PEDOFUNCTIONS APPLIED TO THE LEAST LIMITING WATER RANGE TO ESTIMATE SOIL WATER CONTENT AT SPECIFIC POTENTIALS

Tavanti, Renan F. R.; Freddi, Onã da S.; Tavanti, Tauan R.; Rigotti, Adriel; Magalhães, Wellington de A.

doi:10.1590/1809-4430-Eng.Agric.v39n4p444-456/2019

ABSTRACT

The least limiting water range (LLWR) is a soil physical quality indicator that receives much attention. It has been criticized and put to the test regarding mathematical models that compose it since they describe the behavior of soil physical attributes in a simplified way. This study aimed to assess the efficiency of some pedofunctions proposed in the literature and artificial neural networks on the accuracy in predicting soil water retention at potentials equivalent to field capacity (θFC) and permanent wilting point (θPWP). In other words, to apply the best models to LLWR of two soil types (Oxisol and Ultisol) and verify changes in their structure. The results indicated that pedofunctions using sand, silt, clay, bulk density, and soil organic matter contents are more efficient in estimating θFC and θPWP. However, the use of multiple linear regression models to predict θFC values below 0.20 m3 m−3 may present a slight tendency to overestimate it, which is not observed in the neural networks. As in R2, equations from neural networks were more efficient in estimating θFC and θPWP. Pedofunctions used to calculate LLWR differ in the establishment of the critical soil bulk density, exposing the limitations of the model.

Soil physics; soil physical quality indicator; available water; pedotransfer functions; artificial neural networks

INTRODUCTION

Soil physical quality cannot be measured directly, but it is assessed through attributes such as porosity, bulk density, penetration resistance, and water content available to plants (Guimarães et al., 2013Guimarães RM, Tormena CA, Blainski É, Fidalski, J (2013) Intervalo hídrico ótimo para avaliação da degradação física do solo. Revista Brasileira de Ciência do Solo 37(6):1512-1521. DOI: http://dx.doi.org/10.1590/S0100-06832013000600008
http://dx.doi.org/10.1590/S0100-06832013... ). Soil physical quality was better investigated by Letey (1985)Letey J (1985) Relationship between soil physical properties and crop productions. In: Stewart BA (eds). Advances in Soil Science. Springer, p277-294., who proposed the concept of 'non-limiting water range', which integrates the relationships between soil attributes and water content available to plants. Silva et al. (1994)Silva AP, Kay BD, Perfect E (1994) Characterization of the Least Limiting Water Range of Soils. Soil Science Society of America Journal 58(6):1775-1781. DOI: http://dx.doi.org/10.2136/sssaj1994.03615995005800060028x
http://dx.doi.org/10.2136/sssaj1994.0361... improved this concept when assembling mathematical models for estimating soil moisture in the field capacity, permanent wilting point, air-filled porosity, and soil penetration resistance, originating a soil structural quality indicator known as least limiting water range. Tormena et al. (1998)Tormena CA, Silva AP, Libardi PL (1998) Caracterização do intervalo hídrico ótimo de um latossolo roxo sob plantio direto. Revista Brasileira de Ciência do Solo 22(4):573-581. DOI: http://dx.doi.org/10.1590/S0100-06831998000400002
http://dx.doi.org/10.1590/S0100-06831998... later introduced this indicator in Brazil as Intervalo Hídrico Ótimo.

The least limiting water range (LLWR) has been received much attention in Brazil and applied in several studies. Among them, Freddi et al. (2009)Freddi OS, Centurion JF, Duarte AP, Peres FSC (2009) Compactação do solo e produção de cultivares de milho em Latossolo Vermelho. II - Intervalo hídrico ótimo e sistema radicular. Revista Brasileira de Ciência do Solo 33(4):805-818. assessed compaction levels of an Oxisol and its physical quality reduction processes, as well as yield reduction of two maize hybrids as a response to compaction. The authors verified that, at certain levels of soil bulk density, water content should be above the field capacity to avoid limitations due to soil penetration resistance and meet the water requirements of hybrids. In this case, the intense machinery traffic led to soil structural degradation. In addition, the authors proposed soil decompaction actions when bulk density reached 1.46 Mg m⁻³, considered as critical in LLWR. Betioli Junior et al. (2012) analyzed an Oxisol after 30 years of no-tillage and observed a decrease in LLWR due to an increase in bulk density, regardless of the used critical soil penetration resistance, which was 2 MPa.

Despite the studies that consolidate LLWR as a soil physical quality indicator, it has been criticized and its validity put to the test by several authors (Gubiani et al., 2013Gubiani PI, Reichert JM, Reinert DJ (2013) Indicadores hídrico-mecânicos de compactação do solo e crescimento de plantas. Revista Brasileira de Ciência do Solo 37(1):1-10. DOI: https://doi.org/10.1590/S0100-06832013000100001
https://doi.org/10.1590/S0100-0683201300... , Jong Van Lier & Gubiani, 2015Jong Van Lier QD, Gubiani PI (2015) Beyond the “least limiting water range”: Rethinking soil physics research in Brazil. Revista Brasileira de Ciência do Solo 39(4):925-939. DOI: http://dx.doi.org/10.1590/01000683rbcs20140596
http://dx.doi.org/10.1590/01000683rbcs20... ; Cecagno et al., 2016)Cecagno D, Andrade SEVG de, Anghinoni I, Kunrath TR, Martins AP, Reichert JM, Gubiani PI, Balerini F, Fink JR, Faccio Carvalho PC de (2016) Least limiting water range and soybean yield in a long-term, no-till, integrated crop-livestock system under different grazing intensities. Soil and Tillage Research 156:54-62. DOI: https://doi.org/10.1016/j.still.2015.10.005
https://doi.org/10.1016/j.still.2015.10.... . These studies have questioned the efficiency of the linear mathematical model used to determine LLWR since the relationships between soil attributes are not linear and describe them in a relatively simple way is still one of the challenges of soil physics (Klein et al., 2016Klein VA, Graebin GJ, Bortolanza DR, Daubermann AG (2016) Spatial variability of the least limiting water range of soils under a no-tillage system. Pesquisa Agropecuária Brasileira 51(11):1890-1898. DOI: http://dx.doi.org/10.1590/s0100-204x2016001100011
http://dx.doi.org/10.1590/s0100-204x2016... ; Jong Van Lier & Gubiani, 2015)Jong Van Lier QD, Gubiani PI (2015) Beyond the “least limiting water range”: Rethinking soil physics research in Brazil. Revista Brasileira de Ciência do Solo 39(4):925-939. DOI: http://dx.doi.org/10.1590/01000683rbcs20140596
http://dx.doi.org/10.1590/01000683rbcs20... .

Over the years, researchers have been proposing mathematical models to estimate soil water retention using attributes that correlate directly with one another, such as clay, silt, sand, soil organic matter content, and bulk density (Barros et al., 2013Barros AHC, Jong Van Lier QD, Maia ADHN, Scarpare FV (2013) Pedotransfer functions to estimate water retention parameters of soils in northeastern Brazil. Revista Brasileira de Ciência do Solo 37(2):379-391. DOI: http://dx.doi.org/10.1590/S0100-06832013000200009
http://dx.doi.org/10.1590/S0100-06832013... ; Medrado & Lima, 2014Medrado E, Lima JE (2014) Development of pedotransfer functions for estimating water retention curve for tropical soils of the Brazilian savanna. Geoderma Regional 1:59-66. DOI: https://doi.org/10.1016/j.geodrs.2014.08.003
https://doi.org/10.1016/j.geodrs.2014.08... ; Medeiros et al., 2014)Medeiros JC, Cooper M, Dalla Rosa J, Grimaldi M, Coquet Y (2014) Assessment of pedotransfer functions for estimating soil water retention curves for the amazon region. Revista Brasileira de Ciência do Solo 38(3):730-743. DOI: http://dx.doi.org/10.1590/S0100-06832014000300005
http://dx.doi.org/10.1590/S0100-06832014... . These models are also known as pedofunctions or pedotransfer functions (PTF) and can be applied to LLWR.

