CLUSTER ANALYSIS FOR LANDSCAPE TYPOLOGY

This paper deals with the classification of landscapes by means of cluster analysis, having as a theoretical basis a typology of landscapes, through the notion of zonality by L. S. Berg and the theory of geosystems by V. B. Sochava. Firstly landscape mapping was performed using geoprocessing techniques resulting in 272 landscape units for the municipality of Mineiros (Goiás State, Brazil). This units were defined by union of different elements of morphostructures, lithology, landforms, altitude, slope degree, drainage density, soils and land use. The objective of this work is to compare different forms of grouping to establish the typology of landscapes using an upscaling/bottom-up approach. The similarity coefficient Jaccard, Euclidean Distance metric and k-means algorithm were evaluated. Even though the field validations and statistical tests point to a different scenario, it was considered that the Jaccard and Euclidean Distance metrics presented satisfactory scenarios for the representation of the landscapes. The grouping was important in the optimization of processes, although there is a need to differentiate between statistical and spatial significance. Therefore, the relevance of this technique is in the collaboration to group and redefine a large amount of information that, by means of manual analysis and spatial regrouping, would present excessive delay.


INTRODUCTION
In Physical Geography, notable that landscape units in different locations may have similar structural characteristics. The typologies that classify these units (ISACHENKO, 1991) are created through theoretical generalizations. A typology is a classification system (taxonomy) of landscapes' structure, based on similar elements with a characteristic spatial dimension, grouped utilizing defined criteria, which may or not be subordinate.
Typology allows geosystems to be distinguished by their similarity (homogeneity) and repetition (spatiality) and has become essential in the study of landscapes. According to Rodriguez and Silva (2019, p.34), the classification of subdivisions is essential to understanding landscapes. At present, it is based on morphological and functional indicators and the subdivision of geosystems. The construction of a typology is based on the principles of analogy, homogeneity, replication, belonging to the same group, and the existence of areal discontinuities between their boundaries. From the perspective of multiscale analysis, the creation of a typology can take place in two ways (Figure 1), as highlighted by Cavalcanti and Corrêa (2013, p.153, emphasis added): Multiscale analyzes can still be classified by hierarchical detection. Starting from a large geographical scale towards smaller scales is a downscaling or top-down approach. Starting from small geographical scales towards larger scales is an upscaling or bottom-up approach. Classification is a complex process, which can involve a large number of elements that make up landscapes. In this context, a possible approach is statistical grouping (clustering) that creates models of associations of variables, with high numbers of landscape units 1 .
The precise objective of this work is to carry out a comparative assessment of different forms of grouping (clusters) to establish a landscape typology for the municipality of Mineiros, in the state of Goiás, Brazil, supported by the following factors: morphostructure, geology, geomorphology, altitude, slope, drainage density, soils, and land use and cover.

THEORETICAL REFERENCES
Representations of landscape syntheses use at least three approaches through a taxonomic classification system: typology, regionalization, and topology. This makes it possible to create landscape Mercator, Fortaleza, v.19 , e19011, 2020. ISSN:1984-2201 2/16 CLUSTER ANALYSIS FOR LANDSCAPE TYPOLOGY unit maps on different scales and in different conditions (environmental and territorial), as part of the landscape cartography.
As well as providing a spatial representation, they can show groupings of individuals (the delimitation of spatial sets in homogeneous zones) characterized by groupings of attributes or variables that are commonly understood through different landscape units (ZACHARIAS, 2008;SALINAS CHÁVEZ et al., 2019).
The concept of typologies emerged through Berg's zonality principles (1947) and continues to develop today through the application of multivariate analyzes, which are considered a fundamental step in the definition and logical treatment of landscapes' sectoral parameters (BERUTCHACHVILI and BERTRAND, 1978).
Typology involves the classification of landscapes according to their structure and consists of homogeneous (similar) elements based on the interests and the scale of analysis of the study in question. According to Rodríguez and Silva (2002, p. 98), "Typology means distinguishing units by their similarity and repetition, depending on certain homogeneity parameters". Bolòs i Capdevila (1981) suggests that the classification of geosystems consists of specifying the similarities (homogeneities) between individuals to group those that have possible identities into a taxon. Therefore, a taxon is a set of individuals, in this case, geosystems, which have a high degree of similarity. The different taxa can also be grouped in other levels (higher or lower).
