GeoAmazonas—GIS for Water Resources Management

Geographic Information Systems (GIS) are used essentially for spatial analysis. They can lead to the development of methods for analyzing and planning the use of geographical space and, consequently, are helpful to the decision making process, assisting those responsible for planning the use of a certain territory. This article is a result of the “Project for the Integrated and Sustainable Management of Transboundary Hydric Resources of the Amazon Basin considering Variability and Climate Change”, which has the goal of strengthening institutional guidelines in order to plan and execute activities related to the protection of the land, hydric resources and sustainable management of the Amazon Basin, considering the existing impacts of climatic changes. This article aims at analyzing the process of building and implementing the GeoAmazonas GIS as one of the instruments for managing the basin, including its contribution for standardizing different data sources in the entire area of the basin and the identification of conflicts related the use of water resources and vulnerability situations.

Consequently, the river discharge, which is significantly influenced by anthropic action, is subject to the inter-annual and long term variation of tropical precipitation, causing large variations on the superficial flow and other stages of the hydrologic cycle in the Amazon Basin, such as evaporation and local precipitation, which influence greatly the hydric availability of the region [1] [2].
These processes highlight the need to identify the impacts on the hydrologic cycle and hydric availability of the Amazon Basin, as well as their direct and indirect consequences. The following cases exemplify possible impacts caused by regional changes in The goal of this paper is to present the stages of building and implementing a geographic information system which helps the management of Transboundary hydrographic basins, in particular the Amazon Basin. Nowadays, the system is being distributed and updated, and the scale of analysis is becoming more detailed in order to support Project 3 AMAZON_COOP_H2O.
Some reasons for elaborating a GIS for managing transboundary hydrographic basins are: the possibility of assessing the entire area of study through the data which are available for the basin; supplying data which allow for an integrated management of hydric resources and providing geographic data and information in a standardized and systemized manner.
Accordingly, the Basic Geographic Information System for the Waters from the Amazon Basin (SIG GeoAmazonas) was organized in the scale of 1:5,000,000, with a content of 1.7 gigabytes of georeferenced information. It provides a better understanding of the land use, the water management of the region and its relation and conse- 1 The project had the support of the Global Environment Fund (GEF), Amazon Cooperation Treaty Organization (ACTO), United Nations Environment Programme (UNEP) and the Organization of American States (OAS-Department of Sustainable Development). 2 Geographic Information Systems (GIS) "are an effective tool for storing, managing, and displaying spatial data often encountered in water resources management" (Tsihrintzis et al. 1996, p. 251). 3 Project proposed by COPPE/UFRJ which is included in PROSUL (South American Program to Support Cooperation Activities in Science and Technology/CNPq/Ministry of Science and Technology). Within the goals of the Project of providing financial support for scientific and technological projects related to international cooperation and integration among Amazon countries, it is possible to include the elaboration of an Information System for the Integrated and Sustainable Management of Transboundary Hydric Resources of the Basins from the MAP region-Madre de Dios in Peru, Acre in Brazil and Pando in Bolivia and the Madeira river (Bolivia and Brazil). quences on the hydrographic sub-basins of the region.