Most models currently available were developed for temperate regions (Gupta & Larson, 1979Gupta S, Larson WE (1979) Estimating soil water retention characteristics from particle size distribution, organic matter percent, and bulk density. Water resources research 15(6):1633-1635.; Rawls et al., 1982Rawls WJ, Brakensiek DL, Saxtonn KE (1982) Estimation of soil water properties. Transactions of the ASAE 25(5):1316-1320.; Saxton et al., 1986)Saxton KE, Rawls W, Romberger JS, Papendick RI (1986) Estimating generalized soil-water characteristics from texture. Soil Science Society of America Journal 50(4):1031-1036., where edaphoclimatic properties and soil mineralogical characteristics are different from tropical regions. For Brazil, some models have already been established (Reichert et al., 2009, Reichert JM, Albuquerque JA, Kaiser DR, Reinert DJ, Urach FL, Carlesso R (2009) Estimation of water retention and availability in soils of Rio Grande do Sul. Revista Brasileira de Ciência do Solo 33(6):1547-1560. DOI: http://dx.doi.org/10.1590/S0100-06832009000600004
http://dx.doi.org/10.1590/S0100-06832009... , Barros et al., 2013, Barros AHC, Jong Van Lier QD, Maia ADHN, Scarpare FV (2013) Pedotransfer functions to estimate water retention parameters of soils in northeastern Brazil. Revista Brasileira de Ciência do Solo 37(2):379-391. DOI: http://dx.doi.org/10.1590/S0100-06832013000200009
http://dx.doi.org/10.1590/S0100-06832013... , Medeiros et al., 2014)Medeiros JC, Cooper M, Dalla Rosa J, Grimaldi M, Coquet Y (2014) Assessment of pedotransfer functions for estimating soil water retention curves for the amazon region. Revista Brasileira de Ciência do Solo 38(3):730-743. DOI: http://dx.doi.org/10.1590/S0100-06832014000300005
http://dx.doi.org/10.1590/S0100-06832014... , but their validity in soils submitted to agricultural management different from those of the original database may make them unsuitable for use.

In the case of complex systems, mathematical modeling techniques may be more efficient in predicting soil water content, such as artificial neural networks (ANN) (Jana et al., 2012Jana RB, Mohanty BP, Sheng Z (2012) Upscaling soil hydraulic parameters in the Picacho Mountain region using Bayesian neural networks. Transactions of the ASABE 55(2):463-473. DOI: http://dx.doi.org/10.13031/2013.41396
http://dx.doi.org/10.13031/2013.41396... ; Jana & Mohanty, 2012Jana RB, Mohanty BP (2012) A comparative study of multiple approaches to soil hydraulic parameter scaling applied at the hill-slope scale. Water Resources Research 48(2):1-16. DOI: http://dx.doi.org/10.1029/2010WR010185
http://dx.doi.org/10.1029/2010WR010185... ; Nguyen et al., 2017)Nguyen PM, Haghverdi A, De Pue J, Botula YD, Le KV, Waegeman W, Cornelis WM (2017) Comparison of statistical regression and data-mining techniques in estimating soil water retention of tropical delta soils. Biosystems Engineering 153:12-27. DOI: https://doi.org/10.1016/j.biosystemseng.2016.10.013
https://doi.org/10.1016/j.biosystemseng.... . ANNs have shown high performance due to factors such as robust and parallel distributed structure (layers of neurons), generalization and learning efficiency that make them capable of solving complex problems (Leal et al., 2015)Leal AJF, Pereira Miguel E, Rojo Baio FH, Neves DC, Leal UAS (2015) Redes neurais artificiais na predição da produtividade de milho e definição de sítios de manejo diferenciado por meio de atributos do solo. Bragantia 74(4):436-444. DOI: http://dx.doi.org/10.1590/1678-4499.0140
http://dx.doi.org/10.1590/1678-4499.0140... . In addition, they are tolerant to outliers, in which they are normalized in the layers of neurons, allowing the modeling of distinct variables and their non-linear relationships. This computational technique simulates the neural structure of intelligent organisms, which acquire knowledge through the experience and acquisition of punctual information.

As an example of the application of ANNs in agricultural research, Leal et al. (2015)Leal AJF, Pereira Miguel E, Rojo Baio FH, Neves DC, Leal UAS (2015) Redes neurais artificiais na predição da produtividade de milho e definição de sítios de manejo diferenciado por meio de atributos do solo. Bragantia 74(4):436-444. DOI: http://dx.doi.org/10.1590/1678-4499.0140
http://dx.doi.org/10.1590/1678-4499.0140... reported their efficiency to estimate maize grain yield through soil attributes such as particle size distribution, soil organic matter content, cation exchange capacity, and base saturation. Ebrahimi et al. (2019)Ebrahimi M, Sarikhani MR, Sinegani AAS, Ahmadi A, Keesstra S (2019) Estimating the soil respiration under different land uses using artificial neural network and linear regression models. Catena 174(3):371-382. DOI: https://doi.org/10.1016/j.catena.2018.11.035
https://doi.org/10.1016/j.catena.2018.11... compared the efficiency of mathematical models in the estimates of the biological parameters of soil microbiota from their attributes and verified that ANN was more efficient than multiple linear regressions.

Based on these observations, this study aimed to assess the efficiency of some PTFs proposed in the literature and ANNs on the accuracy in predicting soil water retention at potentials equivalent to field capacity (θFC) and permanent wilting point (θPWP). In other words, to apply the best models to LLWR of two soil types (Oxisol and Ultisol) and verify changes in their structure.

MATERIAL AND METHODS

The data were obtained from two representative soils of the Mato Grosso State, Brazil, classified according to the Brazilian Soil Classification System (Embrapa, 2013) as a Dystrophic Red-Yellow Latosol and Dystrophic Red-Yellow Argisol, located at the geographical coordinates 59°11′59.0″ W and 12°35′49″ S and 56°01′16.8″ W and 9°54′04″ S, with an altitude of 350 and 283 m, respectively. According to the U.S. Department of Agriculture (Soil Survey Staff, 2014Soil Survey Staff (2014) Keys to soil taxonomy. Washington DC, United States Department of Agriculture, 12th ed. 360p.), the soils are classified as Oxisol and Ultisol, respectively. We will use in this study the USDA classification for standardization purposes.

These soils were sampled from October 2015 to August 2016. The Oxisol was under integrated crop-livestock systems, with an intense crop rotation consisting of soybean as main crop and maize as the second crop intercropped with forage species of the genus Urochloa. In some situations, millet or sorghum was chosen instead of maize as the second crop. The forage crops subsidized livestock farming during the dry season until the beginning of rains. The mean annual stocking rate was 2 animals of 450 kg ha⁻¹ year⁻¹.

The Ultisol was under Brachiaria brizantha cv. Marandu for more than ten years managed for extensive livestock farming, which was not subjected to any soil tillage. The mean annual stocking rate was 1.5 animals of 450 kg ha⁻¹ year⁻¹.

