the performance of crops under variables doses of nitrogen, since the NDVI can indicate the nutritional status of the plant in relation to nitrogen (Grohs et al., 2011Grohs DS, Bredemeier C, Poletto N, Mundstock CM (2011) Validação de modelo para predição do potencial produtivo de trigo com sensor óptico ativo. Pesquisa Agropecuária Brasileira 46(4):446-449.; Merotto Júnior et al., 2012Merotto Júnior A, Bredemeier C, Vidal RA, Goulart ICGR, Bortoli ED, Anderson NL (2012) Reflectance indices as a diagnostic tool for weed control performed by multipurpose equipment in precision agriculture. Planta Daninha 30(2):437-447.; Bredemeier et al., 2013Bredemeier C, Variani C, Almeida D, Rosa AT (2013) Estimativa do potencial produtivo em trigo utilizando sensor óptico ativo para adubação nitrogenada em taxa variável. Ciência Rural 43(7): 1147-1154.). These determinations can be performed local scale, as performed by Zanzarini et al. (2013Zanzarini FV, Pissarra TCT, Brandão FJC, Teixeira DB (2013) Correlação espacial do índice de vegetação (NDVI) de imagem Landsat/ETM+ com atributos do solo. Revista Brasileira de Engenharia Agrícola e Ambiental 17(6):608-614.) in an area of 32 hectares. The estimate of the crop quality in foliar nitrogen or crude protein, from a certain phenological stage of the plants, allows the nutritional management of the crop (Grohs et al., 2011Grohs DS, Bredemeier C, Poletto N, Mundstock CM (2011) Validação de modelo para predição do potencial produtivo de trigo com sensor óptico ativo. Pesquisa Agropecuária Brasileira 46(4):446-449.).

In plants subjected to nitrogen stress, there is an increase in carotenoid concentrations and a reduction in chlorophyll production, which causes less energy absorption by leaves, reducing NDVI values (Motomiya et al., 2009Motomiya AV de A, Molin JP, Chiavegato EJ (2009) Utilização de sensor ótico ativo para detectar deficiência foliar de nitrogênio em algodoeiro. Revista Brasileira de Engenharia Agrícola e Ambiental 13(2):137-145.). Nitrogen deficiency causes predictable changes in the development and composition of plant leaves and, indirectly, changes in spectral distribution of reflected radiation, which makes it difficult to estimate productivity (Motomiya et al., 2009Motomiya AV de A, Molin JP, Chiavegato EJ (2009) Utilização de sensor ótico ativo para detectar deficiência foliar de nitrogênio em algodoeiro. Revista Brasileira de Engenharia Agrícola e Ambiental 13(2):137-145.).

The use of sewage treatment effluent (STE) can provide better leaf quality due to nutrient supply to crops (Matos et al., 2013Matos AT de, Silva D de F, Lo Monaco PAV, Pereira OG (2013) Produtividade e composição química do capim-tifton 85 submetido a diferentes taxas de aplicação do percolato de resíduos sólidos urbano. Engenharia Agrícola 33(1):188-200.). The nitrogen, a common element in STE, is one of the inputs that most influences the increase in productivity and the quality of the product harvested. This evidence was verified by Povh et al. (2008Povh FP, Molin JP, Gimenez LM, Pauletti V, Molin R, Salvi JV (2008) Comportamento do NDVI obtido por sensor ótico ativo em cereais. Pesquisa Agropecuária Brasileira 43(8):1075-1083.), in which the nitrogen supply increased yield of wheat, triticale, barley and maize and increased the green pigmentation of the plants, resulting in a higher concentration of leaf chlorophyll and, consequently, higher NDVI values.

In this study, the linear regression models were obtained between normalized difference vegetation index (NDVI), obtained by terrestrial optical sensor, with the productivity, foliar nitrogen (N) and crude protein (CP) content of biomass in the Brachiaria brizantha cv. Marandu fertilized with doses of sewage treatment effluent (STE).

MATERIAL AND METHODS

Characterization of the study area

The experiment was conducted during the year 2014 at the Faculty of Agrarian and Veterinary Sciences (FCAV - UNESP), in Jaboticabal, SP, located around the geographic coordinates of 21°14’41.9” S and 48°16’25.2” W (Figure 1).

