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Article

From Land Cover to Land Use: A Methodology to Assess Land Use from Remote Sensing Data

1
IBADER, GI-1934 TB Department of Botany, University of Santiago de Compostela (Lugo Campus), E-27002 Lugo, Spain
2
Forest Department, United Nation Food and Agriculture Organization, Viale Terme di Caracalla, I-00153 Rome, Italy
*
Author to whom correspondence should be addressed.
Remote Sens. 2012, 4(4), 1024-1045; https://doi.org/10.3390/rs4041024
Submission received: 18 February 2012 / Revised: 5 April 2012 / Accepted: 6 April 2012 / Published: 17 April 2012

Abstract

:
The “land use” concept has evolved during recent decades and it is now considered as the socioeconomic function of land. Land use representation and land use change assessment through remote sensing still remains one of the major challenges for the remote sensing scientific community. In this paper we present a methodological approach based on remote sensing techniques to assess land use in accordance with the requirements of the United Nations Framework Climate Change Convention, UNFCCC (1995). The methodology is based mainly on the recognition of the land key elements and their function and on the adoption of the “predominant land use” criteria in the classification scheme settled by rules. The concept that underpins these rules is that the land use function of land can be expressed through hierarchical relationships among key land elements, and that these functional relationships are based on thresholds reflecting the relevance and predominance of key land elements in the observed area. When analyses are supported by high (10–30 m) or very high (<10 m) spatial resolution remote sensing data, the methodology provides a systematic approach for the representation of land use that is consistent with the concepts and methodologies developed by the International Panel on Climate Change(IPCC) to fulfill UNFCCC commitments. In particular, data with high and very high spatial resolution provide good results, with overall accuracies above 87% in the identification of key land elements that characterize land use classes. The methodology could be used to assess land use in any context (e.g., for any land use category or in any country and region) as it is based on the definition of user/project rules that should be tailored on the land use function of any territory.

Graphical Abstract

1. Introduction

Often confused and ambiguously replaced with land cover, the ‘land use’ concept has evolved over recent decades to be primarily considered as the socioeconomic function of land. While land cover and land cover change detection by satellite imagery have been one of the main aims of the evolution of technologies and methodologies from the beginning of the remote sensing (RS) era, land use recognition and land use change assessment through RS still remain major challenges for the RS scientific community.
It is recognized that large-scale changes in land use and land cover have occurred over the last few centuries and that this can have significant consequences on the functioning of the Earth System [1]. In fact, it has been estimated that 35% of anthropogenic emissions (measured in CO2 equivalents) originated from land use/cover changes [2,3] and therefore land use is considered to be a primary force in determining human impacts on ecosystems and the climate system. As the scientific community generated increasing amounts of evidence on the impacts of land use on surface-atmosphere energy exchanges, the carbon and water cycles, and the provision of ecosystem goods and services, these issues and interactions together became one of the focal points on the global environmental change research agenda [38]. Consequently, changes in land and ecosystems and their implications for global environmental change and sustainability are a major research challenge for the so-called ‘land change science’ [3].
The UNFCCC [9] specified that Parties should report on greenhouse gas (GHG) emissions by sources and removals by sinks resulting from direct human-induced land use change and forestry activities. National GHG inventories, as set out by the IPCC, should be transparent, complete (all land within a country should be included), internally consistent over time, comparable between countries, accurate and adequate (i.e., capable of accounting for land use categories and land use changes). Consequently, information on land cover and land use is becoming increasingly important for policy-making, business and environmental planning from the global to local scale. The collection and analysis of high quality land use and land use change data are therefore major research challenges and essential to the fulfillment of UNFCCC requirements. In this context, we argue that satellite RS imagery represents a valuable and cost-effective tool which could be particularly useful in filling the gaps in the availability of data regarding Land Use, Land Use Change and Forestry (LULUCF) activities [10] for different levels of data needs [11].
In this paper we present a methodological approach based on RS techniques to assess land use in accordance with the UNFCCC requirements. The methodology is based primarily on the recognition of the land key elements, the assessment of their socio-economic functions and the adoption of the “predominant land use” criteria in the classification scheme.