Soil physical and chemical attributes were determined from 156 undisturbed and 30 disturbed soil samples. Disturbed soil samples were collected at depths of 0–0.10 and 0.10–0.20 m with a Dutch auger. Undisturbed soil samples were taken using stainless steel volumetric rings with 5 cm high × 5 cm in diameter (98.17 cm³) from trenches at depths of 0–0.10 and 0.10–0.20 m.

Disturbed soil samples were taken to the laboratory, air dried, and sieved in 200 mm diameter stainless steel mesh sieves. Thus, particle size distribution was determined by the pipette method and organic matter contents (OM) by potassium dichromate oxidation (Embrapa, 2011). Undisturbed soil samples were saturated with water in plastic trays and subjected to tensions of 0, 30, 60, and 100 hPa in a sandbox and 300, 600, 1000, 5000, and 15000 hPa in pressure chambers with a porous plate. After each potential had reached moisture balance, the samples were weighed in order to find the water content. Subsequently, they were subjected to penetration resistance (PR), determined by a bench electronic penetrometer. The penetrometer had the following characteristics: load cell of 20 kg, penetration pin of 3 mm with 4 mm tip in a cone shape with 30° angle, and tip base area of 7.06 mm². The constant penetration rate was 10 mm min⁻¹, with two replications per sample, totaling 180 readings per replication. Therefore, the PR data taken from the first centimeter at the top and bottom of the rings were discarded. Thus, each microprofile consisted of PR readings recorded along a vertical transect of 3 cm, acquired from 1 to 4 cm deep, within a core of 5 cm of soil height, in accordance with the representative elementary volume theory. The PR value of each soil sample was obtained from the overall mean of records.

Subsequently, the undisturbed soil samples were oven-dried at 105 °C for 24 hours. The total porosity (TP), bulk density (BD), and soil water content at each tension were calculated (Embrapa, 2011).

For LLWR construction, the model proposed by Busscher (1990)Busscher WJ (1990) Adjustment of flat-tipped penetrometer resistance data to a common water content. Transactions of the ASAE 33(2):519-0524. was used to build the PR curve. The water content in which soil penetration resistance is limiting to root growth was obtained by [eq. (1)]:

⊖ PR = {(\frac{{PR}_{c}}{\exp^{β 1} \times ({BD}^{β 2})})}^{\frac{1}{β 3}}

(1)

Where:

θPR is the volumetric soil water content in which PR reaches the critical value (m³ m⁻³);

BD is the soil bulk density (Mg m⁻³);

PRc is the critical PR value, and

β1, β2, and β3 are the adjustment parameters of the equation. The PRc value of 2 MPa proposed by Taylor et al. (1966)Taylor HM, Roberson GM, Parker Jr JJ (1966) Soil strength-root penetration relations for medium-to coarse-textured soil materials. Soil Science 102(1):18-22. was used.

The water content in which aeration porosity is 10%, i.e., air-filled capacity (θAFC), was found through [eq. (2)]:

⊖ AFC = TP - 0.1 (2)

(2)

Where:

TP is the total porosity (m³ m^-3).

For the other LLWR curves corresponding to θFC and θPWP, the pedofunctions proposed by several authors were used, as shown in Tables 1 and 2, respectively.

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TABLE 1
Source of pedotransfer functions used to estimate soil water content in the field capacity (θFC).

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TABLE 2
Source of pedotransfer functions used to estimate soil water content in the permanent wilting point (θPWP).

The multilayer perceptron ANN was also tested. For this, 75% of the data were used for ANN training and 25% for validation. The supervised learning was used with two sets of values, i.e., input and output values. Training

consisted of a parameter optimization problem (synaptic weights) to respond to the inputs as expected until the error between observed and estimated values generated by ANNs reached the desired minimum value, i.e., close to zero (Leal et al., 2015Leal AJF, Pereira Miguel E, Rojo Baio FH, Neves DC, Leal UAS (2015) Redes neurais artificiais na predição da produtividade de milho e definição de sítios de manejo diferenciado por meio de atributos do solo. Bragantia 74(4):436-444. DOI: http://dx.doi.org/10.1590/1678-4499.0140
http://dx.doi.org/10.1590/1678-4499.0140... ).

The ANNs consisted of entries (inputs) corresponding to the soil attributes sand (SD), silt (SIL), clay (CL), BD, and OM. Outputs (response variables) were the respective soil water contents equivalent to θFC and θPWP. We chose the composition of two hidden layers, one with seven neurons and other with five neurons, respectively. Thus, the ANN architecture could be described as 5-7-5-2 (Figure 1). The activation function used was the hyperbolic tangent, as described in [eq. (3)]:

FIGURE 1
Artificial neural network architecture (5-7-5-2) used to estimate θFC and θPWP in an Oxisol (A) and Ultisol (B). Circles with letter B indicate the biases assigned to each layer of neurons, and I, H, and O indicate input attributes, neurons, and outputs of θFC and θPWP, respectively.

TanH = \frac{\sinh (x)}{\cosh (x)} (3)

(3)

Where:

TanH is the hyperbolic tangent;

sinh is hyperbolic sine,

cosh is hyperbolic cosine.

The data were submitted to the Shapiro & Wilk normality test (p> 0.05) using the software R (R Development Core Team, 2015R Development Core Team (2015) A Language and Environment for Statistical Computing. R Foundation for Statistical Computing. Vienna, Austria. Available from http://www.R-project.org/.
http://www.R-project.org/... ). Outliers with values 2.5 times higher than the interquartile range were removed, respecting the limit of 10% of the total observations of each treatment (soil type). Subsequently, a descriptive analysis was performed by calculating the mean, median, minimum, and maximum, standard deviation, coefficient of variation (CV), skewness, and kurtosis. The proposed pedofunctions were adjusted for the respective data sets. The neuralnet package was accessed for ANN training following the previously described criteria for assembly of its structure, using the “plotnet” function for network plotting.

The highest coefficient of determination (R²) and lowest mean square error (MSE), root mean square error (RMSE), and mean absolute percentage error (MAPE) were used in order to compare the efficiency of pedofunctions in predicting values.

MSE = \frac{1}{n} Σ_{i = 1}^{n} {(e_{i} - m_{i})}^{2} (4)

(4)

RMSE = \sqrt{\frac{1}{n} Ʃ_{i = 1}^{n} {(e_{i} - m_{i})}^{2}} (5)

(5)

MAPE = \frac{Ʃ_{i = 1}^{n} (e_{i} - m_{i})}{Ʃ_{i = 1}^{n} m_{i}} \times 100 (6)

(6)

Where:

n is the number of sampling points;

e_i is the value estimated by the pedofunctions, and

m_i is the measured value (observed).

RESULTS AND DISCUSSION

Both soils showed a high BD, with mean values of 1.356 and 1.505 Mg m⁻³ for the Oxisol and Ultisol, respectively (Table 3). Variations of minimum and maximum values of 0.920 and 1.545 Mg m⁻³ for the Oxisol and 1.180 and 1.760 Mg m⁻³ for the Ultisol indicated the existence of potentially compacted sites and sites with a structure not affected by management systems. Based on DB for the construction of pedofunctions, this variability is desirable, as they perform estimates with a wide range of values under previously non-sampled conditions. According to Gomes (2000), the variability of the assessed attributes can be classified according to the magnitude of their coefficient of variation (CV), being considered low when CV is lower than 10%, medium when CV is between 10 and 20%, high when CV is between 20 and 30%, and very high when CV is higher than 30%. Thus, BD variability of the Oxisol was classified as medium, and that of the Ultisol was considered low (14.97 and 8.63%, respectively).

