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A Geographically-Based Land Use SuitabilityAssessment and Land Capability Classification
Item Type text; Proceedings
Authors Cruz, Rex Victor O.; Ffolliott, Peter F.
Publisher Arizona-Nevada Academy of Science
Journal Hydrology and Water Resources in Arizona and the Southwest
Rights Copyright ©, where appropriate, is held by the author.
Download date 21/05/2018 21:44:06
Link to Item http://hdl.handle.net/10150/296434
A GEOGRAPHICALLY -BASED LAND USE SUITABILITYASSESSMENT AND LAND CAPABILITY CLASSIFICATION
Rex Victor O. Cruz and Peter F. FfolliottSchool of Renewable Natural Resources
University of ArizonaTucson, Arizona 85721
Introduction
Land capability classification generally refers to thedescription and classification of lands relative to theirbiophysical features and ability to sustain various kinds ofuses. The USDA Soil Conservation Service land capabilityclassification guide is perhaps the most popular system everdeveloped so far (Klingebiel and Montgomery, 1961; andBrakensiek, et al., 1979). It has been modified and used inother countries including Israel, the Philippines, andZimbabwe (Hudson, 1981). In spite of its popularity, however,the USDA guide is based only on agronomic land uses and isqualitative in nature.
Classification systems developed in recent years aremore quantitative in nature as the understanding of therelationships among the different factors influencing soilproductivity and stability increases. For example, Larson etal. (1988) and Warren et al. (1989) developed classificationsystems based on estimated measures of productivity, soilresistivity, and soil erosion, respectively.
Land use suitability assessment is defined here as themeasurement and rating of the impacts of a land use on theproductivity and stability of an area. The impacts could bemeasured in terms of actual volume of production, decline insoil fertility, and the amount of soil erosion.
It is the purpose of this paper to describe amethodology for land use suitability assessment and landcapability classification based on estimated soil loss usingthe modified universal soil loss equation or MUSLE (Williams,1975), with the aid of a geographic information system (GIS).
The GIS
Soil erosion is influenced by many factors which aregeographic in nature, such as topography, soil properties,vegetation, and land use. As such, the use of a GIS wouldenhance the accuracy of soil erosion estimation. By dividingan area into smaller cells, the significance of geographic
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characteristics which would otherwise be diminished as aresult of parameter lumping when the area is treated as onewho'e unit is preserved.
Through the years, GIS has been defined in several ways(Burrough, 1986; Berry, 1986; Parker, 1988). It has beendefined as a set of tools, a technology, and an automatedspatial information system capable of processing spatial orgeographically- referenced information. Most GIS are capableof data input, data storage and retrieval, data manipulationand analysis, and data reporting.
Essentially, GIS can be applied to any activity wherespatial considerations are important, and where largequantities of data need to be processed and reprocessed over anumber of times. It has found many uses in natural resourcesmanagement, economics and marketing, regional and urbanplanning, and engineering.
Works by Berry and Sailor (1987), Gilliland andPotter(1987), Vasconcelos (1988), and Warren et al. (1989) areexamples of the many uses of different kinds of GIS. In thisstudy, Map Analysis Package (MAP) developed by Tomlin (1986)was used.
Study Area
The study area is located in the Ibulao Watershed,Philippines. It is a 65,000 -ha subwatershed of Magat RiverBasin which supports vast areas of agricultural lands.Existing land uses in Ibulao includes, forestry, grazing, andagriculture. The climate generally is humid, with an averageannual rainfall of 2,200 mm. Soils are mostly clay loam, withtopography ranging from flat to very steep and rugged terrain.
Assessment Method
There are four basic components to the methodologydescribed in this paper, namely MUSLE, capabilityclassification, land use suitability assessment, and GIS(Figure 1). Other components, RAINGEN, CREAMS, and IRSX areincidental to MUSLE for the estimation of the runoff factor.
The study area generally was divided into 10 -ha cells.For the entire watershed, different data overlays, such asslope map, soils map, elevation map, and land use map, wereprepared using MAP. From the data overlays, the features andparameters needed in the estimation of soil erosion,capability classification, and land use suitability
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RAINGEN- organize and analyzerainfall data
- simulate rainfallduration
CREAMS- perform water budgetanalysis
- compute for the soilmoisture
IRSX- simulate surface runoffvolume and the peakrunoff rate from eachcell
MUSLE- estimate the soil erosion
from each cell (for eachstorm event, annual)
CAPABILITY CLASSIFICATION- calculate the erosion
index for each cell- classify cells intocapability classesbased on soil erosionindex
iSUITABILITY ASSESSMENT- evaluate the suitabilityof each landuse based oncurrent legal land clas-sification, LCCG of thePhilippine Bureau ofSoils, and soil erosion
GIS Operations
MAP- organize and createsource data basemaps
- create derived maps(soils, slope, eleva-tion, landuse maps)classify the Ibulaowatershed into cellsof homogenous soil,slope, and landusefeatures
- estimate soil erosionfrom each cell
- create output over-lays (surface runoffand soil erosion maps)evaluate suitabilityof landuse for eachcell based on presentlegal land classifica-tion, LCCG, and soilerosioncreate suitabililtymaps based on presentlegal land classifica-tion, LCCG, and soilerosion
- create erodibility mapbased on soil erosionindex of each cellcreate capability mapbased on soil erodi-bility map
IDRISI- refine and organizeoutput overlays
- print out copies ofsource maps, derivedmaps, and outputmaps
Figure 1. Schematic Representation of the Generation and Flowof Information.
