Remote Sensing and Modelling Based Framework for Valuing Irrigation System Efficiency and Steering Indicators of Consumptive Water Use in an Irrigated Region
<p>A detailed description of the irrigation system at various spatial scales in Rechna Doab.</p> "> Figure 2
<p>Workflow diagram depicting Soil Energy Balance Algorithm (SEBAL) methodology, irrigation system performance assessment mechanisms, and spatial–temporal scales of processing.</p> "> Figure 3
<p>Maps of the independent variables used for the Random Forest regression modelling. (1st row) = Site-specific variables; (2nd row) = Proximity variables; (3rd row) = Cropping system variables.</p> "> Figure 4
<p>Theissen Polygons for estimating average rainfall in various irrigation subdivisions.</p> "> Figure 5
<p>Comparison of results between RS based crop acreage and state-owned statistics data.</p> "> Figure 6
<p>Percentage values of user’s (odd bars) and producer’s accuracies (even bars) for major crops of Rechna Doab.</p> "> Figure 7
<p>Plausibility analysis and validation of SEBAL based ET<sub>a</sub> and energy fluxes. (<b>a</b>) Evapotranspiration and rainfall over the study years (<b>b</b>) relationship between Penman Monteith and SEBAL ET with Advective Aridity ET and (<b>c</b>) variation of different fluxes throughout the season at experimental site of the University of Agriculture, Faisalabad, Pakistan.</p> "> Figure 8
<p>Crop water consumption in Rechna Doab during the Kharif (<b>a</b>) and Rabi (<b>b</b>)seasons.</p> "> Figure 8 Cont.
<p>Crop water consumption in Rechna Doab during the Kharif (<b>a</b>) and Rabi (<b>b</b>)seasons.</p> "> Figure 9
<p>Irrigation subdivision level variabilities of crop water consumption (i.e., equity).</p> "> Figure 10
<p>(<b>a</b>,<b>b</b>) Monthly and seasonal average values of the consumed ratio, (<b>c</b>,<b>d</b>) monthly and seasonal average values of relative water supply for different irrigation subdivisions. Please note down the different scale of the y-axis for different graphs.</p> "> Figure 11
<p>Reliability results for (<b>a</b>,<b>b</b>) Rechna Doab (<b>c</b>,<b>d</b>) irrigation circle (<b>e</b>,<b>f</b>) irrigation division and (<b>g</b>,<b>h</b>) irrigation subdivision spatial scales for the Kharif and Rabi seasons.</p> "> Figure 11 Cont.
<p>Reliability results for (<b>a</b>,<b>b</b>) Rechna Doab (<b>c</b>,<b>d</b>) irrigation circle (<b>e</b>,<b>f</b>) irrigation division and (<b>g</b>,<b>h</b>) irrigation subdivision spatial scales for the Kharif and Rabi seasons.</p> "> Figure 11 Cont.
<p>Reliability results for (<b>a</b>,<b>b</b>) Rechna Doab (<b>c</b>,<b>d</b>) irrigation circle (<b>e</b>,<b>f</b>) irrigation division and (<b>g</b>,<b>h</b>) irrigation subdivision spatial scales for the Kharif and Rabi seasons.</p> "> Figure 12
<p>Monthly and seasonal average crop water deficit values for different irrigation subdivisions during the (<b>a</b>) Kharif and (<b>b</b>) Rabi seasons.</p> "> Figure 12 Cont.
<p>Monthly and seasonal average crop water deficit values for different irrigation subdivisions during the (<b>a</b>) Kharif and (<b>b</b>) Rabi seasons.</p> "> Figure 13
<p>Indicators/variables importance ranking for consumptive water use during the (<b>a</b>) Kharif and (<b>b</b>) Rabi seasons.</p> "> Figure 13 Cont.
<p>Indicators/variables importance ranking for consumptive water use during the (<b>a</b>) Kharif and (<b>b</b>) Rabi seasons.</p> "> Figure 14
<p>Indicators/variables importance ranking for (<b>a</b>) rice (<b>b</b>) cotton (<b>c</b>) sugarcane and (<b>d</b>) wheat crops in Rechna Doab.</p> "> Figure 14 Cont.