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TABLE 3
Descriptive analysis of soil physical and chemical attributes of an Oxisol and Ultisol at a depth of 0.00–0.10 m.1

The texture of both soils was classified as medium, but the Oxisol presented a higher clay content (Table 1). The range of CL values varied from 29.479 to 33.315 dag kg⁻¹ for the Oxisol and 9.700 to 39.500 dag kg⁻¹ for the Ultisol, justifying the CV values classified as low and high, respectively. Despite the low variability of clay content in the Oxisol, these values are supposed to be preponderant over the variation of soil water content at specific potentials, especially those related to permanent wilting point.

Regarding OM content, a mean value of 3.649 dag kg⁻¹ was observed for the Ultisol and 2.554 dag kg⁻¹ for the Oxisol (Table 3). The maximum values indicated the existence of sites with a high decomposition capacity and stability of organic residues (3.087 and 7.240 dag kg⁻¹). The highest OM variability was observed for the Ultisol (42.35%).

Soil water content at equivalent tensions θFC and θPWP presented mean values of 0.285 and 0.160 m³ m⁻³ for the Oxisol and 0.210 and 0.160 m³ m⁻³ for the Ultisol, respectively (Table 3). Despite the amplitude of CL contents, θPWP values of both soils were very close. Klein et al. (2013)Klein VA, Navarini LL, Klein C, Costa LO da, Barbosa EA, Steffler VA (2013) Propriedades físicas do solo e rendimento de grãos de trigo em função de manejo do solo e uso de bioestimulantes. Pesquisa Agropecuária Gaúcha 19(1):24-32. reported that θPWP is also related to intra-aggregate pores, with BD being the preponderant factor in the amount of cryptopores in soils. The structural units of aggregates are disrupted as BD increases, leading to an increase in textural pores, responsible for water retention at potentials lower than −15000 hPa. In addition, clay increases the specific surface area of the soil matrix, and capillarity and adsorption phenomena determine the matric potential, responsible for soil water retention (Létourneau et al., 2015Létourneau G, Caron J, Anderson L, Cormier J (2015) Matric potential-based irrigation management of field-grown strawberry: Effects on yield and water use efficiency. Agricultural Water Management 161:102-113. DOI: https://doi.org/10.1016/j.agwat.2015.07.005
https://doi.org/10.1016/j.agwat.2015.07.... ). Based on these observations, clay content and soil compaction (represented by BD) in these systems may have governed soil water retention conditions, especially in relation to potentials equivalent to θPWP.

The Shapiro & Wilk test confirmed the normal distribution for the attributes CL, SD, and θFC (Table 3). Although it was significant for the other attributes, indicating deviations from normality, the classifications were considered as distribution tending to normality since the mean values were close to the median.

Tables 1 and 2 show the pedofunctions used to estimate soil water contents at specific potentials, theoretically θFC and θPWP. Their respective coefficients of determination showed the quality of model adjustments, with R² higher than 0.90 for most cases and all of them significant at 1% probability. A moderate to high correlation was verified between the observed and estimated θFC data (R > 0.74), with a small tendency to overestimate values above 0.30 m³ m⁻³ and underestimate values below 0.20 m³ m⁻³ (Figure 2). Although the residuals of pedofunctions generated with soil data from Brazil (Arruda et al., 1987Arruda FB, Zullo Junior J, Oliveira JD (1987) Parâmetros de solo para o cálculo da água disponível com base na textura do solo. Revista Brasileira de Ciência do Solo 11:11-15.; van den Berg et al., 1987; Oliveira et al., 2002)Oliveira LB, Ribeiro MR, Jacomine PKT, Rodrigues JJV, Marques FA (2002) Funções de pedotransferência para predição da umidade retida a potenciais específicos em solos do estado de Pernambuco. Revista Brasileira de Ciência do Solo 26(2):315-322. DOI: http://dx.doi.org/10.1590/S0100-06832002000200004
http://dx.doi.org/10.1590/S0100-06832002... were higher when compared to the other models, they presented a good performance even without taking into account attributes inherent to edaphology and soil compaction (i.e., OM and BD).

FIGURE 2
Linear regressions between observed and estimated θFC values obtained from the proposed models.

Contrary to what was observed in this study, Bonilla & Cancino (2001)Bonilla M, Cancino V (2001) Estimación del contenido de humedad del suelo mediante el empleo de funciones de pedotransferência. Agricultura Técnica 61(3):326-338. DOI: http://dx.doi.org/10.4067/S0365-28072001000300008
http://dx.doi.org/10.4067/S0365-28072001... observed a low accuracy for Chilean soils. This limitation was overcome by working on a large database to allow a division of soils into more homogeneous classes. According to Reichert et al. (2009)Reichert JM, Albuquerque JA, Kaiser DR, Reinert DJ, Urach FL, Carlesso R (2009) Estimation of water retention and availability in soils of Rio Grande do Sul. Revista Brasileira de Ciência do Solo 33(6):1547-1560. DOI: http://dx.doi.org/10.1590/S0100-06832009000600004
http://dx.doi.org/10.1590/S0100-06832009... , point scattering is higher and water retention accuracy is lower when using pedofunctions generated from a database with characteristics that differ considerably from soils where the model is assessed. Pedofunctions will only efficiently express water retention of soils with genesis and mineralogy similar to that of the database that was generated (Mecke et al., 2002)Mecke M, Westman CJ, Ilvesniemi H (2002) Water retention capacity in coarse podzol profiles predicted from measured soil properties. Soil Science Society of America Journal 66(1):1-11. DOI: http://dx.doi.org/10.2136/sssaj2002.1000
http://dx.doi.org/10.2136/sssaj2002.1000... .

The estimates of θPWP presented lower point scattering and higher accuracy of models when compared to θFC (Figure 3). All tested functions were close to the 1:1 line on a 45° slope, except for the functions of Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326
http://dx.doi.org/10.13031/2013.13326... and Silva et al. (1994)Silva AP, Kay BD, Perfect E (1994) Characterization of the Least Limiting Water Range of Soils. Soil Science Society of America Journal 58(6):1775-1781. DOI: http://dx.doi.org/10.2136/sssaj1994.03615995005800060028x
http://dx.doi.org/10.2136/sssaj1994.0361... . This behavior reflected a high correlation of estimates with the observed data due to an R² higher than 0.90. In addition, the results showed that changes imposed on the Oxisol by agriculture led to an increase in water volume retained at potentials lower than −15000 hPa, in which θPWP values were higher than 0.16 m³ m⁻³ in most cases, even in integrated production systems. The estimates of θPWP allowed a more detailed observation of the Oxisol database, in which OM and BD contents were not significant in the pedofunctions of Gupta & Larson (1979)Gupta S, Larson WE (1979) Estimating soil water retention characteristics from particle size distribution, organic matter percent, and bulk density. Water resources research 15(6):1633-1635., van den Berg et al. (1987), and Oliveira et al. (2002)Oliveira LB, Ribeiro MR, Jacomine PKT, Rodrigues JJV, Marques FA (2002) Funções de pedotransferência para predição da umidade retida a potenciais específicos em solos do estado de Pernambuco. Revista Brasileira de Ciência do Solo 26(2):315-322. DOI: http://dx.doi.org/10.1590/S0100-06832002000200004
http://dx.doi.org/10.1590/S0100-06832002... (Table 2). On the other hand, OM and BD contents were significant in the adjustment of θPWP functions for the Ultisol. According to Rawls et al. (2003)Rawls WJ, Pachepsky YA, Ritchie JC, Sobecki TM, Bloodworth H (2003) Effect of soil organic carbon on soil water retention. Geoderma 116(1-2):61-76., the use of contents of soil organic carbon and their particle size distribution as predictors leads to a small improvement in water content predictions related to the matric potential of −15000 hPa when compared to functions that use only particle size distribution as predictors.