FIGURE 1
Location of the study area.

Effluent from the Dr. Adelson Taroco Sewage Treatment Station, located near the experimental area was used and the treatment system consists initially of mechanical railing (preliminary phase), followed by a mixed system (anaerobic and aerobic) composed of an upflow anaerobic digester (UFAD) (primary phase) and finalized with post treatment by three parallel facultative ponds (secondary phase). This station collects sewage from the city of Jaboticabal, whose municipality has 71,662 inhabitants, territorial area of 707 km² and population density of 101.4 inhabitants per km² (IBGE, 2010IBGE - Instituto Brasileiro de Geografia e Estatística. Censo demográfico 2010. Brasília, IBGE. Available: www.ibge.org.br. Accessed: Out 23, 2014.
www.ibge.org.br... ) and has an average flow of 202 L per inhabitant per day.

The climate of the region is subtropical humid, Aw, according to the classification of Köppen (Alvares et al. 2013Alvares CA, Stape JL, Sentelhas PC, De Moraes G, Leonardo J, Sparovek G (2013) Köppen's climate classification map for Brazil. Meteorologische Zeitschrift 22(6):711-728.), with dry and mild winter and hot and rainy summer (Table 1). The rainfall is concentrated in the hottest months of the year, with an occurrence of about 80% in the period from October to March.

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TABLE 1
Mean climate conditions of Jaboticabal, SP, during the experimental period, in 2014.

The soil is classified as Eutrophic Red Latosol (Santos et al., 2013Santos HG dos, Jacomine PKT, Anjos, LHC dos, Oliveira VA de, Lumbreras JF, Coelho MR, Almeida JA de, Cunha TJF, Oliveira JB de (2013) Sistema brasileiro de classificação de solos. Brasília: Embrapa, 3ed. 353p.), very clayey texture (> 50%), high iron content and good fertility. Sampling of soil between the treatments (E1-E5) from 0 to 100 cm was carried out at the implantation of the experiment (Table 2).

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TABLE 2
Average chemical characteristics (treatments E1 - E5) of the soil in the experimental area at the depths of 0-100 cm, in November of 2012.

Experimental design and management used

A conventional sprinkler system was used with three parallel lines of sprinklers spaced 12 m apart in order to apply a uniform irrigation level, but gradual of STE (Figure 2). The treatments consisted of five doses of STE, distributed in four replications, with the following average fractions of water effluent: E5 = 1.0; E4 = 0.87; E3 = 0.60; E2 = 0.31 and E1 = 0.11.

FIGURE 2
Experimental schemes with treatments (E5 = 1.0; E4 = 0.87; E3 = 0.60; E2 = 0.31 and E1 = 0.l1) distributed in strips with a gradual distribution of STE in water.

The control of the fertirrigation followed the hydric or nutritional necessity of the culture, adopting the criterion of greater value in the interval of 28 days. The nutritional demand was performed according to Vilela et al. (1998Vilela L, Soares WV, Sousa DMG de, Macedo MCM (1998) Calagem e adubação para pastagens na região do cerrado. Planaltina, Embrapa Cerrado. 16p. (Circular Técnico, 37).), applying 15; 3.5 and 18 kg ha^-1 of N, P₂O₅ and K₂O, respectively, per ton of forage dry matter of Brachiaria produced in cycles of 28 days. The water demand supplied by irrigations twice a week, with equal levels to the reference evapotranspiration calculated by the FAO 56 method, taking the E3 treatment as reference.

The irrigation levels were 750, 661 and 842 mm in summer, autumn-winter and spring, respectively, allowing the application of 1,132 kg ha^-1 of nitrogen in the E5 treatment (Table 3). The water excess, especially in the rainy season, was a consequence of the nutritional criterion. The others nutrients were applied by STE in the following amounts (kg ha^-1) in treatment E5: P = 21, K = 463, Ca = 358, Mg = 108, Na = 1,428, SO₄^- = 421, Fe = 17, Mn = 2 and Zn = 3. The others treatments received amounts proportional to the application fractions defined in each treatment.