2. The Evolution of the Land Use Concept

The land use representation starts from the assessment of the land cover (the observed physical cover of the Earth’s surface [12]). During the last few decades the land use concept has been defined in two different ways: the activities undertaken on a surface that induce land cover transformation (the management dimension); and the purpose underlying that transformation (the functional dimension) [416]. Land use dynamics are a major determinant of land cover changes [17].
To improve the understanding of land-use/land-cover relationships, land use must be linked to human actions [14] and, specifically, to the economic drivers behind these actions. In recent years, international organizations (such as the Food and Agriculture Organization of the United Nations, FAO; and the Statistical Office of the European Union, EUROSTAT) and global analyses [8,1820] have focused on the functional dimensions of land use and the socio-economic functions of the land.
The UNFCCC, and the IPCC, identified the use of land as one of the key factors to address in order to account for GHGs emissions to the atmosphere. In 2000, the Global Forest Resource Assessment (FRA 2000) of the FAO [21] defined forest as a land use class and the deforestation process as a land-use change. It is interesting to recall the process that FAO followed in order to change its forest definition: in the first phase of FRA 2000, forest was considered a land cover class “with a continuous vegetation cover in which tree crown cover exceeds 10 percent”, while the official FRA 2000 definition specified that “forests are determined both by the presence of trees and the absence of other predominant land uses”. Thus, forest was considered a land use class, with the FRA 2000 specifying that “one driving factor behind this re-examination was the request for input to the Kyoto Protocol of the UNFCCC process and the elaborations on carbon sequestration in forests”. The FRA 2005 further elaborates the forest definition by making explicit that forest: “does not include land that is predominantly under agricultural or urban land use” and considers that “forest is land spanning more than 0.5 hectares with trees higher than 5 meters and a canopy cover of more than 10 percent, or trees able to reach these thresholds in situ”.
In Europe, a further activity led to a revision of the land use concept: the Land use/cover area frame survey (LUCAS) project of EUROSTAT [22], which considered land use as the description of the socio-economic function of the land.
Under the UNFCCC, all countries agreed on several commitments (Art. 4 of the Convention), one of them being the development of national inventories of all GHGs using comparable methodologies to be agreed upon by the Conference of the Parties. The task of developing these “comparable methodologies” was assigned to the IPCC, which developed guidelines and guidance, such as the 2003 Good Practice Guidance for Land Use, Land Use Change and Forestry (GPG-LULUCF) [10] and the 2006 IPCC Guidelines for National Greenhouse Gas Inventories for Agriculture, Forestry and Other Land Uses (GL-AFOLU) [23]. In these documents six broad categories of land uses were defined: Forest land, Cropland, Grassland, Wetlands, Settlements, Other land. Each category is further subdivided into two sub-categories: land category remaining in the same land category and land converted to the land use category in question. Only broad and non-prescriptive definitions are provided for these land use categories: countries may use their own definitions, which may or may not refer to internationally accepted definitions (e.g., FAO) and may be stratified (e.g., by climate or ecological zones), so that the emissions/removals can be estimated at an appropriate level of detail [11].
The RS scientific community has invested much effort in improving techniques for the detection of land cover and land cover change since the 1970s (when the first satellite specifically designed to collect data on the Earth’s surface was launched by the USA: Earth Resources Technology Satellite, ERTS-1). Improvements in the technical capabilities of the sensors (not only spatial, spectral and temporal resolutions but also the characterization and calibration of different sensors) and the new potentialities of satellites and image processing algorithms represent an authentic technological revolution for the observation of the Earth. However, land use recognition through RS is still not considered feasible, because the use of land depends not only on the land cover elements but also on their social and economical properties. For instance, depending on their human use, a group of trees could be classified as forest, cropland or settlement.
To respond to the above-outlined scientific challenges, this paper describes a method to assess land use through RS. This method is based on a systematic approach that avoids theoretical ambiguity between land cover and land use. The technical constraints which may hinder the proposed approach are also explained and discussed.

3. The Evolution of RS Technologies

RS has played a key role in the monitoring of the magnitude of climate change effects [24] and especially of the relevance of land use change which represents one of the main drivers of change [2,4,25]. Long-term, multispectral satellite observations since the early 1980s are the basis for understanding the dynamics of terrestrial vegetation and responses to changes in the climate and human land use [26].
The need and urgency to characterize and quantify human-actions on climate change persuaded the international community to include several specific reporting requirements under the UNFCCC, in light of the technical-scientific capabilities of countries to assess, and report on, human-induced GHG emissions and removals.
Following the IPCC’s methodologies for the LULUCF sector, RS data can be used to support activity data estimation (area extension and area change extension). Yet there are a number of challenges to using a RS based approach, for example, the definition of forest land with a minimum area of land between 0.05–1.0 ha (agreed in the Marrakesh Accords) [27] that requires a minimum spatial resolution (from very high resolution to high resolution, e.g., from sub-meter to 30–40 m pixel resolution).
The potential of RS to assist countries in fulfilling their reporting requirements under the UNFCCC is also useful for obtaining area estimates of land use categories and land use changes for the historical trend (e.g., the establishment of a 1990 baseline) or for the quantification of emissions and removals due to land disturbance processes (e.g., fire, landslides, etc.).
The development of RS technologies has expanded our capacity to monitor the Earth’s surface through the improvement of spatial, temporal and spectral resolutions of RS data. In the meantime, there has also been fast development of RS techniques to investigate and analyze ecosystems, basins, regions and continents [30]. However, with the realization of global (e.g., GlobCOVER of the European Space Agency) [31] and regional (e.g.,: TREES Project, of the Joint Research Centre of the European Union) [32] RS Earth observation projects, the scientific community realized that there were intrinsic limits to the identification of changes occurring on land using low and medium spatial resolution satellite data. Today, due to the rapid development of satellite technology (see Table 1), it is possible to investigate and conduct analysis at stand, and even tree, scale. These RS achievements allow the detection of different land elements using satellite imagery and thus now make possible the evaluation and identification of land uses, which is the focus of this paper. Indeed, very high spatial resolution images have a pixel resolution on the ground smaller than the size of a tree crown: they provide many pixels per object rather than many objects in a single pixel [33,28]. This therefore facilitates the identification of almost all key land elements (See Figure 1). The analysis of pixel combinations allows the analysis of the spatial combination of key land elements, which will be the first step towards the identification of land uses by RS.