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assessment for each cell were extracted. In turn, the resultsfrom these components were passed back to MAP for processingthe various output overlays.
MUSLE
The general form of the MUSLE is shown as:
E = 11.8 (Q *q)0.56 K L S C P
where E is soil loss (Mg /ha) estimated as the product ofrunoff factor consisting of surface runoff depth (Q) and peakflow (q), soil erodibility factor (K), topography factor (LS),soil cover factor (C), and conservation practice factor (P).
The factors KLSCP were estimated using the proceduresdescribed by Williams and Berndt (1972), Wischmeier and Smith(1978), Dissmeyer and Foster (1980), and David (1985). Adetailed description of the parameter estimation is presentedby Cruz (1990).
The surface runoff and peak flow for each cell weresimulated using IRSX, which is a modification of theinfiltration- kinematic routing program (IRS9) developed by theUSDA -ARS (Stone and Shirley, 1985). Most of the parametersused by IRSX, such as soil porosity, hydraulic conductivity,depth- discharge coefficient, and soil moisture, also aregeographic in nature.
The soil moisture for each cell was estimated by thehydrology component of CREAMS, a field -scale model forchemical, Runoff, and erosion from Agricultural Managementaystems model (Knise1,1980). Likewise, most of the soilrelated parameters used in CREAMS simulation are geographic innature.
Land Capability Classification
Land capability classification is based on soil erosionindex (I). For each cell, the erosion index was estimated by:
I = [11.8 (Q*g)056 KLS] / T
where T is the soil loss tolerance which represents the amountof annual soil erosion that can be sustained by an areawithout jeopardizing its long term productivity. (The valueof T usually ranges between 2.2 and 11.2 t /ha depending upon
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the locally intrinsic rate of soil formation and soil depth;in this case, T was assumed to be 20 t /ha /year).
The capability class of a cell was identified using theestimated average annual erosion index (Table 1 and Figure 2).The different land use recommendations were determined bysolving for the maximum CP value (using the erosion indexequation) for a given capability that would yield an annualsoil erosion value not greater than the tolerance limit.
Land Use Suitability Assessment
Land use suitability in each cell was evaluated on thebasis of the estimated annual soil erosion. A land use in acell was rated suitable if the average annual soil erosion isless than or equal to the tolerance limit. Otherwise, landuse was rated unsuitable (Table 2 and Figure 3).
Applications
The land use suitability assessment and land capabilityclassification procedure described could be useful inidentifying the land use most suitable to a given area. Italso could provide a method of examining the status ofexisting land uses as far as impacts on soil productivity isconcerned. It could be used to identify which existing landuses need to be changed or if they cannot be changed, the toolcould help identify what kind of measures need to be taken tomitigate the adverse impacts of such land uses. Finally, themethod would be instrumental in determining the differentintensities of land uses that would best complement thecapability of an area.
Recommendations
An erosion -based land capability classification andland use suitability assessment is only as useful as the soilerosion estimation component. Therefore, improvements in theexisting tools for soil erosion estimation or development anduse of methods applicable to the area of concern always shouldbe considered.
The accuracy of results obtained from the methoddescribed in this paper also is largely a function of theaccuracy of the different input or source maps. In overlaying
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Table 1. Erosion -Based Land Capability Classification ofIbulao Watershed.
Capabilityclass
Erosionindex
Area(10ha)
Maximumallowable
CP
1 0 -2 286 0.500
2 3 -5 146 0.200
3 6 -10 311 0.100
4 11 -20 1069 0.050
5 21 -30 408 0.030
6 31 -50 2176 0.020
7 > 50 2052 0.010
Recommendedlanduse
unrestricted
grassland,riceterrace /paddy,agroforestry
grassland,riceterrace /paddy,limited agro-forestry
rice terraces,limited agro-forestry withconservationmeasures, forestry
rice terrace,forestry
limited riceterrace, forestry
limited to forestry
,,,,`.,..,
class 1
class 2
class 3
INM
MIND
class 4 -
LEGEND
class 5
class 6
class 7 -
;,.'';..,,:,.ii i:
Figure 2, Erosion -Based Land Capability Classificationof Ibulao Watershed.
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Table 2. Erosion Classes Coverage Under Different LandUses in Ibulao Watershed. (The values representthe number of 10 -ha cells).
Present Landuse
1 2
Erosion
3 4
Class
5 6 7 8 TOTAL
Forest
mossy 178 178
closed canopy 264 264
open canopy 2289 2289
Rice padd /terr 1177 320 1497
Open grass 68 234 62*
112* 116* 103* 583* 1278
Diverse crop 49 7 2 12* 126* 260* 251* 707
Nonvegetated 41 16 11* 14* 2* 11* 95
Residential 8 1* 4* 26* 39
Mainstream 45 5 4 2 10 35 101
TOTAL 4119 582 17 75 116 258 375 906 6448
* Rated unsuitable based on the average annual soil erosionloss.
LEGEND
suitable - unsuitable
Figure 3. Landuse Suitability Map of Ibulao WatershedBased on Soil Erosion.
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several maps, format considerations, such as map resolutionand projection, should be appropriately defined to keep thejoint probability of coincidence the same at all locations.
The success of using geographically -based tools forland use suitability assessment and land capabilityclassification also would depend upon the adequacy ofdefinition and quantification of the different spatialrelationships involved. For example, the relationship betweenneighboring cells as far as surface runoff generated from eachcell should be clearly defined and represented to obtainsatisfactory prediction or simulation results.
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