The head of the Siberian Institute of Geography, Sochava (1970;1975;1978a;1978b) led the creation of a taxon chorological system for landscape classification. This system is organized in a bilateral row containing geomers, geosystems with a homogeneous structure, and geochors, geosystems with a differentiated structure. Even so, Sochava (1978b, p. 8) highlights that "no classification is absolute; it is necessary to modify it, improve it ".
The hierarchical approach, widely discussed by Klijn (1995), led the author to consider that the predominant principle of a hierarchy is that its elements must be based on inequality in their relationships. In the hierarchy of landscapes, it is possible to adopt the relationships established by Klijn (1995), regarding homogeneity or heterogeneity, symmetry, and asymmetry, respectively ( Figure 2). Figure 2 -Symmetrical (homogeneous) and asymmetric (heterogeneous) relationships in hierarchies. 1) "A" dominates "b", unilaterally; 2) "A" dominates "b", but "b" affects "A"; 3) "A" and "b" affect each other similarly.
This system of hierarchizing geosystems presupposes the grouping of landscapes in units of different classes, scales, or taxonomic levels. It is common practice for taxonomic levels to have a particular designation: species, genus, and types of landscapes, among others, according to their structural, genetic, or functional specificity. The landscapes' predominant and most important properties are established using this process of typological classification (taxonomy) (BAYANDINOVA, MAMUTOV, and ISSANOVA, 2018;SERRANO GINÉ et al., 2019).
With the advent of geoinformation, the use of Geographic Information Systems (GIS) has given new impetus to mapping techniques for landscape units. This is exemplified by Isachenko and Reznikov (1995), who state that It is easily verified that, even for a small territory in the taiga zone, there may be dozens of possible dynamic scenarios for the landscapes. It is impossible to map by traditional manual methods. Therefore, future steps on the path of landscape modeling will be connected with the possibilities of GIS technologies (ISACHENKO and REZNIKOV, 1995, p. 804, our translation). Mercator, Fortaleza, v.19 , e19011, 2020. ISSN:1984-2201 Given the possibility of modeling for mapping landscapes, the use of statistics can also contribute to this task. According to Preobrazhenskiy (1983), in the mid-1970s, the first studies to consider such a possibility were by Aleksandrova (1975), who used automated techniques to evaluate landscapes from the correlation of a geographic, mathematical, and statistical model. Shortly afterward, Kuprianova (1977) analyzed the geographical correlation of the natural differentiation of the regionalization of landscapes, by applying computerized and automatic procedures to complex objects (PREOBRAZHENSKIY, 1983).

PROCEDURES
The following eight elements were used to start the mapping: morphostructure, geological units, relief, hypsometry (altitude), slope, drainage density, soils, and land use and cover (Table 1). The crossing of elements using vector data (shapefiles) resulted in a file with 67,691 features. The research steps are summarized in the flowchart in Figure 3.
The result was converted to a given raster (.tiff), reclassified, and submitted to fuzzy (fuzzification) logic. In this conversion process, the raster admits 245 intervals (the binary logic of an 8-bit raster allows a maximum of 255 intervals).
The diffuse classification [fuzzy logic] assumes the limit between two neighboring classes as a continuous overlapping area in which an object participates partially in each class. This point of view not only reflects the reality of many applications in which categories have diffuse boundaries, but it also provides a simple representation of the potentially complex partition of the resource space (ZHENG and KAINZ, 1999, p. 79  In the context of landscape cartography, fuzzy logic is mainly relevant in defining geosystems' limits because, according to Marques Neto (2016), the boundaries between landscapes can be abrupt and well-marked, but they can also change from one unit to another in a diffuse and interdigitated way that may make adequate and more accurate cartographic representation impossible. The next step was the defuzzification of the raster and its transformation into a vector (shapefile) to deal with the residues and correct the confusions in the grouping or separation of possible landscape units, based on cartographic generalization, opting for a cartographic area of at least 5ha.
As specified by Salinas Chávez and Ramón Puebla (2013), the minimum cartographic area of 5 ha corresponds to cartographic representations on the scale of 1: 50,000. After the necessary adjustments, the 245 classes were manually reorganized (vectorization), revised and finally, 272 landscape units were obtained for the municipality of Mineiros (GO).
The map of landscape units -and subsequently of landscape groups -is represented on a scale of 1: 100,000, to value the landscape differences (by a principle of homogeneity 2 ). For the procedures described above, the geoinformation was organized in a Geographic Information System (GIS), using the ArcGIS 10.4.1 software.