FIGURE 3
Linear regressions between observed and estimated θPWP values obtained from the proposed models.

Bonetti et al. (2017)Bonetti JA, Anghinoni I, de Moraes MT, Fink JR (2017) Resilience of soils with different texture, mineralogy and organic matter under long-term conservation systems. Soil and Tillage Research 174:104-112. DOI: https://doi.org/10.1016/j.still.2017.06.008
https://doi.org/10.1016/j.still.2017.06.... studied the water retention of an Oxisol and Ultisol under integrated crop-livestock systems (ICL) and verified that changes imposed by the management system on soil porosity modified θFC to a higher degree when compared to θPWP. The adequate animal stocking rate and dwell time of the forage crop in ICL can favor the reorganization of porous space by the root system development. This strategy contributes to increasing the water content available to plants, with direct changes in microporosity (Bonetti et al., 2017Bonetti JA, Anghinoni I, de Moraes MT, Fink JR (2017) Resilience of soils with different texture, mineralogy and organic matter under long-term conservation systems. Soil and Tillage Research 174:104-112. DOI: https://doi.org/10.1016/j.still.2017.06.008
https://doi.org/10.1016/j.still.2017.06.... ). In this sense, the management system adopted for the Oxisol (ICL with an intensive crop rotation and high animal stocking rate) may not have been adequate to the maintenance of a pore structure with a diameter lower than 0.2 μm, which favored micropore disruption, directly reinforcing the effect of clay contents under soil compaction conditions. In this case, the function adjustment procedure itself is responsible for maintaining or excluding a certain attribute, aiming at the adequacy of adjustment coefficients, as well as the errors between the generated output patterns to reach the desired minimum value, i.e., close to zero.

As in R², ANN showed higher efficiency in the estimation of θFC and θPWP. ANN, Arruda et al. (1987)Arruda FB, Zullo Junior J, Oliveira JD (1987) Parâmetros de solo para o cálculo da água disponível com base na textura do solo. Revista Brasileira de Ciência do Solo 11:11-15., and van den Berg et al. (1987) were the best classified for the MSE, RMSE, and MAPE values of the pedofunctions that estimated θFC (Table 4). On the other hand, ANN, Rawls et al. (1982)Rawls WJ, Brakensiek DL, Saxtonn KE (1982) Estimation of soil water properties. Transactions of the ASAE 25(5):1316-1320., and van den Berg et al. (1987), in this order, were the best for those that estimated θPWP. MSE was a sensitive evaluator to errors of pedofunctions because it raised the individual differences between the observed and estimated squared values. This evaluator is always positive and, when zero, indicates the perfect model simulation. In addition to MSE, RMSE also expresses the accuracy of results, with error values under the same dimensions of the analyzed variable. MAPE is a less robust evaluator and showed the error representativeness in relation to the total of the measured observations. In this case, ANNs were classified first in the pedofunctions rank, with lower MSE, RMSE, and MAPE in both θFC and θPWP estimates.

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TABLE 4
Mean square error (MSE), root mean square error (RMSE), and mean absolute percentage error (MAPE) calculated from the proposed θFC and θPWP pedofunctions.

The estimates generated by these two adjustment categories could be considered as satisfactory and valid, but the use of multiple linear regression models to predict θFC values below 0.20 m³ m⁻³ may present a slight tendency to overestimate it, which was not observed by the neural network. The pedofunctions applied to LLWR showed that the available soil water content (AW), represented by the difference between θFC and θPWP, was positively influenced by an increase in BD between 0.69 and 1.06 Mg m⁻³ in all cases (Figure 4C, D). This behavior confirms the positive relationship between soil compaction and the available water range (without considering restrictions imposed by θPR), in which the water content retained at potentials of −100 and −15000 hPa is higher. The models proposed by Silva et al. (1994)Silva AP, Kay BD, Perfect E (1994) Characterization of the Least Limiting Water Range of Soils. Soil Science Society of America Journal 58(6):1775-1781. DOI: http://dx.doi.org/10.2136/sssaj1994.03615995005800060028x
http://dx.doi.org/10.2136/sssaj1994.0361... and Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326
http://dx.doi.org/10.13031/2013.13326... stood out from the other pedofunctions in both soils, indicating an excess LLWR of 0.02 m³ m⁻³ in the Oxisol (Figure 4A) and a deficit of 0.04 m³ m⁻³ in the Ultisol (Figure 4B) based on the estimates carried out by ANN, which had the best performance in both soils.

FIGURE 4
Variation of LLWR in the Oxisol (A) and Ultisol (B) and available water content in the Oxisol (C) and Ultisol (D) using the tested pedofunctions.

Regarding the critical BD, in which LLWR is zero, all the proposed models for Oxisol showed LLWR zero for a BD of 1.33 Mg m⁻³, while most of the models for the Ultisol presented LLWR zero for a BD of 1.38 Mg m⁻³ (Figure 4A, B). In this case, the models of Oliveira et al. (2002)Oliveira LB, Ribeiro MR, Jacomine PKT, Rodrigues JJV, Marques FA (2002) Funções de pedotransferência para predição da umidade retida a potenciais específicos em solos do estado de Pernambuco. Revista Brasileira de Ciência do Solo 26(2):315-322. DOI: http://dx.doi.org/10.1590/S0100-06832002000200004
http://dx.doi.org/10.1590/S0100-06832002... and Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326
http://dx.doi.org/10.13031/2013.13326... underestimated and overestimated the critical BD in the Ultisol, respectively. For LLWR construction in the Ultisol using the pedofunctions proposed by Oliveira et al. (2002)Oliveira LB, Ribeiro MR, Jacomine PKT, Rodrigues JJV, Marques FA (2002) Funções de pedotransferência para predição da umidade retida a potenciais específicos em solos do estado de Pernambuco. Revista Brasileira de Ciência do Solo 26(2):315-322. DOI: http://dx.doi.org/10.1590/S0100-06832002000200004
http://dx.doi.org/10.1590/S0100-06832002... , the critical BD would be 1.35 Mg m⁻³, while using the pedofunctions proposed by Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326
http://dx.doi.org/10.13031/2013.13326... , the critical BD would be 1.61 Mg m⁻³ (Figure 4B). Considering that LLWR accesses soil physical quality through BD, the main objective of its determination is to clarify the critical BD so that preventive actions are taken in agricultural systems. In the evaluated systems, the θPR curve was the preponderant factor in the establishment of the critical BD.

Regardless of the pedofunctions used for LLWR construction in the Oxisol, it was not restricted by the air-filled capacity curve (θAFC) (Figure 5). The θAFC was above θFC in all cases, not being a preponderant factor even at high BD levels. According to Gubiani et al. (2013)Gubiani PI, Reichert JM, Reinert DJ (2013) Indicadores hídrico-mecânicos de compactação do solo e crescimento de plantas. Revista Brasileira de Ciência do Solo 37(1):1-10. DOI: https://doi.org/10.1590/S0100-06832013000100001
https://doi.org/10.1590/S0100-0683201300... , there are practically no criticisms reported in the Brazilian literature for the upper LLWR limits. Most crops are grown on soils with optimum drainage, where the period of water excess, i.e., soil aeration deficiency is much lower when compared to periods of water deficit. Under these soil conditions, studies have indicated a higher relationship of plant development with PR (Freddi et al., 2009Freddi OS, Centurion JF, Duarte AP, Peres FSC (2009) Compactação do solo e produção de cultivares de milho em Latossolo Vermelho. II - Intervalo hídrico ótimo e sistema radicular. Revista Brasileira de Ciência do Solo 33(4):805-818.; Kaiser et al., 2009), being more frequent than with θAFC.