4. Methods

In this article, the term Land use refers to the description of the socio-economic function of the land; Land cover is considered to be the observed physical cover of the Earth’s surface (for the purpose of this paper the definitions developed by EUROSTAT in its LUCAS project have been adopted [22]). Key land element is defined as a physical component of the land that characterizes one or more land cover classes and/or land use categories.
The methodology set out in this paper focuses on the analysis of the function of the key land elements and on the possibility of detecting them through RS data. Both land cover and land use concepts are based on the analysis of the spatial aggregation of elements present in the land (There may be some exceptions, e.g., area with no land elements but that still fall under a specific land use, such as firebreaks that would be considered as Forest land). For land cover, it is most often the extension and homogeneity of land elements by aggregation that determine a class, while for land use it is often the economic value of the different land elements that characterizes the predominant land use category. For example, the key land element which characterizes forest (land cover) and forest land (land use) is the tree: once we are able to detect it, it will be its spatial and functional relationship with other key land elements that will determine which land cover class or land use categories the area will fall under. Thus the critical step to determine land cover and land use through RS application is the detection of the single land element. The spatial dimension of the key land elements (see Table 2) has a wide range, varying from less than one meter to more than one kilometer. The capacity to detect all or almost all of the key land elements is then strongly correlated to the spatial resolution on the ground of the RS data and also in part to the spectral or radiometric resolution. In general, when the pixel spatial resolution is lower than the dimensions of the land elements, then the single land elements should be detectable. However, if the pixel spatial resolution is larger than the dimension of the land elements, it will be not possible to detect the single elements, but their presence will have to be determined through an analysis of the pixel’s spectral properties which then will be used in texture and object-oriented analyses, etc. (Figure 2).
Another factor which affects the capacity to detect the key land element is the methodology used to elaborate the RS data. In general, to detect the single elements, the methodologies which analyze the single pixel or single object properties may be more appropriate, but the choice of a determinate methodology will depend on the land properties, as the performance of methodologies may vary according to the data used and the characteristics of land elements. In this paper, different methodologies have been tested with the intention of demonstrating that the methodology to assess land use may be applied in combination with the most common approaches for image processing (e.g., pixel based and object oriented). Some results are presented in this paper as examples while others are available in the online supporting materials.
Once detection of the key land elements has been carried out, the land cover is determined by the presence and spatial distribution of the land elements on the surface. The land cover classification through RS images is generally undertaken through the identification of homogeneous areas following geometric, contextual and radiometric characteristics. If the data (pixel spatial resolution lower than land elements dimension) and methodology allow the detection of all land elements, the land cover assessment is not required for the land use assessment. While if the data (for instance, if the pixel spatial resolution is greater than the dimensions of land elements) and the methodology do not allow the detection of all the key land elements, then the land cover assessment is a necessary step for the land use assessment. In this paper we do not discuss the method used to assess the land cover as many methodologies have already been developed and most of them are suitable to be used within the proposed methodological approach to assess land use. If the assessment of the land use has to be realized through a multi-temporal approach and with the use of different RS data than a harmonized approach to assess land cover, such as the Land Cover Classification System, LCCS [34], could facilitate the assessment of the land use.
The land use describes a function of the land, and all the possible functions (e.g., forest land, settlement, cropland, etc.) need a minimum area to be valid. Thus, to determine these land use functions, it is necessary to observe a portion of land so that the presence and the functional relationships among the key land elements may be assessed. The portion of land that should be observed may reflect the minimum mapping unit (mmu) of a land use category or it could be larger, additionally including the surroundings of the observed/sampling point.
With the suggested methodology, the assessment of the land use may follow two possible procedures: one which directly analyzes the spatial distribution and the relations between the key land elements, and another which analyzes the land cover distribution.
The first procedure requires RS data which allows the detection of the key land elements, e.g., orthophoto or very high resolution satellite images. Once the thematic product which reveals the position of all the key land elements is assessed (see Figure 3), the analysis of the distribution and functional relationship between them will be undertaken through spatial rules that assess the land uses that are present and identification of the predominant one. These rules are project- or user-dependent (the functional relationship between the same key land elements may change, according to different socio-economic conditions and national circumstances) and they are critical in order to proceed with the land use assessment and mapping. The concept that underpins these rules is that the land use function of the land can be expressed through hierarchical relationships between the key land elements and these functional relations are based on thresholds reflecting the relevance and predominance of key land elements in the observed area. An example for these rules is a hierarchical sequence such as settlement > cropland > forest land > grassland > wetland > other land, with a threshold of 20% for all of the land use categories to determine their predominance. In this specific case, if the minimum observed area shows that there is 10% settlement, 30% cropland, and 60% grassland, then the predominant land use of the observed area will be cropland, because the area occupied by the settlement land use category (the first one in the hierarchy) is less than the specified threshold (20%) (Figure 4 A.1; B.1; C.1). In the same case, the use of a different hierarchy such as grassland > cropland > settlement > forest land> wetland > other land, will produce a different result and the predominant land use of the observed area will be grassland (Figure 4 A.2; B.2; C.2).
The second procedure should be used when RS data do not allow the detection of the single key land elements, e.g., Landsat data or coarser spatial resolution where the pixel dimension on the ground exceeds the dimension of the key land elements. In this case, the intermediate step is a pixel-based land cover layer (map) which is used as the best proxy to reflect the presence of key land elements. The spatial rules to assess the land use will be directly applied to the land cover information. The land cover information will be pixel-based and the land use rules will be applied through a matrix of pixels where the predominance will be assessed through thresholds (a 2 × 2 matrix will enable only thresholds which are multiples of 25%, while a 3 × 3 matrix will enable thresholds that are multiples of 11%). An example for this second procedure is a hierarchical sequence such as settlement > cropland > forest land > grassland > wetland > other land, with a threshold of 20% for all the land use categories to reveal their relevance. In this specific case, if we analyze a 3 × 3 matrix (almost one hectare with Landsat ETM+ data) and there is one pixel classified as settlement, two pixels classified as cropland, and six pixels classified as grassland, then the predominant land use of the observed area will be cropland (Figure 5 A.1; B.1; C.1). In the same example, if thresholds are modified and a threshold of 5% in settlement, 10% in croplands and 15% in forest land are decided, the predominant land use of the observed area will be settlement (Figure 5 A.2; B.2; C.2).
Figure 4 A.3 represents another example using a very high spatial resolution image with the hierarchical sequence settlement > cropland > forest land > grassland > wetland > other land, but in this case with the thresholds being: 10% in settlements; 20% in croplands; 30% in forest lands; and 50% in grasslands and wetlands, to express their predominance. In this specific case, if in the minimum observed area (as an example, of 1 ha) there is 6% of settlement, 15% of cropland, 56% of forest land, 16% grassland, and 7% of wetland (Figure 4 B.3), then the predominant land use of the observed area will be forest land (Figure 4 C.3). While with the hierarchical sequence forest land > settlement > cropland > grassland > wetland > other land, and the thresholds being: 20% in forest land; 20% in settlement and 30% in croplands, the predominant land use of the observed area will again be forest land (Figure 4 A.4; B.4; C.4).