Due to the large number of landscape units (272), it was necessary to create groups (clusters) that were similar. This is a common statistical technique when large amounts of numbers are involved. It also resembles the principles of mapping landscapes, which aim to determine elements with homogeneous structures, and those that are heterogeneous, identifying different hierarchies of "clusters" or "separations" and finally, simplifying their cartographic representation.
The typology was performed through cluster analysis (clustering), by applying multivariate statistics. This procedure was adopted because of the number of observation objects. In this way, efforts were concentrated on grouping these units into higher hierarchies with a certain degree of similarity to represent groups of landscapes through clustering.
The cluster analysis (clustering) was carried out using the PAST statistic (3.25), software and the Unweighted Pair Group Method with Arithmetic Mean -UPGMA method was selected, using the Euclidean and Jaccard Distance similarity coefficients and the K-means algorithm.
The UPGMA calculates the average distances or similarities between a landscape unit (LU) and each of the other LUs, which all receive the same weight, with the matrix (of distance or similarity) being updated and reduced at each stage of the algorithm. It is, therefore, an agglomerative (bottom-up) strategy (LEGENDRE and LEGENDRE, 2012).
Concerning the application of the UPGMA, Metz (2006, p.23) points out that this approach, like the others, builds the groupings so that examples belonging to the same cluster have high similarity and examples belonging to different clusters have a low similarity. [...] However, a distinction between this approach and the others is that the result obtained is not just a partition of the initial data set, but a hierarchy that describes a different partitioning at each level analyzed.
Regarding the coefficients used in this work, it is notable that the Euclidean distance, which was "defined by the Greek mathematician Euclides and represents the shortest distance between two objects in the multidimensional plane" (MACHADO, 2011, p. 29), is the most common metric distance used in cluster analysis (clustering), as explained by Metz (2006), and defined by Equation 1 below: (1) The Jaccard coefficient (JACCARD, 1901) is a similarity metric, understood as a coefficient used to measure association when the characteristics are only described by two discrete values, for example, 1 or 0. The Jaccard coefficient considers that the correspondence between the 0-0 (non-existent) values is less important than that of the 1-1 (existing) values. This occurs because, in most applications, the value 1 is used for attributes where the described characteristic is present and the value 0 indicates the absence of the characteristic (Equation 2) (METZ, 2006). "Thus, this algorithm compares the number of presences of common variables and the total number of variables involved, excluding the number of joint absences" (MEYER, 2002, p. 9).
(2) As well as using a hierarchical algorithm (UPGMA), a non-hierarchical and non-supervised K-means algorithm was used. Initially, the clusters are assigned randomly. Then an iterative procedure is adopted, where items are moved to the cluster with the closest average to the grouping. The procedure is repeated continuously until the items are not closer to other clusters (HAMMER, 2019).
The k-means proposed by MacQueen (1967), is heuristic, as an algorithm takes two properties into account when creating its structure. Furthermore, k-means is considered an unsupervised clustering algorithm because it generates groupings from predetermined class numbers. The k-means has a rapid execution time, based on strategies to make simple and fast choices, iteratively minimizing the elements' distance to a set of k-centers given by x = {x1, x2, ..., xk}. The k-means depends on a parameter (k = number of clusters), which is pre-established by the user. This is a non-hierarchical algorithm, given by Equation 3 (LINDEN, 2009) (3) Operationally, the construction of the typology appropriated the 272 units and each of the 71 classes of the eight elements used for mapping the units, organizing them in a "presence-absence" binary matrix -assigning 0 to elements absent in the landscape unit and 1 for elements present in the unit. This procedure defines the similarities or differences between the input elements from a distance, in this case, the Euclidean distance or similarity coefficient. Linden (2009, p.18-19) highlights that The criterion is usually based on a dissimilarity function, which receives two objects and returns the distance between them. [...] Groups determined by a quality metric must have high internal homogeneity and high separation (external heterogeneity). This means that the elements of a given set must be mutually similar and, preferably, very different from the elements of other sets (LINDEN, 2009, p. 18-19).
Thus, the 272 landscape units were grouped into landscape groups, using the UPGMA (Euclidean Distance and Jaccard) procedure resulting in a dendrogram, formed by the grouping of landscape units at levels of distance from the clusters formed. However, the K-means results directly in a matrix containing the intervals of the clusters.