FIGURE 5
LLWR construction of the Oxisol as a function of soil bulk density using the proposed pedofunctions to estimate θFC and θPWP.

When the proposed pedofunctions are used to construct the LLWR concept, it is evident that the main changes occur on the available soil water content (AW). In the Oxisol, LLWRs estimated by ANN, Gupta & Larson (1979)Gupta S, Larson WE (1979) Estimating soil water retention characteristics from particle size distribution, organic matter percent, and bulk density. Water resources research 15(6):1633-1635., Rawls et al. (1982)Rawls WJ, Brakensiek DL, Saxtonn KE (1982) Estimation of soil water properties. Transactions of the ASAE 25(5):1316-1320., Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326
http://dx.doi.org/10.13031/2013.13326... , Arruda et al. (1987)Arruda FB, Zullo Junior J, Oliveira JD (1987) Parâmetros de solo para o cálculo da água disponível com base na textura do solo. Revista Brasileira de Ciência do Solo 11:11-15., Oliveira et al. (2002)Oliveira LB, Ribeiro MR, Jacomine PKT, Rodrigues JJV, Marques FA (2002) Funções de pedotransferência para predição da umidade retida a potenciais específicos em solos do estado de Pernambuco. Revista Brasileira de Ciência do Solo 26(2):315-322. DOI: http://dx.doi.org/10.1590/S0100-06832002000200004
http://dx.doi.org/10.1590/S0100-06832002... , and van den Berg et al. (1987) were similar (Figure 5). The model presented by Silva et al. (1994)Silva AP, Kay BD, Perfect E (1994) Characterization of the Least Limiting Water Range of Soils. Soil Science Society of America Journal 58(6):1775-1781. DOI: http://dx.doi.org/10.2136/sssaj1994.03615995005800060028x
http://dx.doi.org/10.2136/sssaj1994.0361... overestimated AW values for conditions of lower bulk density, i.e., between 0.75 and 1.2 Mg m⁻³ (Figure 5B). In contrast, the model of Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326
http://dx.doi.org/10.13031/2013.13326... underestimated AW at low BD levels and then presented significant AW gains with an increase in BD (Figure 5E).

Considering the results obtained for the Ultisol, it was evident that AW was overestimated under all BD conditions when the pedofunctions proposed by Silva et al. (1994)Silva AP, Kay BD, Perfect E (1994) Characterization of the Least Limiting Water Range of Soils. Soil Science Society of America Journal 58(6):1775-1781. DOI: http://dx.doi.org/10.2136/sssaj1994.03615995005800060028x
http://dx.doi.org/10.2136/sssaj1994.0361... were used (Figure 6B). The model proposed by Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326
http://dx.doi.org/10.13031/2013.13326... , as observed for the Oxisol, underestimated AW at low BD levels and overestimated AW at high BD levels, which would restrict its use for this type of soil (Figure 6E).

FIGURE 6
LLWR construction of the Ultisol as a function of soil bulk density using the proposed pedofunctions to estimate θFC and θPWP.

The results obtained in this study provided important information for the management of compacted and/or irrigated areas, demonstrating the use of the main models to estimate θFC and θPWP, the result on LLWR determination, and available water of two soils frequently found in Brazil. In addition, further studies using a larger database are needed, allowing the establishment of an artificial neural network that could be validated for Brazilian soils or tropical regions.

CONCLUSIONS

Among the evaluated pedofunctions, multilayer perceptron artificial neural networks are more efficient to estimate water contents in the field capacity and permanent wilting point.

Pedofunctions that use contents of sand, clay, organic matter, and soil bulk density are more efficient in estimating water contents in the field capacity and permanent wilting point.

Multiple linear regression techniques are inferior regarding statistics that measure the accuracy of models and tend to overestimate water content values in the field capacity.

Pedofunctions differ in the establishment of the critical bulk density when they are used to calculate the least limiting water range, exposing the limitations of the models.

ACKNOWLEDGMENTS

To the Coordination for the Improvement of Higher Education Personnel (CAPES) for granting the scholarship to the first author. To Embrapa Agrosilvopastoral and Certeza Farm for providing one of the areas for study.

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Publication Dates

Publication in this collection
12 Aug 2019
Date of issue
Jul-Aug 2019

History

Received
19 Jan 2018
Accepted
29 May 2019

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] Arruda FB, Zullo Junior J, Oliveira JD (1987) Parâmetros de solo para o cálculo da água disponível com base na textura do solo. Revista Brasileira de Ciência do Solo 11:11-15.

[2] Barros AHC, Jong Van Lier QD, Maia ADHN, Scarpare FV (2013) Pedotransfer functions to estimate water retention parameters of soils in northeastern Brazil. Revista Brasileira de Ciência do Solo 37(2):379-391. DOI: http://dx.doi.org/10.1590/S0100-06832013000200009
» http://dx.doi.org/10.1590/S0100-06832013000200009

[3] Betioli Junior E, Moreira WH, Tormena CA, Bernabe Ferreira CJ, Silva AP, Giarola NFB (2012) Intervalo hídrico ótimo e grau de compactação de um Latossolo Vermelho após 30 anos sob plantio direto. Revista Brasileira de Ciência do Solo 36(3):971-982. DOI: http://dx.doi.org/10.1590/S0100-06832012000300027
» http://dx.doi.org/10.1590/S0100-06832012000300027