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TABLE 3
The nitrogen fertilization via sewage treated effluent (kg ha^-1) applied according to treatment during Summer, Autumn-Winter and Spring, in 2014^* * E5 = 1.0; E4 = 0.87; E3 = 0.60; E2 = 0.31 and E1 = 0.11 are sewage effluent doses in water. .

Due to the low concentration of phosphorus and potassium in the effluent, mineral supplementation was necessary, applying in the summer, autumn-winter and spring 136 and 696 kg ha^-1 of P₂O₅ and K₂O, respectively. The fertilizations were staggered according to the needs of the crop in each cutting cycle (28 days), with 13 fertilizations being realized in the year 2014.

The production of dry biomass was determined with the help of a metal frame (0.25 m²) by taking samples randomly in three replicates in the plot and four per treatment. The cutting height was 15 cm. The forage harvested was homogenized and then, a sample was then taken to be weighed and taken to the greenhouse with forced air circulation, determining the dried biomass at 65°C until constant weight (Lacerda et al., 2009Lacerda MJR, Freitas KR, Silva JW (2009) Determinação da matéria seca de forrageiras pelos métodos de micro-ondas e convencional. Bioscience Journal 25(3):185-190.).

The qualitative evaluations of the forage were based on the crude protein (CP) and the nitrogen (N) content of the leaf, being obtained in the respective seasons of the year.

Data collection and analysis

The active ground sensor used was the GreenSeeker HandHeld™, portable. The data collection with the GreenSeeker was done manually, with passage over the canopy of the forage, always evaluating the center of each plot. The monitoring was always done one day before the beginning of the harvest. The GreenSeeker calibration was always performed on soil without vegetation.

The readings in all treatments (Figure 1) were obtained from an average height of 0.8 to 1.0 m between the sensor and the target (Grohs et al., 2011Grohs DS, Bredemeier C, Poletto N, Mundstock CM (2011) Validação de modelo para predição do potencial produtivo de trigo com sensor óptico ativo. Pesquisa Agropecuária Brasileira 46(4):446-449.) and performed at 7.2 m² (12 m of linear displacement on the experimental unit, multiplied by the useful width of 0.6 m captured by the sensor), generating an average value of 20 to 30 measurements of NDVI performed per treatment.

Rouse et al. (1973Rouse JW, Haas RH, Schell JA, Deering DW (1973) Monitoring vegetation systems in the great plains with ERTS. In: Earth Resources Tecnology Satellite Symposium. Washington, NASA, Proceedings…) proposed the NDVI (Equation 1) to quantify the growth of vegetation and accumulated biomass, with values ranging from −1 and +1, and the higher the NDVI value, the greater the development vigor of the crop and the more distant form zero will be the value of NDVI.

(1)

N D V I = \frac{(ρ n i r - ρ r)}{(ρ n i r + ρ r)}

in which,

NDVI: normalized difference vegetation index,

ρnir: near infrared reflectance (770 nm), and

ρr: red reflectance (650 nm).

An electronic spreadsheet for data editing and graphing was used and the BioEstat v.5.3 software was also used to determine the linear correlation model between the variables, as well as the calculation of the coefficient of determination (R²), the Pearson linear correlation coefficient (r) and analysis of the regression residuals, as well as the F value for the regression. In the analysis of residues, the value of 1σ for the detection interval of the outliers.

For the interpretation of the linear correlation between variables, the classification proposed by Callegari-Jacques (2003Callegari-Jacques SM (2003) Bioestatística: princípios e aplicações. Porto Alegre, Artemed. 255p.) was adopted. In order to represent the spatial distribution of the NDVI values, the software SPRING v.5.3 was used.

RESULTS AND DISCUSSION

A total of 13 harvestings were taken in 2014, with an increase in NDVI values in response to the increase of nitrogen doses via STE. To illustrate this effect, Figure 3 shows the spatial distribution of NDVI in the study area, obtained in the harvest performed on 04/29/2014. Note that in the central region of the study area, higher values of NDVI (dark green areas) were observed, which coincide approximately with the region of higher STE levels. Similar results were obtained in the other harvests in 2014, with decreasing mean values as a function of decreasing STE application (Figure 4).