5. Results and Discussion

The next Figure (Figure 6) shows the results obtained after applying the methodology, with different rules, on the same heterogeneous European landscape of Northwestern Spain. Using a very high spatial resolution image (QuickBird satellite with 2.8 m of spatial resolution), 1 km2 of surface was analyzed and six classes of key land elements were identified by means of a maximum likelihood algorithm based on pixels (See Figure 3), showing a global accuracy of 93.9% with a Kappa value of 0.883. A hierarchical sequence of settlement > cropland > forest land > grassland > wetland > other land was then applied in both cases, but in the Study Case 1 (Figure 6 A.2; B.2) a threshold of 30% was applied in all the land uses. In the Study Case 2 (Figure 6 A.3; B.3) the thresholds applied were as follows: 10% in settlements; 20% in croplands; 30% in forest lands; and 50% in grasslands and wetlands, to express their predominance. Again, 1 ha was considered as the minimum observed area that was symbolized as a zonal grid of 1ha. Results of both tests show relevant differences in both the number and type of land use classes identified as the proportion of the different land uses, reflecting the expression of different possibilities in the land use functions of the land (Figure 6 C.2; C.3).
The results presented in this paper demonstrated that different ways to represent land use are always possible, and in general there will never be an objective option. The most appropriate result will have to be assessed following the rules adopted to assess the land use function of the territory. These rules that support the results should be decided in light of local or national circumstances and socioeconomic functions and they will therefore be user dependent. As an example in this paper we have compared the results with the European CORINE Land Cover map 2000 ( http://www.eea.europa.eu/data-and-maps/data#c12=corine+land+cover+version+13). CORINE map is a well-known European cartography that partly applies a land use concept. In this study area, CORINE draws two categories of land use/cover: (a) Land principally occupied by agriculture, with significant areas of natural vegetation; and (b) Complex cultivation patterns. It allows us to visually represent the hierarchy and thresholds applied in Case 1 that best reflect the land use function (Figure 6 B.4; C.4), showing an overall accuracy of 82.0% with a Kappa value of 0.460 in Case 1 and an overall accuracy of 80.0% with a Kappa value of 0.339 in Case 2 (it is important to note that the relevance of the correspondence with CORINE is, in this example, only relative).
As reported above, this paper does not discuss the method to assess land cover, as many methodologies are suitable for use within the proposed methodological approach to assess land use. Moreover, this methodology could be applied with any optical, RADAR or LIDAR RS data. The only limitation that concerns this approach is the data suitability in the recognition of the land elements and the consequent accuracy of the land cover representation. Figure 7 shows the influence of spatial resolution on the number and categories of land elements/covers identified, and finally on the recognized land uses on a real European landscape (NW Spain). Images with different spatial resolutions were used (2,8 m; 10 m; 30 m; 60 m; and 250 m) in an area of 1 km2, and key land elements or covers were identified by means of a maximum likelihood algorithm based on pixels. Global accuracies and Kappa values of the different classifications are shown in Table 3, as well as the number and categories recognized. The number of identified land use categories decreases as spatial resolution decreases. But high spatial resolution (like Landsat with 30 m) shows good overall accuracy (87.0%) and results (in terms of the number and type of land use categories identified).In some cases, Landsat class data might be considered the optimal data source, as they provide a good balance between adequate spectral, spatial and temporal resolutions.
The methodology presented in this paper may facilitate a consistent land uses representation over time. The wide availability of RS data and the capacity of the methodology to change/adapt the rules for the data analysis will allow countries to adopt it and more easily provide land use and land use change data in the context of UNFCCC. The cases presented in this paper demonstrate that it is possible to obtain an appropriate representation of the land uses when Landsat class data or data with higher spatial resolution are available. This opens the way for a good prospect for an appropriate and consistent representation of land use through RS as a new generation of high resolution class satellites are going to be available soon (Sentinel-ESA, http://www.esa.int/esaLP/SEM3ZT4KXMF_LPgmes_0.html; Landsat-8 USA, http://landsat.gsfc.nasa.gov/; CBERS-3 Brazil-China, http://www.cbers.inpe.br/index.php). When data allow the application of the two methodological approaches, with or without the preliminary land cover assessment, the result is not in large differences in the land use representation, and both could represent an appropriate solution. Users will have to select the approaches that, following their specific land use hierarchal rules, will generate a more appropriate representation of the land use functions of the territory.