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Source	Soil	Model¹	R²
		Oxisol
Silva et al. (1994)Silva AP, Kay BD, Perfect E (1994) Characterization of the Least Limiting Water Range of Soils. Soil Science Society of America Journal 58(6):1775-1781. DOI: http://dx.doi.org/10.2136/sssaj1994.03615995005800060028x http://dx.doi.org/10.2136/sssaj1994.0361...	CAN	θFC = exp ^-0.873* BD ^0.511* 100 ^-0.115	0.96*
Gupta & Larson (1979)Gupta S, Larson WE (1979) Estimating soil water retention characteristics from particle size distribution, organic matter percent, and bulk density. Water resources research 15(6):1633-1635.	USA	θFC = 0.001^* SD + 0^ns ST + 0^ns CL + 0^ns OM + 0.179* BD	0.99*
Rawls et al. (1982)Rawls WJ, Brakensiek DL, Saxtonn KE (1982) Estimation of soil water properties. Transactions of the ASAE 25(5):1316-1320.	USA	θFC = – 0.588^* + 0^ns SD + 0^ns ST + 0.027^* CL + 0^ns OM + 0^ns BD	0.74*
Saxton et al. (1986)Saxton KE, Rawls W, Romberger JS, Papendick RI (1986) Estimating generalized soil-water characteristics from texture. Soil Science Society of America Journal 50(4):1031-1036.	USA	θFC = exp[( – 1.335^* – ln A)/ B]	0.57*
Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326 http://dx.doi.org/10.13031/2013.13326...	USA	GM = 0.169^* (CL/SD) ^0.405* → θFC = GM × BD	0.47*
Arruda et al. (1987)Arruda FB, Zullo Junior J, Oliveira JD (1987) Parâmetros de solo para o cálculo da água disponível com base na textura do solo. Revista Brasileira de Ciência do Solo 11:11-15.	BRA	θFC = 0.040^* + 0^ns (CL+ST) + 1.22×10^-4* (CL+ST)²	0.74*
van den Berg et al. (1987)	TRP	θFC = -1.752^* + 0.053^* CL + 0^ns ST + 0.132^* OM	0.74*
Oliveira et al. (2002)Oliveira LB, Ribeiro MR, Jacomine PKT, Rodrigues JJV, Marques FA (2002) Funções de pedotransferência para predição da umidade retida a potenciais específicos em solos do estado de Pernambuco. Revista Brasileira de Ciência do Solo 26(2):315-322. DOI: http://dx.doi.org/10.1590/S0100-06832002000200004 http://dx.doi.org/10.1590/S0100-06832002...	BRA	θFC = 0.015^* ST + 0.003^* CL	0.99*
		Ultisol
Silva et al. (1994)Silva AP, Kay BD, Perfect E (1994) Characterization of the Least Limiting Water Range of Soils. Soil Science Society of America Journal 58(6):1775-1781. DOI: http://dx.doi.org/10.2136/sssaj1994.03615995005800060028x http://dx.doi.org/10.2136/sssaj1994.0361...	CAN	θFC = exp ^-0.951* BD ^-0.163* 100 ^-0.124*	0.34*
Gupta & Larson (1979)Gupta S, Larson WE (1979) Estimating soil water retention characteristics from particle size distribution, organic matter percent, and bulk density. Water resources research 15(6):1633-1635.	USA	θFC = 0^ns SD + 0^ns ST + 0^ns CL + 0.017^* OM + 0.109^* BD	0.99*
Rawls et al. (1982)Rawls WJ, Brakensiek DL, Saxtonn KE (1982) Estimation of soil water properties. Transactions of the ASAE 25(5):1316-1320.	USA	θFC = 0.382 – 0.003^* SD + 0^ns ST + 0^ns CL + 0^ns OM + 0^ns BD	0.72*
Saxton et al. (1986)Saxton KE, Rawls W, Romberger JS, Papendick RI (1986) Estimating generalized soil-water characteristics from texture. Soil Science Society of America Journal 50(4):1031-1036.	USA	θFC = exp[(– 0.665^* – ln A)/ B]	0.60*
Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326 http://dx.doi.org/10.13031/2013.13326...	USA	GM = 0.255^* (CL/SD) ^0.167* → θFC = GM × BD	0.01*
Arruda et al. (1987)Arruda FB, Zullo Junior J, Oliveira JD (1987) Parâmetros de solo para o cálculo da água disponível com base na textura do solo. Revista Brasileira de Ciência do Solo 11:11-15.	BRA	θFC = 0.107^* + 0.003^* (CL+ST) + 0^ns (CL+ST)²	0.72*
van den Berg et al. (1987)	TRP	θFC = 0^ns + 0^ns CL + 0^ns ST + 0^ns OM	-
Oliveira et al. (2002)Oliveira LB, Ribeiro MR, Jacomine PKT, Rodrigues JJV, Marques FA (2002) Funções de pedotransferência para predição da umidade retida a potenciais específicos em solos do estado de Pernambuco. Revista Brasileira de Ciência do Solo 26(2):315-322. DOI: http://dx.doi.org/10.1590/S0100-06832002000200004 http://dx.doi.org/10.1590/S0100-06832002...	BRA	θFC = 0.004^* ST + 0.006^* CL	0.97*

Source	Soil	Model¹	R²
		Oxisol
Silva et al. (1994)Silva AP, Kay BD, Perfect E (1994) Characterization of the Least Limiting Water Range of Soils. Soil Science Society of America Journal 58(6):1775-1781. DOI: http://dx.doi.org/10.2136/sssaj1994.03615995005800060028x http://dx.doi.org/10.2136/sssaj1994.0361...	CAN	θPWP = exp ^-0.873* BD ^0.511* 15000 ^-0.115	0.96*
Gupta & Larson (1979)Gupta S, Larson WE (1979) Estimating soil water retention characteristics from particle size distribution, organic matter percent, and bulk density. Water resources research 15(6):1633-1635.	USA	θPWP = 0^ns SD – 0.017^* ST + 0.010^* CL + 0^ns OM + 0^ns BD	0.99*
Rawls et al. (1982)Rawls WJ, Brakensiek DL, Saxtonn KE (1982) Estimation of soil water properties. Transactions of the ASAE 25(5):1316-1320.	USA	θPWP = 1.034^* + 0^ns SD – 0.099^* ST + 0^ns CL + 0^ns OM + 0^ns BD	0.95*
Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326 http://dx.doi.org/10.13031/2013.13326...	USA	θPWP = θ_pwp^* – 1.35×10^-10* exp ^{(0.285* SD)}	0.90*
Arruda et al. (1987)Arruda FB, Zullo Junior J, Oliveira JD (1987) Parâmetros de solo para o cálculo da água disponível com base na textura do solo. Revista Brasileira de Ciência do Solo 11:11-15.	BRA	θPWP = – 0.382^* + 0.013^* (CL+ST)	0.94*
van den Berg et al. (1987)	TRP	θPWP= 1.034^* + 0^ns CL – 0.099^* ST	0.95*
Oliveira et al. (2002)Oliveira LB, Ribeiro MR, Jacomine PKT, Rodrigues JJV, Marques FA (2002) Funções de pedotransferência para predição da umidade retida a potenciais específicos em solos do estado de Pernambuco. Revista Brasileira de Ciência do Solo 26(2):315-322. DOI: http://dx.doi.org/10.1590/S0100-06832002000200004 http://dx.doi.org/10.1590/S0100-06832002...	BRA	θPWP = 0^ns SD – 0.017^* ST + 0.010^* CL + 0^ns BD	0.99*
		Ultisol
Silva et al. (1994)Silva AP, Kay BD, Perfect E (1994) Characterization of the Least Limiting Water Range of Soils. Soil Science Society of America Journal 58(6):1775-1781. DOI: http://dx.doi.org/10.2136/sssaj1994.03615995005800060028x http://dx.doi.org/10.2136/sssaj1994.0361...	CAN	θPWP = exp ^-0.951* BD ^-0.163* 15000 ^-0.124*	0.34*
Gupta & Larson (1979)Gupta S, Larson WE (1979) Estimating soil water retention characteristics from particle size distribution, organic matter percent, and bulk density. Water resources research 15(6):1633-1635.	USA	θPWP = 0^ns SD + 0^ns ST + 0.003^* CL + 0.019^* OM + 0.020^* BD	0.99*
Rawls et al. (1982)Rawls WJ, Brakensiek DL, Saxtonn KE (1982) Estimation of soil water properties. Transactions of the ASAE 25(5):1316-1320.	USA	θPWP = 0.293^* – 0.002^* SD + 0^ns ST + 0^ns CL + 0^ns OM + 0^ns BD	0.70*
Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326 http://dx.doi.org/10.13031/2013.13326...	USA	θPWP = θ_pwp^* – 2.51×10^-5* exp ^{(0.087* SD)}	0.78*
Arruda et al. (1987)Arruda FB, Zullo Junior J, Oliveira JD (1987) Parâmetros de solo para o cálculo da água disponível com base na textura do solo. Revista Brasileira de Ciência do Solo 11:11-15.	BRA	θPWP = 0.088^* + 0.002^* (CL+ST)	0.70*
van den Berg et al. (1987)	TRP	θPWP= 0.088^* + 0.002^* CL + 0.002^* ST	0.70*
Oliveira et al. (2002)Oliveira LB, Ribeiro MR, Jacomine PKT, Rodrigues JJV, Marques FA (2002) Funções de pedotransferência para predição da umidade retida a potenciais específicos em solos do estado de Pernambuco. Revista Brasileira de Ciência do Solo 26(2):315-322. DOI: http://dx.doi.org/10.1590/S0100-06832002000200004 http://dx.doi.org/10.1590/S0100-06832002...	BRA	θPWP = 0^ns SD + 0.003^* ST + 0.005^* CL + 0^ns BD	0.97*