FIGURE 3
Spatial distribution of Normalized Difference Vegetation Index (NDVI) in a experimental area of Brachiaria brizantha fertigated with doses of sewage treated effluent (E5 = 1.0; E4 = 0.87; E3 = 0.60; E2 = 0.31 and E1 = 0.11) before the harvest on 04/29/2014.

FIGURE 4
Box-plot for Normalized Difference Vegetation Index (NDVI) in Brachiaria brizantha fertigated with doses of sewage treated effluent (E5 = 1.0; E4 = 0.87; E3 = 0.60; E2 = 0.31 and E1 = 0.11) during 2014.

In the residue analysis, the linear regressions presented only a value outside the range, denoting a low presence of outliers. The F values were all significant, indicating that the variables correlated with the NDVI values increased as the NDVI value increased.

There was a high linear correlation (r>0.9570) between the nitrogen and NDVI doses (Figure 5). In addition, there was a greater effect on the reflectance indices in the autumn and winter. This fact occurs due to water deficit in the same period, resulting in gradual nitrogen uptake via STE by the forage.

FIGURE 5
Normalized Difference of Vegetation Index in function of N doses applied via sewage treated effluent, and respective coefficients of correlation, for: a) season of the year (S = Summer, AW = Autumn-Winter and Sp = Spring) and b) annual in 2014.

In autumn-winter and spring, nitrogen doses of less than 200 kg ha^-1 by season of the year caused less development of the forage causing many flaws and, in this way, there was a direct influence on the area of exposed soil or dry biomass, resulting in lower NDVI values. In the summer, the climatic factors favored the rapid development of the crop, and it was possible to determine, with higher quality, and without the interference of areas with exposed soil, the canopy reflectance variability.

Similar linear correlation results (r>0.90) were obtained by Povh et al. (2008Povh FP, Molin JP, Gimenez LM, Pauletti V, Molin R, Salvi JV (2008) Comportamento do NDVI obtido por sensor ótico ativo em cereais. Pesquisa Agropecuária Brasileira 43(8):1075-1083.), evaluating the relations of the readings performed with an active sensor with N doses, nitrogen concentration in the leaves, dry biomass production and grain yield in the wheat, triticale, barley and corn crops. Zerbato et al. (2016Zerbato C, Rosalen DL, Furlani CEA, Deghaid J, Voltarelli MA (2016) Agronomic characteristics associated with the normalized difference vegetation index (NDVI) in the peanut crop. Australian Journal of Crop Science 10(5):758-764.), evaluating the linear correlation between NDVI and peanut yield in the production of green and dry peanut mass, obtained positive linear regression and determination coefficients of 0.3161 and 0.2761, respectively. The low NDVI values were attributed to naked soil exposure between rows of plants.

There was a high linear correlation (r>0.9256) between NDVI and dry biomass, demonstrating that the method can be used to estimate this variable (Figure 6). Povh et al. (2008Povh FP, Molin JP, Gimenez LM, Pauletti V, Molin R, Salvi JV (2008) Comportamento do NDVI obtido por sensor ótico ativo em cereais. Pesquisa Agropecuária Brasileira 43(8):1075-1083.) evaluated the determination coefficient between NDVI and nitrogen doses in wheat crop, they showed that the NDVI and dry biomass production at the end of the seasoning were satisfactory, with a determination coefficient varying from 83% to 99%.

FIGURE 6
Dry biomass in function of the normalized difference vegetation index by season (a) and annual in 2014 (b).

The successive applications and in graded doses of STE resulted in better leaf quality as compared to nitrogen, correlating with higher NDVI indexes (Figure 7). It was obtained high linear correlation (r> 0.8939) between NDVI and leaf nitrogen.

FIGURE 7
Leaf nitrogen in function of the normalized difference vegetation index by season (a) and annual (b).