6. Conclusions

This paper presents a methodology to consistently represent land use and land use changes through remote sensing data. This methodology is based on the analysis of the spatial distribution and functional relationships of key land elements. When the analyses are supported by remote sensing data with high (Landsat class data, 10–30 m) or very high (<10 m) spatial resolution, the methodology provides a systematic approach for the classification and assessment of land use that is consistent with the methodological guidance and guidelines developed by International Panel on Climate Change for a reliable land representation under the United Nations Framework Climate Change Convention. The cases presented in this paper demonstrate that it is possible to obtain an appropriate representation of land uses when Landsat class data or data with higher spatial resolution are available. With these data the methodology provides good results, with overall accuracies above 87% for the identification of key land elements with the capacity to assess/classify the six IPCC land use categories.
The methodology may be used in any context (e.g., for any land use category or in any country and region) and with any spatial assessment approach (wall-to-wall or sampling) as it is based on the definition of user/project rules reflecting the land use function of the territory. The concept that underpins these rules is that the land use function of the land can be expressed through hierarchical relationships between the key land elements and these functional relations are based on thresholds reflecting the presence, relevance and predominance of the key land elements in the observed area. This article is a first attempt to open a scientific discussion on the possibility to identify land use through remote sensing data. Unfortunately, in the scientific literature, there are few references to this subject and often land use is still confused with land cover. Remote sensing data are now freely available and in the near future these data are going to have better spatial and spectral resolutions (e.g., Landsat 8 from NASA and Sentinel from ESA). In this respect the proposed methodology that is mainly based on the use of these data could represent a step forward for a more consistent, easier and systematic assessment of the socioeconomic functions of the land.

Acknowledgments

The authors thank Sandro Federici for his fruitful comments, ideas and suggestions on this paper. We would also like to thank three anonymous reviewers for their useful comments on the manuscript. Special thanks go to Joel Scriven. The Autonomous Region of Galicia (Spain) has financed Susana Martínez for this study through the Research Program PGIDT-INCITE-Xunta de Galicia.