Attributes²	Mean	Median	Min	Max	SD	CV	Kurt	Asym	Pw<W
	Oxisol
SD (dag kg^-1)	55.341	58.335	52.419	62.424	3.236	5.847	0.057	1.246	0.001*
SIL (dag kg^-1)	12.527	9.096	8.097	14.266	1.986	15.850	0.185	-1.287	0.001*
CL (dag kg^-1)	32.131	32.744	29.479	33.315	1.250	3.890	-0.130	-1.181	0.002*
OM (dag kg^-1)	2.554	2.411	2.333	3.087	0.244	9.553	0.045	1.242	0.001*
BD (Mg m^-3)	1.356	1.458	0.920	1.545	0.203	14.970	-0.054	-1.209	0.001*
θFC (m³ m^-3)	0.285	0.293	0.212	0.346	0.039	13.684	-0.545	-0.558	0.248^ns
θPWP (m³ m^-3)	0.160	0.168	0.132	0.172	0.014	8.750	-0.170	-1.275	0.000*
	Ultisol
SD (dag kg^-1)	65.736	64.900	50.500	81.000	7.019	10.638	0.666	0.502	0.242^ns
SIL (dag kg^-1)	10.932	8.500	1.700	18.900	4.400	36.363	-0.339	-0.268	0.880^ns
CL (dag kg^-1)	22.800	22.300	9.700	39.500	6.560	26.315	0.949	0.296	0.461^ns
OM (dag kg^-1)	3.649	3.562	1.860	7.240	1.546	42.356	-0.289	0.776	0.046*
BD (Mg m^-3)	1.505	1.361	1.180	1.760	0.138	8.637	0.804	-0.802	0.170^ns
θFC (m³ m^-3)	0.210	0.209	0.160	0.260	0.043	20.476	-2.214	-0.265	0.002*
θPWP (m³ m^-3)	0.160	0.160	0.130	0.220	0.032	20.00	0.563	0.926	0.021*

Fonte	θFC				θPWP

	MSE	RMSE	MAPE	Rank¹	MSE	RMSE	MAPE	Rank¹
	Oxisol
Silva et al. (1994)Silva AP, Kay BD, Perfect E (1994) Characterization of the Least Limiting Water Range of Soils. Soil Science Society of America Journal 58(6):1775-1781. DOI: http://dx.doi.org/10.2136/sssaj1994.03615995005800060028x http://dx.doi.org/10.2136/sssaj1994.0361...	0.0004	0.0220	0.0118	6^th	1.54×10^-5	0.0039	0.0075	5^th
Gupta & Larson (1979)Gupta S, Larson WE (1979) Estimating soil water retention characteristics from particle size distribution, organic matter percent, and bulk density. Water resources research 15(6):1633-1635.	0.0005	0.0228	0.0485	7^th	0.0001	0.0114	0.0694	6^th
Rawls et al. (1982)Rawls WJ, Brakensiek DL, Saxtonn KE (1982) Estimation of soil water properties. Transactions of the ASAE 25(5):1316-1320.	0.0004	0.0202	0.0184	5^th	9.08×10^-6	0.0030	0.0029	2^nd
Saxton et al. (1986)Saxton KE, Rawls W, Romberger JS, Papendick RI (1986) Estimating generalized soil-water characteristics from texture. Soil Science Society of America Journal 50(4):1031-1036.	0.0009	0.0304	0.0189	8^th	-	-	-	-
Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326 http://dx.doi.org/10.13031/2013.13326...	0.0826	0.2875	0.0046	9^th	0.0001	0.0135	0.0103	8^th
Arruda et al. (1987)Arruda FB, Zullo Junior J, Oliveira JD (1987) Parâmetros de solo para o cálculo da água disponível com base na textura do solo. Revista Brasileira de Ciência do Solo 11:11-15.	0.0003	0.0192	0.0021	2^nd	1.17×10^-5	0.0034	0.0004	4^th
van den Berg et al. (1987)	0.0003	0.0193	0.0119	3^rd	9.08×10^-6	0.0030	0.0029	3^rd
Oliveira et al. (2002)Oliveira LB, Ribeiro MR, Jacomine PKT, Rodrigues JJV, Marques FA (2002) Funções de pedotransferência para predição da umidade retida a potenciais específicos em solos do estado de Pernambuco. Revista Brasileira de Ciência do Solo 26(2):315-322. DOI: http://dx.doi.org/10.1590/S0100-06832002000200004 http://dx.doi.org/10.1590/S0100-06832002...	0.0003	0.0194	0.0012	4^th	0.0001	0.0114	0.0694	7^th
Artificial neural network	0.0002	0.0142	0.0018	1^st	5.22×10^-6	0.0022	0.0019	1^st
	Ultisol
Silva et al. (1994)Silva AP, Kay BD, Perfect E (1994) Characterization of the Least Limiting Water Range of Soils. Soil Science Society of America Journal 58(6):1775-1781. DOI: http://dx.doi.org/10.2136/sssaj1994.03615995005800060028x http://dx.doi.org/10.2136/sssaj1994.0361...	0.0016	0.0411	0.0424	7^th	0.0036	0.0601	0.3087	8^th
Gupta & Larson (1979)Gupta S, Larson WE (1979) Estimating soil water retention characteristics from particle size distribution, organic matter percent, and bulk density. Water resources research 15(6):1633-1635.	0.0004	0.0222	0.0338	2^nd	3.73×10^-5	0.0061	0.0121	2^nd
Rawls et al. (1982)Rawls WJ, Brakensiek DL, Saxtonn KE (1982) Estimation of soil water properties. Transactions of the ASAE 25(5):1316-1320.	0.0006	0.0256	0.0654	4^th	0.0002	0.0146	0.0137	3^rd
Saxton et al. (1986)Saxton KE, Rawls W, Romberger JS, Papendick RI (1986) Estimating generalized soil-water characteristics from texture. Soil Science Society of America Journal 50(4):1031-1036.	0.0012	0.0359	0.0587	6^th	-	-	-	-
Ritchie et al. (1999)Ritchie JT, Gerakis A, Suleiman A (1999) Simple model to estimate field-measured soil water limits. Transactions of the ASAE 42(6):1609-1614. DOI: http://dx.doi.org/10.13031/2013.13326 http://dx.doi.org/10.13031/2013.13326...	0.0080	0.0895	0.3519	8^th	0.0006	0.0254	0.0371	6^th
Arruda et al. (1987)Arruda FB, Zullo Junior J, Oliveira JD (1987) Parâmetros de solo para o cálculo da água disponível com base na textura do solo. Revista Brasileira de Ciência do Solo 11:11-15.	0.0005	0.0229	0.0588	3^rd	0.0002	0.0151	0.0170	4^th
van den Berg et al. (1987)	-	-	-	-	0.0002	0.0151	0.0170	5^th
Oliveira et al. (2002)Oliveira LB, Ribeiro MR, Jacomine PKT, Rodrigues JJV, Marques FA (2002) Funções de pedotransferência para predição da umidade retida a potenciais específicos em solos do estado de Pernambuco. Revista Brasileira de Ciência do Solo 26(2):315-322. DOI: http://dx.doi.org/10.1590/S0100-06832002000200004 http://dx.doi.org/10.1590/S0100-06832002...	0.0012	0.0357	0.0989	5^th	0.0008	0.0291	0.0915	7^th
Artificial neural network	4.94×10^-6	0.0022	0.0043	1^st	6.56×10^-6	0.0025	0.0096	1^st