The lowest leaf nitrogen content in spring and summer and, consequently, NDVI indexes, is caused by the higher foliar expansion velocity in the period, providing dilution of foliar nutrients (Silva et al., 2012Silva JGD, Matos AT, Borges AC, Previero CA (2012) Composição químico-bromatológica e produtividade do capim-mombaça cultivado em diferentes lâminas de efluente do tratamento primário de esgoto sanitário. Revista Ceres 59(5):606-613.). Motomiya et al. (2009Motomiya AV de A, Molin JP, Chiavegato EJ (2009) Utilização de sensor ótico ativo para detectar deficiência foliar de nitrogênio em algodoeiro. Revista Brasileira de Engenharia Agrícola e Ambiental 13(2):137-145.), evaluating foliar nitrogen deficiency in the cotton crop using active terrestrial sensor, obtained an increase in NDVI rates with the increase of the applied nitrogen rates, being an efficient tool for the detection of foliar nitrogen deficiency.

The availability of nitrogen to the forages favored the best nutritional quality of the forage, as a consequence of the increase of more digestible compounds, there being a gradual effect on the crude protein content and consequently higher values of NDVI with the application of nitrogen via STE. A high linear correlation coefficient (r>0.8421) was obtained between NDVI and the forage crude protein content (Figure 8).

FIGURE 8
Crude protein in function of the normalized difference vegetation index by season (a) and annual in 2014(b).

CONCLUSIONS

The successive application of treated sewage effluent resulted in higher productivity in dry biomass and better leaf quality (higher levels of nitrogen and crude protein).

The productivity, the quality and the vegetation indices increased due to the application in gradual doses of applied sewage treatment effluent.

The levels of nitrogen and crude protein and the production of dry biomass showed a close correlation with the normalized vegetation index, demonstrating that the method can be used to estimate the yield and quality of the forage of Brachiaria brizantha cv. Marandu.

ACKNOWLEDGEMENTS

We would like to thank the Foundation for Research Support of São Paulo (FAPESP) for the grant: 2012/12923-3 and the Scholarship: 2013/00362 and also to the Autonomous Service of Water and Sewage of Jaboticabal - SAAEJ for the availability of effluents.