References

  1. Ramankutty, N.; Foley, J.A. Estimating historical changes in global land cover: Croplands from 1700 to 1992. Global Biogeochem. Cy 1999, 13, 997–1027. [Google Scholar]
  2. Foley, J.A.; DeFries, R.S.; Asner, G.P.; Barford, C.; Bonan, G.; Carpenter, S.R.; Chapin, F.S.; Coe, M.T.; Daily, G.C.; Gibbs, H.K.; et al. Global consequences of land use. Science 2005, 309, 570–574. [Google Scholar]
  3. Turner, B.L., II; Lambin, E.F.; Reenberg, A. The emergence of land change science for global environmental change and sustainability. Proc. Natl. Acad. Sci. USA 2007, 104, 20666–20671. [Google Scholar]
  4. Lambin, E.F.; Geist, H.J. Land-Use and Land-Cover Change: Local Processes and Global Impacts; Springer: Berlin, Germany, 2006. [Google Scholar]
  5. DeFries, R.S.; Bounoua, L. Consequences of land use change for ecosystem services: A future unlike the past. GeoJournal 2004, 61, 345–351. [Google Scholar]
  6. IPCC, Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. In Climate Change 2007: The Physical Science Basis; Solomon, S.; Qin, D.; Manning, M.; Chen, Z.; Marquis, M.; Averyt, K.B.; Tignor, M.; Miller, H.L. (Eds.) Cambridge University Press: Cambridge, UK and New York, NY, USA, 2007; p. 996.
  7. Houghton, R.A. Revised estimates of the annual net flux of carbon to the atmosphere from changes in land use and land management 1850–2000. Tellus 2003, 55, 378–390. [Google Scholar]
  8. Lambin, E.F.; Turner, B.L., II; Geist, H.J.; Agbola, S.B.; Angelsen, A.; Bruce, J.W.; Coomes, O.T.; Dirzo, R.; Fischer, G.; Folke, C.; et al. The causes of land-use and land-cover change: Moving beyond the myths. Glob. Environ. Change 2001, 11, 261–269. [Google Scholar]
  9. UNFCCC. Report of the Conference of the Parties on Its First Session, FCCC/CP/1995/7/Add.1; UN Framework Convention on Climate Change (UNFCCC): Berlin, Germany, 1995; p. 63. Available online: http://unfccc.int/resource/docs/cop1/07a01.pdf (accessed on 12 February 2012).
  10. Penman, J.; Gytarsky, M.; Hiraishi, T.; Krug, T.; Kruger, D.; Pipatti, R.; Buendia, L.; Miwa, K.; Ngara, T.; Tanabe, K.; Wagner, F. (Eds.) IPCC. Good Practice Guidance for Land Use, Land-Use Change and Forestry; Institute for Global Environmental Strategies (IGES); Intergovernmental Panel on Climate Change (IPCC): Hayama, Japan, 2003; p. 632. Available online: http://www.ipcc-nggip.iges.or.jp (accessed on 12 February 2012).
  11. Achard, F.; Grassi, G.; Herold, M.; Teobaldelli, M.; Mollicone, D. Use of Satellite Remote Sensing in LULUCF Sector.GOFC-GOLD Report No. 33; Global Observation of Forest and Land Cover Dynamics (GOFC-GOLD): Jena, Germany, May 2008; p. 25. Available online: http://www.fao.org/gtos/gofc-gold (accessed on 12 February 2012).
  12. Eurostat. Manual of Concepts on Land Cover and Land Use Information Systems; Office for Publications of the European Communities: Luxembourg, 2001; p. 93. Available online: http://ec.europa.eu/eurostat/ramon/statmanuals/files/KS-34-00-407-__-I-EN.pdf (accessed on 12 February 2012).
  13. Lambin, E.F.; Baulies, X.; Bockstael, N.; Fischer, G.; Krug, T.; Leemans, R.; Moran, E.F.; Rindfuss, R.R.; Sato, Y.; Skole, D.; et al. Land-Use and Land-Cover Change (LUCC). Implementation Strategy; IGBP Report 48; IHDP Report10; International Geosphere-Biosphere Programme and the International Human Dimensions Programme on Global Environmental Change: Stockholm, Sweden and Bonn, Germany, 1999; p. 125. [Google Scholar]
  14. Turner, B.L., II; Skole, D.; Sanderson, S.; Fischer, G.; Fresco, L.; Leemans, R. Land-Use and Land-Cover Change Science/Research Plan; IGBP Global Change Report No. 35 and HDP Report No. 7. International Geosphere-Biosphere Programme and the Human Dimensions of Global Environmental Change Programme: Stockholm, Sweden and Geneva, Switzerland, 1995. Available online: http://www.ihdp.unu.edu/article/read/lucc-sci-plan (accessed on 12 February 2012).
  15. Meyer, W.B. Past and present land use and land cover in the USA. Consequences 1995, 1, 25–33. [Google Scholar]
  16. Turner, B.L., II; Meyer, W.B.; Skole, D. Global land-use/land-cover change: Towards an integrated program of study. Ambio 1994, 23, 91–95. [Google Scholar]
  17. McConnell, W.; Moran, E.F. Meeting in the Middle: The Challenge of Meso-Level Integration; LUCC Focus 1 Office, Anthropological Center for Training and Research on Global Environmental Change, Indiana University: Ispra, Italy, 2001; p. 62. Available online: http://www.globallandproject.org/Documents/LUCC_No_5.pdf (accessed on 12 February 2012).
  18. Eva, H.; Lambin, E.F. Fires and land-cover change in the tropics: A remote sensing analysis at the landscape scale. J. Biogeogr 2000, 27, 765–76. [Google Scholar]
  19. Goldewijk, K.K.; Ramankutty, N. Land Use Changes during the Past 300 Years. Land Use, Land Cover and Soil Sciences. Encyclopedia of Life Support Systems (EOLSS); UNESCO: Ontario, Canada and Paris, France, 2004; 1. Available online: http://www.eolss.net/outlinecomponents/Land-Use-Land-Cover-Soil-Sciences.aspx (accessed on 12 February 2012).
  20. Verburg, P.H.; van de Steeg, J.; Veldkamp, A.; Willemen, L. From land cover change to land function dynamics: A major challenge to improve land characterization. J. Environ. Manage 2009, 90, 1327–1335. [Google Scholar]
  21. UN Food and Agriculture Organization (FAO). Global Forest Resources Assessment 2000, FRA 2000 Main Report; Forestry Paper 140. FAO: Rome, Italy, 2001; p. 479. Available online: http://www.fao.org/forestry/fra/2000/report/en/ (accessed on 12 February 2012).
  22. Eurostat. The Lucas Survey European Statisticians Monitor Territory; Office for Publications of the European Communities: Luxembourg, 2003. Available online: http://www.uni-mannheim.de/edz/pdf/eurostat/03/KS-AZ-03-001-EN-N-EN.pdf (accessed on 12 February 2012).
  23. Eggleston, H.S.; Buendia, L.; Miwa, K.; Ngara, T.; Tanabe, K. (Eds.) IPCC. 2006 Guidelines for National Greenhouse Gas Inventories, Prepared by the National Greenhouse Gas Inventories Programme; Institute for Global Environmental Strategies (IGES); IPCC: Hayama, Japan, 2006. Available online: http://www.ipcc-nggip.iges.or.jp/ (accessed on 12 February 2012).
  24. Mollicone, D.; Achard, F.; Eva, H.; Belward, A.S.; Federici, S.; Lumicisi, A.; Rizzo, V.C.; Stibig, H.J.; Valentini, R. Land Use Change Monitoring in the Framework of the UNFCCCC and Its Kyoto Protocol: Report on Current Capabilities of Satellite Remote Sensing Technology; European Commission, Directorate General, Joint Research Centre: Luxembourg, 2003; p. 48. Available online: http://publications.jrc.ec.europa.eu/repository/bitstream/111111111/10699/1/EUR%2020867%20EN.pdf (accessed on 12 February 2012).