<p>Indicators/variables importance ranking for (<b>a</b>) rice (<b>b</b>) cotton (<b>c</b>) sugarcane and (<b>d</b>) wheat crops in Rechna Doab.</p> "> Figure 15
<p>Crop specific consumptive water use difference of average value with 5th and 95th percentile for (<b>a</b>) rice (<b>b</b>) sugarcane (<b>c</b>) cotton and (<b>d</b>) wheat. The blue color shows a positive deviation from the average value and the red color shows the negative deviation from the average value.</p> ">
Abstract
:1. Introduction
2. Study Region
2.1. Irrigation System
2.2. Agriculture and Climate
3. Datasets
3.1. Remote Sensing Data
3.2. Geographical Information System (GIS) Data
3.3. Field Data
3.4. Secondary Data
4. Methods
4.1. Land Use Land Cover Mapping
4.2. SEBAL for Estimating Consumptive Water Use
4.3. Validation/Plausibility Analysis of SEBAL ETa Results
4.4. Calculation of Performance Indicators
4.4.1. Equity of Irrigation Distribution
4.4.2. Adequacy of Irrigation System
Overall Consumed Ratio (ep)
Relative Water Supply (RWS)
Relative Evapotranspiration
4.4.3. Reliability of Irrigation System
4.5. Spatio-Temporal Scales for Assessment
4.6. Factors/Variables Importance Analysis
4.6.1. Set of Factors
- Physical factors influence the cropping system in various ways that drive the water utilization and its supply [47,48,49,50]. The major variables include slope, canal density, road density, soil texture, elevation, and population density. Land slope influences consumptive water use, as some slopes create hindrance in reachability and flow of water, and therefore result in increased efforts for irrigation [51]. Higher canal densities would enable easy access to irrigation water and resultantly higher cropping intensities. Moreover, better soil moisture can be maintained in such regions due to low soil temperatures [51]. Road density does not have a direct impact, but could influence crop water use indirectly by facilitating better extension services. This could help in adopting better technologies and informed decision making, in time [51]. Moreover, crop husbandry could be improved due to easy and frequent access to the field by the farmers. Soil texture is a variable that influences water demands directly due to varying crop rotations, crop inputs, and due to different water holding capacities [52]. The elevation is another vital variable, which influences consumptive water use in multiple ways. Higher elevation usually results in fewer irrigation demands due to lower temperatures and higher precipitation, however, it increases the energy demands for pumping irrigation water and land leveling efforts. Population density could affect crop water utilization as better technical services for irrigation could be available in the vicinity of larger cities. However, it could influence adversely because of the lowering of farming interest due to fragmented and small landholdings among larger populations. Additionally, increased population leads to tough competition for water availability among various sectors competing for water, for instance, water diversion for agriculture, industry, and domestic needs [53].
- Proximity factors are another class of variables influencing crop water use/availability. Such variables include distances of farms from water bodies, from irrigation canals, from roads, from cities, and from canal outlets (i.e., mogha) [54]. Distances from water bodies help to maintain ecosystem balance, ground surface cooling, and a better supply of irrigation water, however, there are very few water bodies located in the Rechna Doab. Distances from canal infrastructures could be very vital, as longer distances result in more loss of canal water through seepage and resultantly less flows in the remote regions [55]. Distances from road and cities could affect better access to fields to adopt diversified cropping practices and to perform various advanced cropping activities. It influences the farmer’s interest in diversified agriculture and therefore making adjustments within their irrigation resources for resource optimization [33,56]. Canal outlets are the exit points of irrigation canals from where water is distributed among various farms. Farms near to canal outlet receive generally more water, as longer distances could lead to more water loss during the channel flow. This might not always be true, considering soil texture and lining of water distribution channels [48,57,58].
- The third set of variables are related to the cropping system, as it includes Simpson cropping diversity that takes care of spatial heterogeneity, and rotation diversity that caters to the multi-temporal pattern of cropping practices. According to [59], cropping and rotation diversity could influence crop conditions and water utilization due to improved soil conditions. Healthier soils result in better soil moisture-holding and improved irrigation water delivery at farms. The Simpson Diversity Index (SDI; [60]) reflects the probability of the next crop species being another species, thus indicates the spatial pattern of cropping diversity in a certain region [52,61]. It can be measured as below:
4.6.2. Implementation of Random Forest Regression modelling
4.7. Statistical Analyses
5. Results
5.1. The Status of Canal Water Supply and Rainfall
5.2. Land Use Land Cover Mapping
5.3. Plausibility Analysis of SEBAL Results
5.4. Analysis of Consumptive Water Use
5.4.1. Crop Water Consumption in Rechna Doab
5.4.2. Crop Water Consumption in Irrigation Circles