To validate the groupings, it was assumed that the sixteen types of landscapes constitute the reality in the field, considering that even products generated from the cluster were manually refined through the fieldwork.
Therefore, the validation involved selecting two well-known locations that had been extensively verified in the field, which were compared with the limits of the landscape types, field validation points, and with each of the groupings resulting from the UPGMA and K-means.
In addition to the manual measurement, based on field information, statistical tests for the clusters were included, using the MATLAB, "evalclusters" with the Silhouette, Davies-Bouldin, and Gap indices.

RESULTS AND DISCUSSION
The crossing of the elements defined 272 landscape units. Although at first, this situation is indicative of the diversity of landscapes in the municipality of Mineiros (GO), from the point of view of cartographic representation and the intention to use the landscape information for environmental and territorial planning, it was deemed necessary to adopt other (geographic and cartographic) analysis scales 3 .
The issue of geographical scale in the study of landscapes is very relevant since in Sochava's theory of geosystems (1978a) the author was already pointing to the bilateral rows of geomers and geochores, as well as their suborders and subcategories 4 . Solntcev (1949;2006) had also raised concerns about the delimitation of landscape units, both in terms of geographic and cartographic scales, and the number of units to be represented, due to their analytical complexity.
The groupings using the unweighted pair group method with arithmetic mean -UPGMA resulted in dendrograms, whose intervals on the cut lines were 3.0 for the Euclidean distance, and 0.25 for Jaccard ( Figure 4). Mercator  It is essential to emphasize that each mapping reality has particularities regarding the distinction of the landscape units; there is no inflexible rule when selecting cut lines that are always the same in the resulting dendrograms. However, the choice of cut lines directly impacts the quantity and configuration of the landscape units' boundaries ( Figure 4).
As regards the UPGMA grouping, the determination of its quality occurs from the evaluation of the co-phenetic correlation coefficient, with 0.7425 for the Euclidean distance and 0.759 for Jaccard. According to Rohlf's (1970) proposal, co-phenetic correlations > 0.7 are permissible for good groupings.
The result for the k-means is given directly by a matrix indicating the groups (clusters) of the respective landscape units (Table 1). The clusters are then organized according to the landscape units and used to map the landscape groups ( Figure 5).
The manual procedure was selected to assess the clusters, anchored in field information and statistical evaluation, based on cluster validation indexes. Gath and Geva (1989) (2004) specify at least three requirements when defining an acceptable grouping, namely: 1) the clear separation between the resulting groups; 2) a certain concentration (cohesion) of points around the center of a group; and 3) the smallest possible number of groups, provided that they also comply with the previous requirements.
However, there is a need for caution when dealing with groupings involving spatial limits, since it is clear that, in this case, statistical significance does not take spatial significance into account, despite its great importance for landscape cartography. The results of the manual validation indicated that in terms of reliable groupings, the hierarchical method, in this case, the UPGMA algorithm, proved to be more advantageous than the k-means when considering the limits of the landscape types and the landscapes of Mineiros in particular. The validation ( Figure 6) adopted three better-known field areas and concentrated the measurement points, to compare with the landscapes and landscape types identified in the field activities. The statistical validation employed the Silhouette, Davies-Bouldin, and Gap indices, which assess the ideal number of clusters. The Silhouette index gave the best cluster result with the Jaccard coefficient and the k-means of twenty-five groups. The Gap index indicated the most satisfactory cluster using the UPGMA algorithm, applying the Euclidean distance similarity metric (corroborating the manual assessment for the landscape limits), followed by the k-means of twenty-five groups. Although the Davies-Bouldin metric showed the ideal grouping of k-means of 25 groups, this index was unable to specify similarity metrics (except Euclidean and Jaccard distances), therefore, its results were discarded from the assessment.
For the clustering procedure using the Euclidean distance, there was a cut line of 25 groups of landscapes, whereas, with Jaccard, the choice of the cut line indicated 20 groups. For the k-means, the Mercator, Fortaleza, v.19 , e19011, 2020. ISSN:1984-2201 10/16 CLUSTER ANALYSIS FOR LANDSCAPE TYPOLOGY earlier choice of 25 groups of landscapes was opted for.
The main difference in the mappings is in the spatial limits of the resulting landscape groups. The Jaccard grouping created more extensive groups, which tended to be regulated by the formations of the relief, lithology, and morphostructure of the municipality.
