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A biodiversity Vision for the upper Paraná Atlantic Forest Ecoregion


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Chapter 4




Designing a Biodiversity Conservation Landscape – Methods

The aim of this Biodiversity Vision analysis is to design a Biodiversity Conservation Landscape that, if implemented, would accomplish the biodiversity conservation goals described earlier: maintenance of large and resilient forest blocks, maintenance of viable populations of umbrella species, healthy ecological processes, and representation of the native ecological communities.

During the past three years, WWF has led a tri-national participatory process, involving local organizations representing multiple sectors and disciplines, to develop this Vision for the time frame and geographic scale necessary to conserve the biodiversity of the Upper Paraná Atlantic Forest ecoregion. Thirty-six partners and WWF staff gathered in Foz do Iguaçu, Brazil, in April 2000. In preparation for the workshop, various partner organizations in Paraguay and Argentina were contracted to collect and compile the best data available for fauna and flora distributions, geomorphologic, and socio-economic aspects that would be compatible with the information already collected for Brazil in the PROBIO14 national Atlantic Forest workshop held in Atibaia, Brazil on August 1999. Many of these organizations provided information and data critical to produce this Biodiversity Vision15, which will continue to be refined over time as additional information becomes available.

This Biodiversity Vision is a product of various scientific analyses using ArcView, a Geographic Information System (GIS). We used the Spatial Analyst module of ArcView, using a grid cell size of 500 x 500m (1/4 km2). The basic information for the analyses is expressed in maps that represent the spatial distribution of a variety of different biological and socio-economic variables. Various layers of information were overlaid or combined to obtain new maps providing more integrated information. A buffer zone of 25 km on the ecoregion border with the Araucaria Ecoregion was used for the analyses. We initially conducted three separate but interdependent analyses, described below.


Landscape units analysis. We first discriminated landscape units within the area of analysis. A landscape unit is an area that contains a set of species, communities, or ecological processes that differs from other such landscape units. Each landscape unit usually has a characteristic climate, soil type, and set of species. Thus, to get a good representation of the full range of species and natural communities of an ecoregion, it is necessary to preserve representative portions of each landscape unit.

Since we did not have sufficient biological data to define and map landscape units, we used climatic and topographic information as proxies for developing a biological model. The assumption behind this simplification is that geographic units with different climatic conditions and topography will be correlated with distinct ecological communities. This approach to define the landscape units is similar to those used in other Biodiversity Vision analyses16, where actual biological data were not available. To discriminate the landscape units we used three data layers. The first layer is the number of dry months in three categories: areas without dry season, areas with one to two dry months, and areas with three or more dry months (Figure 12). The second layer of information is altitude. We divided the ecoregion into two altitudinal ranges: above or below 500 m asl (Figure 13). For the third layer, using topographic data, we created a map that describes the degree of slope. We then defined three categories: plains, moderate slopes, and steep slopes, representing areas of increasing steepness and increasing topographic variation (Figure 14). The combinations of these three layers of information gave us a total of 18 landscape units (Figure 15). It will be important to test if these landscape units actually represent distinct ecological entities.


Fragmentation analysis. This analysis is aimed at discriminating those native forest fragments with the highest potential for achieving conservation goals. The basic information for this analysis is a map of forest fragments obtained from satellite images (Figure 16). This forest fragment map was created combining the SOS Mata Atlântica forest fragments map (Fundação SOS Mata Atlântica 1998) for the Brazilian portion of the ecoregion (based on satellite images from 1990-1995); a map produced by Fundación Moisés Bertoni, the Dirección de Ordenamiento Ambiental (DOA), and the Carrera de Ingeniería Forestal for the Paraguayan portion of the ecoregion (based on satellite images from 1997); and a map produced by Fundación Vida Silvestre Argentina (based on satellite images provided by the Ministerio de Ecología y Recursos Naturales Renovables de Misiones from 1999).

We rated the forest fragments according to their importance for conservation. The importance for conservation of a forest fragment was evaluated using five variables:



  1. Fragment size­­­­—The larger the fragment, the higher its importance for biodiversity conservation. (Figure 17).

  2. Fragment Core—The forest fragment area after excluding a buffer zone of 500 m, a distance to which edge effects are proven to be significant (see Chapter 3). This serves as an indirect measure of the shape and border effect of the fragment (Figure 18).

  3. Nearest Neighbor—The distance from the fragment to another forest fragment. This is a measure of connectivity/isolation of the forest fragments.

  4. Altitudinal range within the forest fragment—An indirect measure of variation in topographic, soil, and microclimatic conditions within a forest fragment.

  5. Location of a fragment within a river basin—Measure of the contribution of a forest fragment to watershed conservation. For this purpose we constructed a watershed position index.

We analyzed the contribution of each of the five variables to total fragment importance variability with a Principal Components Analysis. This multivariate analysis indicated that the first four variables contributed most of the variation in forest fragments’ conservation importance. As the last variable (location of a fragment within a river basin) did not contribute any new information, it was discarded.

We developed a “Fragment Importance Index” using the first four variables. Each was placed in one of four categories (using the natural breaks ArcView function) assigning a value from 0 (least important category) to 3 (highest). The Fragment Importance Index is the average of the values of the four variables used in the analysis. We then ranked each forest fragment according to its Fragment Importance Index (Figure 19).
Threats and opportunities analysis. The objective of this analysis was to map the areas that represent critical threats to biodiversity conservation and areas that represent opportunities for biodiversity conservation. This map was created using land use data, with different land uses representing threats or opportunities for conservation.