  25. Verburg, P.H.; Neumann, K.; Nol, L. Challenges in using land use and land cover data for global change studies. Glob. Change Biol 2011, 17, 974–989. [Google Scholar]
  26. DeFries, R.S. Terrestrial vegetation in the coupled human-earth system: Contributions of remote sensing. Annu. Rev. Environ. Resour 2008, 33, 369–390. [Google Scholar]
  27. UNFCCC. The Marrakesh Accords and the Marrakesh Declaration, FCCC/CP/2001/137Add.1 (Annex, Section A); UN Framework Convention on Climate Change (UNFCCC): Marrakesh, Morocco, 2001. Available online: http://unfccc.int/resource/docs/cop7/13.pdf (accessed on 12 February 2012).
  28. Wulder, M.A.; Hall, R.J.; Coops, N.C.; Franklin, S.E. High spatial resolution remotely sensed data for ecosystem characterization. BioScience 2004, 54, 511–521. [Google Scholar]
  29. Global Observation for Forest and Land Cover Dynamics (GOFC-GOLD). A Sourcebook of Methods and Procedures for Monitoring and Reporting Anthropogenic Greenhouse Gas Emissions and Removals Caused by Deforestation, Gains and Losses of Carbon Stocks in Forests Remaining Forests, and Forestation, GOFC-GOLD Report Version COP17-1; GOFC-GOLD Project Office, Natural Resources Canada: Edmonton, AB, Canada, 2010; p. 209. Available online: http://www.gofc-gold.uni-jena.de/redd/ (accessed on 12 February 2012).
  30. Waring, R.H.; Running, S.W. Forest Ecosystems. In In Analysis at Multiple Scales, 2nd ed.; Academic Press: San Diego, FL, USA, 1998. [Google Scholar]
  31. Arino, O.; Gross, D.; Ranera, F.; Bourg, L.; Leroy, M.; Bicheron, P.; Latham, J.; Di Gregorio, A.; Brockmann, C.; Witt, R.; et al. GlobCover: ESA Service for Global Land Cover from MERIS. Proceedings of the IEEE International Geoscience and Remote Sensing Symposium, Barcelona, Spain, 23–27 July 2007; pp. 2412–2415. Available online: http://publications.jrc.ec.europa.eu/repository/handle/111111111/10701 (accessed on 12 February 2012).
  32. Achard, F.; Eva, H.; Stibig, H.J.; Mayaux, P.; Gallego, J.; Richards, T.; Malingreau, J.P. Determination of deforestation rates of the world’s humid tropical forests. Science 2002, 297, 999–1002. [Google Scholar]
  33. Strahler, A.; Woodcock, C.; Smith, J. On the nature of models in remote sensing. Remote Sens. Environ 1986, 20, 121–139. [Google Scholar]
  34. Di Gregorio, A.; Jansen, L.J.M. Land Cover Classification System (LCCS); FAO: Rome, Italy, 2000; p. 180. [Google Scholar]
Figure 1. The visual effects of the pixel ground resolution on land representation of the same area; (A) MODIS 250 m of spatial resolution; (B) AWIFS 55 m; (C) LANDSAT TM 30 m; (D) SPOT 10 m; (E) QUICKBIRD 2.8 m; (F) ORTHOPHOTO, 1/5,000. Universal Transverse Mercator Projection (UTM 29T); European Datum 1950 (ED50).
Figure 1. The visual effects of the pixel ground resolution on land representation of the same area; (A) MODIS 250 m of spatial resolution; (B) AWIFS 55 m; (C) LANDSAT TM 30 m; (D) SPOT 10 m; (E) QUICKBIRD 2.8 m; (F) ORTHOPHOTO, 1/5,000. Universal Transverse Mercator Projection (UTM 29T); European Datum 1950 (ED50).
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Figure 2. Methodological scheme.
Figure 2. Methodological scheme.
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Figure 3. Identification of the key land elements on a very high spatial resolution satellite image. (UTM Projection; ED50). (A) Quick Bird image, with 2.8 m of spatial resolution; (B) Identification of land elements using a pixel-based classification and maximum likelihood algorithm.
Figure 3. Identification of the key land elements on a very high spatial resolution satellite image. (UTM Projection; ED50). (A) Quick Bird image, with 2.8 m of spatial resolution; (B) Identification of land elements using a pixel-based classification and maximum likelihood algorithm.
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Figure 4. Land use function of the land determined through very high spatial resolution satellite images. (A) Hierarchies (with a decreasing order of prevalence) and thresholds for all the land use categories; (B) 1 ha of surface (blue square) representing the minimum observed area. Inside, white squares correspond to 10 m size pixels representing key land elements identified using a very high spatial resolution satellite image (B.1–B.4.); (C) Land use: it is determined after applying the hierarchy and threshold criteria (on the left) over the minimum observed area of 1 ha: cropland (C.1–C.4).
Figure 4. Land use function of the land determined through very high spatial resolution satellite images. (A) Hierarchies (with a decreasing order of prevalence) and thresholds for all the land use categories; (B) 1 ha of surface (blue square) representing the minimum observed area. Inside, white squares correspond to 10 m size pixels representing key land elements identified using a very high spatial resolution satellite image (B.1–B.4.); (C) Land use: it is determined after applying the hierarchy and threshold criteria (on the left) over the minimum observed area of 1 ha: cropland (C.1–C.4).
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Figure 5. Land use function of the land determined through high spatial resolution satellite images. (A) Hierarchies (with a decreasing order of prevalence) and thresholds for all the land use categories; (B) 1 ha of surface (blue square), representing the minimum observed area. Inside, white squares correspond to 30 m pixel size representing land covers identified using a Landsat image (B.1 and B.2); (C) Land use: it is determined after applying the hierarchy and threshold criteria (on the left) over the minimum observed area of 1 ha.
Figure 5. Land use function of the land determined through high spatial resolution satellite images. (A) Hierarchies (with a decreasing order of prevalence) and thresholds for all the land use categories; (B) 1 ha of surface (blue square), representing the minimum observed area. Inside, white squares correspond to 30 m pixel size representing land covers identified using a Landsat image (B.1 and B.2); (C) Land use: it is determined after applying the hierarchy and threshold criteria (on the left) over the minimum observed area of 1 ha.
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Figure 6. Application of the methodology on a real European landscape (NW Spain). (UTM Projection; ED50) (A.1) Key land elements mapping by using Quickbird with 2.8 m of pixel size and a maximum likelihood classification algorithm; (A.2 and A.3) Hierarchy following different thresholds for each land use categories; (B.1) 1 km2 surface: covered with a 1 ha zonal grid representing zones with the mmu of the land use category: 1 ha zones; (B.2 and B.3) Land uses: after applying the hierarchy and threshold criteria (on the left) and using 1 ha zones as minimum observed area; (B.4) European CORINE Land Cover map; (C) Total surfaces (%) of the different categories.
