The study area (Figure 1) is located in the center of Morocco, between the Atlantic coast in the north-west and the Atlas Mountains in the south-east (32°23' north latitude, 6°31' west longitude, 445 m above sea level). Covering 100 000 ha, the irrigated plain of Tadla is characterized by a flat topography and composed of a right bank (Beni-Amir) and left bank (Beni-Moussa). This area is characterized by a semi-arid climate: the average annual precipitation is about 300 mm (average over the period 1970-2010), with a significant interannual variation ranging from 130 to 600 mm in the same period. This plain is managed by the Regional Office for Agricultural Development of Tadla (ORMVAT).

Wheat is one of the main crops in this area, covering 36% of the total cultivated area. The wheat-growing cycle in the region runs from November-December to June. During this period, wheat is irrigated, using the flooding irrigation technique, between two and five times, depending on the water available in autumn and the volume accumulated in dams during winter and spring seasons.

The area is divided into several hundred irrigation plots. Sixteen wheat plots of them were selected in this study. The size of these plots varied from 1.7 to 14.5 ha (the total area is 77 ha). The combination of crop management and irrigation schedule for these plots was representative of the agricultural practices for wheat in the region. Figure 1 shows the location of studied area and illustrates the position of the selected plots (P1 to P16).

Experiments were conducted during the 2012-2013 wheat growing season to record dates and amounts of irrigated water supplied and to collect crop physiological data. Data were collected from 16 fields of wheat, located at Tadla’s Regional Agricultural Research or belonging to farmers, thus providing a valid representation of the soil-plant relationship in the study area. The field data related to Marzak and Achtar cultivars, which are widely cultivated in the study region.

Vegetation water content was measured weekly from anthesis until wheat grain filling (March to May 2013). It was measured in four randomly selected quadrates in each plot (i.e. an area of 0.5 x 0.5 m). From each quadrate, subsamples were used to measure the weight of the fresh and dry above-ground biomass (dried in an oven at 65°C for 48 h) (IQBAL et al., 2014). Water vegetation content was quantified on a gravimetric basis (gram of water/gram of vegetation) and was expressed in this document as a percentage (%).

We synchronized the field measurements with the planning for acquiring satellite images. In our case study, we only considered field measurements taken within a time lag of three days. We also ensured that during this time lag there was no rainfall event or irrigation supply.

Using geographical information system (GIS) software, we vectorized the collected field data (vegetation water content) as point and the experimental plots delimitations as polygons. We subdivided the experimental plots into units (subplots) of the same size and assigning per unit a code to identify and locate in space and time. Then, each subplot has been joined to the punctual data of vegetation water content and soil moisture corresponding to it spatially.

Three SPOT-5 HRV satellite images were acquired on 21 March 2013, 26 March 2013 and 11 April 2013 when the soil was completely covered by vegetation. They covered the period between anthesis (March) and grain filling (April) in the 2012-2013 cropping season. These wheat growth stages are crucial to ensure good yield (DE SAN CELEDONIO et al., 2014).

SPOT-5 scenes have 10 m pixel resolution and four spectral bands: B1 (green: 0.50–0.59 µm), B2 (red: 0.61–0.68 µm), B3 (near infrared NIR: 0.79–0.89 µm) and B4 (short-wave infrared SWIR: 1.58–1.75 µm). One of the big advantages of SPOT-5 images compared to other VHR images is the large swath (60 x 60 km) that allows a complete view of our region of interest. We also had the opportunity to program the satellite passes when the vegetation covered completely the soil and to match the critical time for the wheat crop.

The processing level of the acquired images was (1 B), which included radiometric and geometric corrections. We conducted an atmospheric correction from the images of radiance, using the FLAASH model (Fast Line-of-sight Atmospheric Analysis of Spectral Hypercubes) included in the ENVI 5 software. The latter model is considered more accurate compared to other models for SPOT-5 images (GUO and ZENG, 2012).

We computed two spectral indices, the NDWI (GAO, 1996; HARDISKY et al., 1983) and the MSI (CECCATO et al., 2001; CECCATO et al., 2002b; HUNT and ROCK, 1989), using the NIR and SWIR spectral reflectance for each SPOT-5 HRV image acquisition date (Table 1).

The next step consisted in generation of a mask of wheat subplots, using ENVI 5 software. The average values of the spectral indices (NDWI and MSI) were then computed for each corresponding subplot (7 x 7 pixels) where field measurements were conducted (Figure 2). In our case study, we took 1.5 ha (7 x 7 pixels) as a reference area, where irrigation applications are synchronous and homogeneous at this scale. Regression analysis was carried out between vegetation water content measurements, MSI and NDWI values. This permitted to establish the relationships between the NDWI and MSI values derived from the SPOT-5 images dataset and the ground studied measurements.