Support Systems for Decision-Making Related to the Planning of Water Resources
Even though the concept was restricted to planning, it is possible to find distinct models of Decision Support Systems (DSS) for hydric resources. Mohaneed et al. [3] states that Decision makers usually take their decisions based upon economical and technical analysis, considering the available alternatives. "Traditional understanding of Decision Support Systems (DSS), as tools predominantly developed by water resources experts and for the same experts, is evolving towards viewing DSSs as potential platforms for knowledge exchange among users belonging to a much broader user base, which includes the experts, the involved stakeholders and the decision makers." Jonoski and Popescu [4].
The mathematical optimization and simulation models have been used in studies focused on the planning of hydric resources since the decade of 1960. They are essential for interpreting and trying to predict the behavior of water bodies. Several researchers have proposed different tools, with different functionalities and capabilities, to assist the decision-making process. These tools can be mathematical models, geomatics systems, performance evaluation systems and others, and they can be used for several challenges related to water planning and management to help the decision-making. For instance: • Zhang et al. [5] proposes a web-based watershed management spatial decision support system based on a Geographic Information System to evaluate different scenarios for watershed planning and management; • Kronaveter et al. [6] proposes a Negotiation Support System applied to the management of conflicts involving the use and management of water resources; • Pearson et al. [7] develops a decision support framework that assists managers in the urban water industry; • Zhang et al. [8] proposes a multi objective decision/bargaining model based on the "satisfaction principle" which is developed for inter-basin water transfer system decision-making; • Purkey et al. [9] presents an overview of decision-making processes ranked based on the application of a 3S: Sensitivity, Significance and Stakeholder support; • Ana and Bauwens [10] presents a review of selected sewer asset management decision-support tools, which are grouped according to their functionalities and capabilities, and describes the concept behind each one; • Fanghua and Guanchun [11] discusses how to apply a fuzzy multi-criteria group decision-making (MCDM) model to watershed ecological risk management, presenting a case study of the Three Gorges Reservoir Area in China.
This knowledge may be employed for determining areas in which dams can be constructed and where energy can be captured and generated. In addition, it may help de-fine the granting of rights to the use of water resources 4 , since the discharge data of the historic series are used by the government agencies which manage hydric resources in order to establish what they call reference discharges, making it possible to determine the limit discharge that can be removed from a water body which can be used in different manners due to a granting of rights.
Nevertheless, there are limitations for including non-quantitative aspects, which reduce the capacity that hydrologic models have in aiding some aspects of the planning, such as: the identification of areas that may potentially affect the resources, the identification of who is involved in each activity and the gaps of space and time coverage when gathering hydrometeorological data, which may lead to inconsistencies in the historical series.

Support Systems for Decision-Making Related to the Real-Time Management of Water Resources
In this case, mathematical modelling and the Decision Support System (DSS) tools are components of a wider Management System, which must provide information in a dynamic way and integrate technical and administrative routines, allowing for consultations, analyses and the elaboration of reports. In geohydroinformatics, the Management Systems based on DSS tools are Real-Time Control (RTC) systems, for they can manage a wider variety of information in the related database. In this context, the capacity of associating spatial and non-spatial data and the possibility of interacting with a mathematical model and more complex databases and, lastly, the capacity of spatializing the analysis with output graphical interfaces that are becoming increasingly more accessible make the Geographic Information Systems (GIS) an essential tool for the planning and management of hydric resources, as well as for other topics that are directly or indirectly associated with the conflicts and impacts regarding these resources.
Among the several definitions which were presented, the definition proposed by Calkins and Tomlinson, singled out by Christofoletti, emphasizes the potential of integrating technology with its stages and mentions that the GIS is a integrated set of programs (software) elaborated specifically for activities related to data manipulation. These activities include input, storage, recuperation and problems associated with data management, excluding the wide variety of descriptive and analytical processes.
In a more recent work, Burrough and Mcdonnell [12] state that a GIS is a powerful set of tools to collect, store and recuperate information by transforming and organizing data gathered from the real world into a particular set of goals.
Over the last 20 years, several authors have used GIS technology as a research tool in 4 The Granting of Rights to the Use of Water Resources one of the instruments of the National Water Resources Policy, which aims to ensure the "qualitative and quantitative control of water use and the effective exercise of rights of access to water resources" (Article 11, Law 9433/1997). There are four categories of granting of rights of water resources: Granting of rights for using hydric resources-for new right requests; Alteration of a Granting of rights for using hydric resources-alters the conditions of a granting of rights which was already given; Renewal of a Granting of rights for using hydric resources-for the cases in which the granting of rights is expiring; Granting of rights for Preventing Use-it aims to separate the discharge which can be used so investors can plan the projects that need these resources.
The following organogram demonstrates in a simplified manner how the three operational levels of the SIG are organized as a DSS tool (Figure 1).
In the structure level, the databases are fed and organized, including all information that may be georeferenced. The interface level includes the visual presentation of the information, and several layers of information can be overlayed according to the selected topics and the specific goal of analysis. Lastly, in the user level there are analyses based on the alfanumeric information and other information provided by the layers.