REFERENCES

Alvares CA, Stape JL, Sentelhas PC, De Moraes G, Leonardo J, Sparovek G (2013) Köppen's climate classification map for Brazil. Meteorologische Zeitschrift 22(6):711-728.
Bredemeier C, Variani C, Almeida D, Rosa AT (2013) Estimativa do potencial produtivo em trigo utilizando sensor óptico ativo para adubação nitrogenada em taxa variável. Ciência Rural 43(7): 1147-1154.
Callegari-Jacques SM (2003) Bioestatística: princípios e aplicações. Porto Alegre, Artemed. 255p.
Galvanin EA dos S, Neves SMA da S, Cruz CBM, Neves RJ, Jesus PHH de, Kreitlow JP (2014) Avaliação dos índices de vegetação NDVI, SR e TVI na discriminação fitofisionomias dos ambientes do Pantanal de Cáceres/MT. Ciência Florestal 24(3):707-715.
Grohs DS, Bredemeier C, Poletto N, Mundstock CM (2011) Validação de modelo para predição do potencial produtivo de trigo com sensor óptico ativo. Pesquisa Agropecuária Brasileira 46(4):446-449.
IBGE - Instituto Brasileiro de Geografia e Estatística. Censo demográfico 2010. Brasília, IBGE. Available: www.ibge.org.br. Accessed: Out 23, 2014.
» www.ibge.org.br
Lacerda MJR, Freitas KR, Silva JW (2009) Determinação da matéria seca de forrageiras pelos métodos de micro-ondas e convencional. Bioscience Journal 25(3):185-190.
Lissner JB, Guasselli LA (2013) Variação do índice de vegetação por diferença normalizada na lagoa Itapeva, litoral norte do Rio Grande do Sul, Brasil, a partir de análise de séries temporais. Sociologia & Natureza 25(2):427-440.
Matos AT de, Silva D de F, Lo Monaco PAV, Pereira OG (2013) Produtividade e composição química do capim-tifton 85 submetido a diferentes taxas de aplicação do percolato de resíduos sólidos urbano. Engenharia Agrícola 33(1):188-200.
Merotto Júnior A, Bredemeier C, Vidal RA, Goulart ICGR, Bortoli ED, Anderson NL (2012) Reflectance indices as a diagnostic tool for weed control performed by multipurpose equipment in precision agriculture. Planta Daninha 30(2):437-447.
Meteorological Station - UNESP. Available: http://www.fcav.unesp.br/#!/estacao-agroclimatologica/ Accessed: Feb 5, 2015.
» http://www.fcav.unesp.br/#!/estacao-agroclimatologica/
Motomiya AV de A, Molin JP, Chiavegato EJ (2009) Utilização de sensor ótico ativo para detectar deficiência foliar de nitrogênio em algodoeiro. Revista Brasileira de Engenharia Agrícola e Ambiental 13(2):137-145.
Povh FP, Molin JP, Gimenez LM, Pauletti V, Molin R, Salvi JV (2008) Comportamento do NDVI obtido por sensor ótico ativo em cereais. Pesquisa Agropecuária Brasileira 43(8):1075-1083.
Rouse JW, Haas RH, Schell JA, Deering DW (1973) Monitoring vegetation systems in the great plains with ERTS. In: Earth Resources Tecnology Satellite Symposium. Washington, NASA, Proceedings…
Silva JGD, Matos AT, Borges AC, Previero CA (2012) Composição químico-bromatológica e produtividade do capim-mombaça cultivado em diferentes lâminas de efluente do tratamento primário de esgoto sanitário. Revista Ceres 59(5):606-613.
Santos HG dos, Jacomine PKT, Anjos, LHC dos, Oliveira VA de, Lumbreras JF, Coelho MR, Almeida JA de, Cunha TJF, Oliveira JB de (2013) Sistema brasileiro de classificação de solos. Brasília: Embrapa, 3ed. 353p.
Vilela L, Soares WV, Sousa DMG de, Macedo MCM (1998) Calagem e adubação para pastagens na região do cerrado. Planaltina, Embrapa Cerrado. 16p. (Circular Técnico, 37).
Zanzarini FV, Pissarra TCT, Brandão FJC, Teixeira DB (2013) Correlação espacial do índice de vegetação (NDVI) de imagem Landsat/ETM+ com atributos do solo. Revista Brasileira de Engenharia Agrícola e Ambiental 17(6):608-614.
Zerbato C, Rosalen DL, Furlani CEA, Deghaid J, Voltarelli MA (2016) Agronomic characteristics associated with the normalized difference vegetation index (NDVI) in the peanut crop. Australian Journal of Crop Science 10(5):758-764.

Publication Dates

Publication in this collection
Nov-Dec 2017

History

Received
08 Sept 2015
Accepted
06 Sept 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] Alvares CA, Stape JL, Sentelhas PC, De Moraes G, Leonardo J, Sparovek G (2013) Köppen's climate classification map for Brazil. Meteorologische Zeitschrift 22(6):711-728.

[2] Bredemeier C, Variani C, Almeida D, Rosa AT (2013) Estimativa do potencial produtivo em trigo utilizando sensor óptico ativo para adubação nitrogenada em taxa variável. Ciência Rural 43(7): 1147-1154.

[3] Callegari-Jacques SM (2003) Bioestatística: princípios e aplicações. Porto Alegre, Artemed. 255p.

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Seasons	Temperature (°C)			Humidity (%)	Precipitation (mm)	ETo^* * ETo = Reference evapotranspiration. (mm)
Seasons	Minimum	Maximum	Average	Humidity (%)	Precipitation (mm)	ETo^* * ETo = Reference evapotranspiration. (mm)
Summer	15.8	35.9	24.8	68.8	348	584
Autumn-Winter	8.4	33.7	20.8	62.8	102	460
Spring	11.5	39.8	24.2	55.9	271	572

Season	Treated
Season	E5	E4	E3	E2	E1
Summer	346	304	210	107	38
Autumn-Winter	366	321	222	113	40
Spring	420	369	255	130	46
Total	1.132	994	687	350	124

pH	OM	K	Ca	Mg	H+Al	SB	T	Al	P	B	Cu	Fe	Mn	Zn	S	V
	g dm^-3	------- mmoldm^-3-----------							------- mg dm^-3------------							%
5.5	20	4	25	12	27	40	68	0	53	0.3	3.4	12	18	2	24	57