Although like Jaccard, it conserved some larger landscape groups, the Euclidean distance resulted in a set of spatial limits that were more coherent and better suited to the desired mapping scale (1: 100,000). As a result, it is considered to be the most appropriate, specifically for the interests proposed in this work.
Even though it had the same number of landscape groups as the Euclidean distance, in the k-means grouping there was a greater fragmentation in the spatial limits, and it was not possible to point to one of the elements (soil, relief, etc.) as a regulator in the landscape groups.
Thus, it is understood that both the issues of scale and spatial significance are very relevant in the study of landscapes, and they should be considered with the same weight attributed to the clustering procedures and their statistical significance.
With traditional manual procedures, the grouping should be carried out analytically in each of 272 landscape units, correlating them from their structural elements (relief, soil, vegetation, etc.) and seeking correspondence with analogous (homogeneous) units.
However, the software algorithms indicate which objects (landscape units) have analogous elements in their structure. When modeling the data in a quantitative (statistical) way, the software indicates different grouping levels of landscape units. The clustering levels defined by the cut lines suggested by the dendrogram, in the case of Euclidean and Jaccard distance, or the resulting k-means matrix, also suggest different geographical scales for landscape analysis.
Although the contribution of cluster analysis for the grouping of landscapes has been recognized, some questions can still be raised.
The first involves considering how the spatial significance between the landscape units from the groupings suggested by the cluster classification can be obtained since the statistical significance (cluster) does not take the spatial significance of the landscape units' boundaries into account.
Another reflection involves the capacity of the statistical technique (clustering) to determine the preponderant elements in the landscape groupings. For example, is geomorphology, in fact, the main element that conditions the formation of landscape groups? This situation leads to another observation: is it possible to identify possible elements that condition the landscape groups from the cluster analysis?
One of the most relevant issues in landscape cartography is geographical and cartographic scale. Given this, the UPGMA (Euclidean and Jaccard distance) cluster analysis indicates the cut lines, which differentiate the levels of the resulting clusters.
Therefore, the issue involves finding a relationship between the grouping levels (cut lines) and the geographical and/or cartographic scales that are representative of the complexity (and reality) of the representation of the landscapes. Or, in the case of k-means, the same relationship with the number of clusters predetermined by the user.
Assuming that in this case, the most relevant grouping was the Euclidean distance, initially, there was no rule, or even a trend, in the genetic sense of conditioning the landscapes that indicated a regulation in the formation and hierarchy of geosystems. Thus, when considering the three grouping techniques (Euclidean distance, Jaccard, and k-means) there was no consensus in identifying one or more preeminent elements in the formation or even the grouping of landscapes Reflection on the results presented, reinforces, for the time being, the premise that in the organization and formation of landscapes all the structure's elements are interrelated. The grouping, therefore, followed the premise of one of the theoretical-conceptual models of landscapes, corroborating Sochava's (1978, p. 292) definition that geosystems are "a dimension of terrestrial space where the different natural components have systemic connections with each other, with a defined integrity". Consequently, the study results were considered satisfactory, with the attributes used exerting a decentralized influence on the formation of landscape units.
The statement that there were "gains" and "losses" in each similarity algorithm and metric adopted is very relevant to the results. Even so, the Euclidean distance, through the UPGMA algorithm, was the metric that came closest to reality (types of landscapes and reality in the field). There is also the assertion that the Jaccard metric can also be considered adequate for landscape groups, considering some "gains" and "losses" in the representation of landscape groups 6 .
The k-means (with 25 landscape groups) is the least satisfactory algorithm as its grouping had more "losses" in the representation of the reality of the landscapes, especially in relation to the boundaries of the types of landscapes in the municipality of Mineiros (GO).

CONCLUSIONS
The use of clustering is a differential technique and still little explored in works in the field of Physical Geography, especially in Brazil, but it has shown considerable potential in landscape unit groupings for cartographic representation.
The use of clustering statistical techniques was relevant for the optimization of processes. Even so, it is noteworthy that this is an option to subsidize the mapping of landscapes but given what has been presented and discussed in this work it cannot be understood as the main and indisputable orientation in the definition of landscape units. As already presented, there is a need to differentiate statistical significance from spatial significance within the limits presented by the landscape clusters.
The procedure's biggest advantage was that it optimized the regrouping of the unit limits for landscape groups. So, based on the Euclidean distance clustering optimized 91% of the limits between the 272 landscape units and their grouping into 25 landscape groups, in a very short time.