Figure 6. Application of the methodology on a real European landscape (NW Spain). (UTM Projection; ED50) (A.1) Key land elements mapping by using Quickbird with 2.8 m of pixel size and a maximum likelihood classification algorithm; (A.2 and A.3) Hierarchy following different thresholds for each land use categories; (B.1) 1 km2 surface: covered with a 1 ha zonal grid representing zones with the mmu of the land use category: 1 ha zones; (B.2 and B.3) Land uses: after applying the hierarchy and threshold criteria (on the left) and using 1 ha zones as minimum observed area; (B.4) European CORINE Land Cover map; (C) Total surfaces (%) of the different categories.
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Figure 7. Influence of spatial resolution on the number and categories of land elements/covers identified and on the recognized land uses, on a real European landscape (NW Spain) represented in an area of 1 km2. First column: (A) Key land elements mapping by using QuickBird with 2.8 m of pixel size and a maximum likelihood classification algorithm; (C; E; G; I) Land elements and covers by using images with 10 m, 30 m, 60 m and 250 m, respectively. Second column (B; D; F; H; J) Land uses after applying the following hierarchy: settlement > cropland > forest land > grassland > wetland > other land with 30% of threshold for each land use category over the classification on the left. (UTM Projection; ED50).
Figure 7. Influence of spatial resolution on the number and categories of land elements/covers identified and on the recognized land uses, on a real European landscape (NW Spain) represented in an area of 1 km2. First column: (A) Key land elements mapping by using QuickBird with 2.8 m of pixel size and a maximum likelihood classification algorithm; (C; E; G; I) Land elements and covers by using images with 10 m, 30 m, 60 m and 250 m, respectively. Second column (B; D; F; H; J) Land uses after applying the following hierarchy: settlement > cropland > forest land > grassland > wetland > other land with 30% of threshold for each land use category over the classification on the left. (UTM Projection; ED50).
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Table 1. Potentialities of optical satellite imagery.
Table 1. Potentialities of optical satellite imagery.
Resolution TypeSensorSpatial ResolutionSpectral Resolution (spectral Bands)Corresponding Minimum Land Use Mapping Unit * (ha)Potentially Identifiable Key Land ElementsIdentification Level
Coarse (250–1,000 m)NOAA-AVHRR1 km6900Broad land cover patternsGlobal/regional
SPOT-Vegetation1 km4
Terra-MODISUp to 250 m1056
Envisat-MERISUp to 300 m15
Medium (30–60 m)Landsat-MSS80 m56Separation of extensive masses of evergreen/deciduous forestStand level
IRS-AWIFS60 m43
High (10–30 m)Landsat-TM30 m7<0.8
Landsat-ETM+30 m MS/15 m P**8
Terra-ASTERUp to 15 m14
SPOT 4 HRV20 m MS/10 m P5
IRS-LISS III23 m MS/ 5,8 m P5
CBERS HRCCD20 m5
DMC32 m MS/4 m P4
Very high (<10 m)SPOT 510 m MS/2.5 m P4<0.1Recognition of large individual treesTree and stand level
IKONOS4 m MS/1 m P5
QuickBird2.8 m5
Source: modified from [28] and [29];
*(To assess the land use, a minimum matrix of 3 × 3 pixels is necessary);
**(MS multispectral; P panchromatic). Low-resolution sensors (such as TIROS and NOAA AVHRR launched in the 1960s, SPOT-VEGETATION launched in 1998, MODIS launched in 2000) carry out monitoring of broad land cover patterns at global or regional levels. Medium-resolution satellites, such as LANDSAT MSS (launched in 1972) with 80 m and high resolution satellites like Landsat TM with 30 m spatial resolution or SPOT (launched in 1986) are able to characterize features at landscape to regional level. Landsat was the first Earth-observation satellite system to include SWIR (Shortwave Infrared) channels which have become key factors in the study of forest vegetation [32]. Since the 2000s, very high spatial resolution sensors (IKONOS launched in 1999, QUICKBIRD launched in 2001) produce data at tree level (identification of tree crowns, forest structure and biomass estimation over small areas), approaching the quality of airborne photography. Besides, SPOT-5, with 10 m multispectral spatial resolution, has included a SWIR band since 2002. On the other hand, RADAR data (such as RADARSAT-2 SAR launched in 2007 or ALOS PALSAR launched in 2006) are particularly appropriate in tropical forest where clouds and high biomass present difficulties for passive sensors and at present they potentially provide very high spatial resolution.
Table 2. A list of key land elements subdivided by land use class. (For instance, any kind of infrastructure is a key land element for the settlement land use class).
Table 2. A list of key land elements subdivided by land use class. (For instance, any kind of infrastructure is a key land element for the settlement land use class).
Land Use CategoryLand Elements/or Key Elements
Forest landStanding trees, harvested trees
SettlementBuildings, paved roads, railroads
CroplandStanding crops, harvested crops
WetlandWater, grasses
GrasslandGrasses, scrubs (shrubs)
Other landIce, rock, snow, barren land
Table 3. Potential and accuracy assessment of different classifications in the study area.
Table 3. Potential and accuracy assessment of different classifications in the study area.
Spatial Resolution (m)Land Unit (1 km2)Number of Land–Element/Cover Categories IdentifiedLand–Element/Cover Categories Identified in the classificationAccuracy assessment (%)Kappa value
2.81 KM26Trees, Buildings, Grasses, Crops, Water, Paved Roads93.90.883
101 KM25Trees, Buildings, Grasses, Crops, Paved Roads89.30.793
301 KM23Trees, Settlements, Crops87.00.740
601 KM23Trees, Settlements, Crops77.10.538
2501 KM22Crops, Trees64.90.212

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Martínez, S.; Mollicone, D. From Land Cover to Land Use: A Methodology to Assess Land Use from Remote Sensing Data. Remote Sens. 2012, 4, 1024-1045. https://doi.org/10.3390/rs4041024

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Martínez S, Mollicone D. From Land Cover to Land Use: A Methodology to Assess Land Use from Remote Sensing Data. Remote Sensing. 2012; 4(4):1024-1045. https://doi.org/10.3390/rs4041024

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Martínez, Susana, and Danilo Mollicone. 2012. "From Land Cover to Land Use: A Methodology to Assess Land Use from Remote Sensing Data" Remote Sensing 4, no. 4: 1024-1045. https://doi.org/10.3390/rs4041024

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