5.4.3. Crop Water Consumption in Irrigation Divisions
5.4.4. Crop Water Consumption in Irrigation Subdivisions
5.4.5. Water Consumption by Major Crops of Rechna Doab
5.5. Performance Assessment Results
5.5.1. Equity
5.5.2. Adequacy
Overall Consumed Ratio (ep)
Relative Water Supply (RWS)
Relative ET
5.5.3. Reliability
Temporal Variation of EF
Crop Water Deficit (CWD)
5.6. Indicators/Variables Importance Assessment
5.6.1. Importance Assessment by Different Seasons
5.6.2. Importance Assessment by Crop Types
5.6.3. Importance Assessment by Overall Consumptive Water Use
6. Discussion
6.1. Validation & Plausibility Assessment
6.2. Irrigation Source and Consumptive Water Usage
6.3. Canal Water Supplies and Irrigation System Performance
6.4. The Current Balance of Crop Water Usage and Required Actions
7. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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Predictor Variable Name | Type | Description | Unit/Source |
---|---|---|---|
Slope (X1) | Site specific | Land suitability for irrigation: Higher slopes increase the irrigation efforts. | Percent slope as derived from Digital Elevation Model (DEM). |
Canal density (X2) | Site specific | Better access and availability to canal water. Short distances enable more crop diversity and facilitate the growth of higher delta crops (e.g., Rice, Cotton). | Km/km2, waterway layers were analyzed using the density function of the spatial analyst tool (ArcGIS). |
Road density (X3) | Site specific | Strong connectivity means better extension services from research and academia about the latest technologies. | Km/km2, polylines of open street map were analyzed using the density function of the spatial analyst tool (ArcGIS). |
Soil texture (X4) | Site specific | Categorical information about soil distribution: A variable that influences water demand, varying crop rotation, and other crop inputs. | Zones of major soil types were extracted from spatial data collected from IWMI, Pakistan |
Elevation (X5) | Site specific | Terrain elevation from GTOPO at 1km resolution. A higher elevation means higher energy demands for pumping irrigation water and decreased irrigation demands due to more precipitation. | GTOPO30 global Digital Elevation Model (DEM), https://earthexplorer.usgs.gov/. |
Water bodies distance (X6) | Proximity | Fewer distances mean better environmental conditions and better irrigation water availability in the vicinity regions. | Meter, Euclidean distance measured with geospatial data collected from Punjab Irrigation Department, GOVT of Punjab, Pakistan. |
Canal distance (X7) | Proximity | Long distances imply a reduced amount of irrigation water availability and vice versa due to decrease flow and higher transmission losses. | Meter, Euclidean distance measured with geospatial data collected from Punjab Irrigation Department, GOVT of Punjab, Pakistan. |
Road distance (X8) | Proximity | Better access to field and irrigation systems for improved management of the agricultural system. | Meter, Euclidean distance measured with open street map. |
City distance (X9) | Proximity | Near infrastructure is assumed to increase management skills due to advisory services, and also easy and economical access to the latest technologies, along with more demand for water for human needs, etc. | Meters, Euclidean distance measured with open street map. |
Population density (X10) | Site specific | Better services availability with bigger cities. Adversely affecting agricultural inputs due to small landholdings, resulting in lower farming interest. More population density leads to more demand for domestic human consumption. | Density/arc-second, https://sedac.ciesin.columbia.edu/data/set/gpw-v3-population-density/data-download. |
Mogha (outlet) distance (X11) | Proximity | Similar to canal distances, but at a higher level. Lower distances mean better availability of irrigation water to crops | Meter, Euclidean distance measured with geospatial data collected from Punjab Irrigation Department, GOVT of Punjab, Pakistan. |
Cropping diversity (Simpson) (X12) | Cropping system | Simpson index of cropping diversity. | Dimensionless. |
Rotation diversity (multi-temporal) (x13) | Cropping system | Simpson index of the diversity of crop types from 2010–2015. | Dimensionless. |
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Usman, M.; Mahmood, T.; Conrad, C.; Bodla, H.U. Remote Sensing and Modelling Based Framework for Valuing Irrigation System Efficiency and Steering Indicators of Consumptive Water Use in an Irrigated Region. Sustainability 2020, 12, 9535. https://doi.org/10.3390/su12229535
Usman M, Mahmood T, Conrad C, Bodla HU. Remote Sensing and Modelling Based Framework for Valuing Irrigation System Efficiency and Steering Indicators of Consumptive Water Use in an Irrigated Region. Sustainability. 2020; 12(22):9535. https://doi.org/10.3390/su12229535
Chicago/Turabian StyleUsman, Muhammad, Talha Mahmood, Christopher Conrad, and Habib Ullah Bodla. 2020. "Remote Sensing and Modelling Based Framework for Valuing Irrigation System Efficiency and Steering Indicators of Consumptive Water Use in an Irrigated Region" Sustainability 12, no. 22: 9535. https://doi.org/10.3390/su12229535
APA StyleUsman, M., Mahmood, T., Conrad, C., & Bodla, H. U. (2020). Remote Sensing and Modelling Based Framework for Valuing Irrigation System Efficiency and Steering Indicators of Consumptive Water Use in an Irrigated Region. Sustainability, 12(22), 9535. https://doi.org/10.3390/su12229535