We began the threats and opportunities analysis by assigning and mapping different levels of threat and opportunity to different variables (types of land use). For example, a road is usually a threat to biodiversity conservation while a protected area is an opportunity for conservation. We weighted the different variables used in this analysis according to the level of threat or opportunity they represent for biodiversity conservation, carrying out two separate analyses, one for threats and one for opportunities.


The threat variables we used in this analysis included:

  1. Cities­­—Cities are represented by circular areas on a map. The area of the circle is equivalent to the area actually occupied by the city. In the analysis we identified three buffer zones around each city, with the threat to conservation decreasing as the distance from the city increases, the city itself representing the highest threat. The buffer zones around the cities are directly proportional to the size of the city, with larger cities having a larger area of negative influence on biodiversity conservation. (Figure 20).

  2. Agriculture­­—This variable represents the impact of agriculture, and was measured as the percentage of a municipality or departmental area devoted to agriculture, including both annual and perennial crops (Figure 21). We acknowledge that perennial and annual crops may have different impacts on biodiversity conservation, but the area occupied by perennial crops was so small in comparison to that of the annual crops, it was determined that it would not justify a separate data layer.

  3. Cattle Ranching­­—This variable represents the impact of cattle ranching on biodiversity conservation. It was measured as the percentage of a municipality or departmental area devoted to this activity (Figure 22).

  4. Rural Population Density—Due to the widespread cultural tradition of hunting and harvesting of non-timber products, and the fact that most people see the forest as an obstacle for development (see Chapter 2), the presence of rural population in the ecoregion usually has a large negative impact on the conservation of the native forest remnants. Thus, this variable represents the impact of rural population density on biodiversity conservation and is measured as people per hectare in each municipality or department (Figure 23).


(Notes: 1. Due to the extreme fragmentation, and the high density of roads, almost any single forest area in the ecoregion is easily accessed by road. We did not consider roads as another threat variable because roads already impact nearly the entire ecoregion.

2. For illustration purposes the maps are presented with their original scales (e.g., actual rural population density). However, for the analysis we divided all variables into four categories following natural breaks in their frequency distribution (a function of ArcView does this automatically). These four categories were assigned values of 1, 2, 4 and 8, with each category having double the value of the previous one.)
We weighted threat variables differently according to the degree of threat each poses to biodiversity conservation. Cities pose the highest threat, thus we assigned to this variable three times the weight we assigned to the variables posing a lesser threat. Agriculture represents the second highest threat to biodiversity because it is the economic activity with the most negative impact on biodiversity because it is mainly large-scale monoculture plantations that usually require high loads of herbicides and pesticides. It also usually has a high opportunity cost in relation to cattle-ranching, an activity usually restricted to the less productive areas. We assigned to agriculture two times the weight we assigned to the least threatening variables. Finally we assigned to the threat variables cattle ranching and density of rural population the least weight because both have less impact on biodiversity conservation than agriculture or the presence of a city. With these four threat variables, we created a map, that depicts areas with high and low threat to biodiversity conservation (Figure 24).
As opportunity variables we used:

  1. Proximity to a strictly protected area (IUCN categories I-III) —Protected areas present an opportunity for conservation because there is usually an interest to increase their area by incorporating nearby areas of high potential for conservation. Also the implementation of buffer zones around protected areas, usually an important component of management plans, facilitates the development of local conservation programs. Areas closer to a strictly protected area have a higher potential for becoming a protected area, a biological corridor, or a Sustainable Use Area (Figure 25). We assigned to each protected area three possible areas of influence (buffers) surrounding it 1,000, 5,000 and 20,000 meters, representing decreasing opportunities for conservation as the distance from the strictly protected area increased.

  2. Proximity to a river­—We assumed that rivers in this ecoregion constitute potential biological corridors that may help to connect forest fragments. Because in the three countries there is legislation that protects the riverine forests, areas closer to rivers have higher potential for connectivity (Figure 26). On the other hand, since the majority of rivers in this ecoregion are not navigable, they do not represent ways to access the forest as they do in other ecoregions. We assigned three buffer zones of 1,000, 2,500 and 5,000 m on both margins of the rivers (all rivers have a width of 500m the minimum unit of analysis, irrespective of their size), representing areas of decreasing potential for connectivity to other conservation areas.

  3. Zones of planned conservation—Sustainable Use Areas (IUCN categories IV-VI) and areas prioritized for conservation by PROBIO17 constitute areas identified by government or other institutions as areas with potential for conservation (Figure 27). The political consensus around these areas gives them a higher potential for conservation. PROBIO defined five categories of areas: category A corresponds to areas of extremely high biological importance; B to areas of very high biological importance; C to areas of high biological importance; D to insufficiently known areas but of probably high biological importance; and L to corridors. We assign a value of 8 to existing Sustainable Use Areas, a value of 4 to category A PROBIO areas, a value of 2 to category B PROBIO areas and a value of 1 to areas categorized as C, D, and L by PROBIO.

We weighted the three opportunity variables according to their potential for conservation, with strictly protected areas representing three times and rivers constituting two times the potential for conservation of the zones of planned conservation. These three layers of information were combined to produce a map of opportunities for biodiversity conservation (Figure 28).



We combined these two maps of threats and opportunities into one consolidated map (Figure 29) that depicts areas with the highest threats (in blue) and areas with the best opportunities (in green) for biodiversity conservation.
Using the three analyses described above, we then conducted two additional analyses:
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