Hence, the relevance of this technique is its contribution to clustering procedures, that is, it grouped and redefined a large amount of information that would be excessively slow using manual analysis and spatial regrouping.
Specifically regarding the cluster algorithms, validating Linden's premises (2009), it was identified that the k-means tends to emphasize homogeneity and ignore quality in the separation of clusters, which in this research may justify the fragmentation in the spatial limits of landscape groups and, consequently, the reduced spatial significance.
Another weakness of the k-means is the problem of the prior selection of the number of clusters by the user since it is not usually known a priori exactly how many clusters will be ideal, which may induce the arrangement of the resulting landscape groups. Linden (2009) also pointed out that a small number of clusters may perhaps merge two "natural" clusters, while a larger preselected number will influence an exaggerated break up of "natural" clusters.
The hierarchical cluster algorithms tested through UPGMA, Euclidean distance, and Jaccard have the advantage of results that not only differentiate the clusters but also identify the structure and the context of grouping the landscape units, through the dendrogram. Thus, it is possible to choose different grouping levels -in a possible relationship with the desired scale, in the case of landscapes -and obtain the grouping hierarchy more comprehensibly.
As a result, it is possible that the choice of intervals (cut line in the dendrogram) may also imply, a form of "preselection" of landscape groups. Unlike the k-means, it is not a preceding choice, but it is still a decision that will impact the number of groups obtained.
Currently, this is considered a weakness of the UPGMA, in terms of determining which cut line to adopt in different situations and objectives in landscape cartography. This leads us to question whether the cut line should only be adopted to evaluate the number of landscape groups to be represented later.
Regarding the results of the statistical validation, the indexes aim to evaluate the ideal number of clusters. Even so, this analysis is not entirely sufficient to determine the best cluster for landscape grouping, considering that the k-means was the least satisfactory algorithm for the grouping and the most acceptable from the point of view of the ideal number of clusters. The Gap index, in turn, corroborated the choice of Euclidean distance as the best similarity metric for grouping landscapes.
The Silhouette index pointed to Jaccard as a satisfactory metric of similarity, confirming that Jaccard would be an acceptable metric for adopting the cluster to group landscapes, evaluating the "gains" and "losses" of their results for the representation of landscapes.
Consequently, the results broaden the spectrum on the perspectives that can still be explored on this theme, through new analyzes that aim to overcome existing challenges, such as: To improve the assertion on the grouping levels (cut lines) and their possible relationship with the geographical and/or cartographic scales, aiming at greater rigor in the cartographic representation of landscapes in parallel with reality.
To understand which elements would be preponderant in landscape grouping, that is, which of them would condition the formation of some landscape groups.
The complexity of concomitantly obtaining the statistical and spatial significance between the groups suggested by the statistical clustering analysis.
The urgency of carrying out future tests and comparisons with other non-hierarchical algorithms and metrics, such as Principal Component Analysis -PCA, taking into account that k-means was the least satisfactory algorithm and the only non-hierarchical method tested.

NOTES
1 -This approach was also used in the elaboration of the National Atlas of Spain, in the last decade (MATA OLMO, 2009) 2 -It is reinforced here that, as explained by Luca and Santiago (2015), the principle of homogeneity in the landscapes does not mean that the whole area is identical, but the existence of a common pattern that can be distinguished by field activities and cartography. 3 -Since, as Castro (2010) explains, the cartographic scale can be understood as the proportion ratio between objects (or surfaces) and their representation in maps, letters, drawings, etc .; while the geographical scale deals with the level of apprehension of the geographical phenomenon, that is, the extent of its occurrence in the geographical space. 4 -In Russian-Soviet Geography, an established model includes hierarchical groupings of facies. Solntcev (1967;2006), corroborated by Isachenko (1973;1991), organizes the morphology of landscapes through locations, treatments, subtracts and facies, and states that landscapes are contained in subunits of the geographical envelope (higher hierarchy), recognizing them as geographic individuals. Rodríguez and Silva (2002), dealing with landscape geoecology, also suggested different nomenclatures for the orders (scales) of landscape typology, such as: type, class, group and species. In addition to three subordinate or secondary orders: subtype, subclass and subgroup. 5 -The colors of the landscape groups only correspond when the landscape limits are exactly coincident, apart from that, the colors were randomly defined. 6 -The so-called "gains" and "losses" are directly related to the limits of the landscape groups and their coincidence with the landscape limits found in the field, in the municipality of Mineiros (GO).