In order to define the cereal area, which is our region of interest, we used a supervised classification method where 65 datasets have been taken for calibration and 112 sets for validation data. Separability analysis allow to determine how distinct, and thus separable, different surface types are from each other. Wheat, as a cereal, and other land occupations were categorized into two different classes to analyze their spectral separability. The Jeffries-Matusita (JM) distance was used to assess the potential of band pairs to discriminate between two different region classes. The values range between 0 and 2 (RICHARDS, 1995).

Cross-validation is a technique to explore the reliability of a model to assess how the results of a statistical analysis will be applied to an independent data set (KOHAVI, 1995). It is mainly used to estimate the accuracy of a predictive model. Several cross-validation techniques are used: holdout method, k-fold cross-validation and leave-one-out cross-validation (LOOCV).

The k-fold cross validation (k-fold CV) approach was used to evaluate the accuracy of the obtained regression models between the two spectral indices and surface water content (CASSEL, 2007). This approach uses k replicate samples of observation data, builds models with (k-1)/k of data and tests with the remaining 1/k. K-fold CV is an effective and widely used method. In our case, it involved 20% of the observations as the validation data, with the remaining 80% of the observations being the training data. We emphasize that the random k-fold CV takes k independent samples of size N(k-1)/k (CASSEL, 2007). We performed the cross-validation analysis using SAS 9.1 software.

Different statistical indices were used to compare predicted and observed values. These indices were the coefficient of determination (R²), the root mean square error (RMSE), the normalized RMSE (nRMSE) expressed as a percentage of the RMSE divided by the mean of observed values (RICHTER et al., 2012) and the mean absolute error (MAE):

where Si and Oi refer to simulated and observed values of the studied variable, respectively; n is the number of observations; and M is the mean of the observed variable. The nRMSE indicates the accuracy of the model and the dispersion around the mean of the observed values.

To illustrate the practical use of this study, vegetation water content was mapped by using the validated linear regression model between vegetation water content and NDWI index. Three maps were presented here for the east of Beni-Moussa irrigated area.

We compared the values of observed vegetation water content of 32 studied subplots and their spectral indices values derived from the three images acquired on 21 March 2013, 26 March 2013 and 11 April 2013. The results of this comparison are presented in Figure 3.

The statistical indicators obtained from the previous comparison, presented in Figure 3, showed that both spectral indices simulated well the vegetation water content. The values of statistical indicators R², RMSE, and nRMSE were 0.63, 3.19% and 4.24% for the NDWI, and 0.58, 3.22% and 4.27% for the MSI, respectively. Similar results were reported for the indices based on shortwave infrared band by QIUXIANG et al. (2012) and HUNT and ROCK (1989) when simulating the vegetation water content.

In order to validate these results, we compared observed vegetation water content values and those predicted using the k-fold CV method. As shown in Figure 4, the errors were minimal for both the NDWI and MSI. The evaluation model indicators obtained for predicted vegetation water content from the NDWI were 0.52, 3.39% and 4.52% for R², RMSE and nRMSE, respectively. For the MSI, these values were 0.48, 3.55% and 4.74% for R², RMSE and nRMSE, respectively (Figure 4). These results confirmed the ability of NDWI to retrieve well the vegetation water content of wheat, while the values in MSI were comparatively less in agreement with the observed values.

We performed a supervised classification to identify cereal area (Figure 5). The analysis of the numerical JM values allowed us to conclude that the separability results for training samples on final classification scheme are good. The estimated value of separability was 1.99.

The contingency matrix was used to evaluate the percentage of sampled pixels that were classified as expected. This classification was validated and the accuracy assessment and Kappa statistic indicated that it was a good classification. The overall accuracy is 0.95 while the overall Kappa is 96.7%.

Figures 6 and 7 show three maps of vegetation water content (VWC) of wheat class derived from the five SPOT-5 images. These maps were generated using the regression model (VWC = 51.55NDWI + 65.75) obtained by comparing the three images on a pixel basis and field measurements. The analysis of the three maps showed that vegetation water content ranged from 58 to 87% between the three considered dates. For these maps we had an RMSE of 3.19% and an nRMSE of 4.24%.

Figure 6 presents a high homogeneity of vegetation water content (dominance of green color). Indeed, vegetation water content exceeded 70% for all plots. This is explained by important precipitation events that were recorded between 14 and 18 March 2013 (31.3 mm) and on 24 March 2013 (14 mm).

On the opposite, Figure 7 shows a strong heterogeneity in vegetation water content values after three weeks of precipitation and a homogeneous drying of several plots, with vegetation water content ranging from 58 to 76%.

Obtained maps allowed monitoring the variability of vegetation water content in wheat for each agricultural development center (ADC). Irrigation management is done independently at each development center. An overview of the maps allowed distinguishing between different levels of vegetation water content. Such information could be valuable for stakeholders and decision-makers in charge of irrigation areas and could help them to better manage irrigation at a large scale. It could also help judge the priority ADC to receive irrigation supplies according to the given state of vegetation water content.