The Amazon River Transboundary Basin (Study Area)
The Amazon River Basin is the largest hydrographic basin in the world, with an area of  Regarding the area called Amazon Region, with South America as a reference, some topics must be discussed. Firstly, it is necessary to point out that, within this context, some concepts and ideas must be debated according to the suggestions of Corrêa [32], for the use of the term region is not done in a standardized way; it is very complex. It is possible to say that there are some difficulties in identifying the limits of the region, especially because there are several criteria that can be considered. These criteria even change from country to country-each country uses different criteria to define their "Amazon" regions ( Figure 3 and Figure 4).
In this context, the Amazon and the topics related to it are discussed so widely nowadays that, at least in the common sense, the region is a spatial entity without any geographic delimitations. When the Amazon is mentioned, it is common to overlook the different spatial outlines which can be used to define it. Nevertheless, in theoretical, political and especially quantitative terms, it is important to define the territorial matrix used as reference in order to discuss any theme related to the Amazon.
In this sense, it is possible to define at least four territorial outlines for the Amazon.
The first one, determined by the hydrographic basin, includes an area of 7 million·km 2 , 4.8 of which are in Brazilian territory. The second possibility is to consider the vegetation cover, which is estimated to be 40% of the total area of the basin. Another possible outline is to consider the regional division of the country-in this case, the Amazon would include the North Region, which is composed of the states of Acre, Amapá,  According to Eva and Huber [33], although this situation does not create any problems on a national level, it may create issues for integrating data and statistics (in content or spatial dimension) on a regional level. Therefore, studies about the regionalization of the Amazon must also be done.   [33]. It is worth noting that French Guiana is not part of the ACTO.

Stages for Building the System
The It was elaborated based on the bibliographical and cartographical survey, considering the topics and spatial outlines delimitated on the goals previously determined for the GeoAmazonas Geographic Information System. Subsequently, it was necessary to represent the structure of the information in the system, i.e., the types of data and how they were related to one another, as the following example shows ( Figure 5). This stage is focused on the interaction the user has with the system. The way to access the system is through the GIS, which allows the user to communicate with the system by requesting consultations and viewing results.

• Stage 7 (Storage, Consultations and Analyses)
Lastly, some files were organized, some consultations were made (for instance, the boundaries and the calculation of the area of the Amazon Basin inside Venezuelan territory were verified due to a request of the Environment Coordination of the ACTO) and analyses were done considering the outlines of the region, country or basin (for instance, spatial analysis regarding occupation and deforestation and spatio-temporal analyses regarding the evolution of the deforestation in the Acre River Basin). With this stage, a series of thematic maps was generated, which will be presented in the results.

Results and Discussion
These stages led to the definition of the scope of GeoAmazonas and defined which representation shapes would be more adequate for integrating the surveyed databases ( Figure 6 and Table 1).
The following table (Table 2) shows data and information of the countries which were analyzed by the GeoAmazonas GIS. The consultations to the GIS can be done by outline of the basin or by country (representations for different themes were created for each country).
As it is possible to see, the GeoAmazonas GIS led to several results, such as the ac-  The result of this survey is extremely relevant for identifying and understanding the regional water management, types of ecosystems, protection areas and land use, since these data are hard to access and expensive to survey due to the comprehensive area of the basin.
During the process of building GeoAmazonas, there were difficulties and a certain need for some initiatives that would benefit significantly the data production and the research in the region of the Amazon Basin. The initiatives could mean an update for the system or even lead to other studies.
Among the main issues found, it is possible to mention: • The need to detail the used base for the scales of 1:1,000,000; 1:500,000; • Stimulating the production of information in a standardized way between the countries that are part of the Amazon Basin, especially when it comes to strategic topics such as water management and climate vulnerability;

Continued
Suriname Suriname does not have a determined drainage area of the Amazon Basin. One of the goals of the GET Amazonas Project is to define this area, which may represent between 0.05% and 0.1% of the total area of the basin and from 1% to 2% of the territory of the country. The main basins flow into the Atlantic, such as the basins of Rivers Tapanahony and Litani. The rivers that flow into the Amazon still need to be defined.

Venezuela
Venezuela has a drainage surface of the Amazon Basin of 42,784 km 2 , which represents about 0.7% of the total area of the basin and 4.7% of the Venezuelan territory. Its main basin is the Negro river basin.
*It is worth pointing out that some of the enlargements made for the map representations of each country led to enlargements of the graphical error associated with them.

Conclusions
The efforts made to create and implement the GeoAmazonas GIS are an evidence of the current valorization and diffusion of the geographic information which has been increasingly stimulated by social and economic demands for a better understanding of the territorial reality, for that is the basis for implementing policies of sustainable management and development.
The challenges in developing a GIS for the region of the Amazon Basin-which is a transboundary area including water bodies under different domains-involve mostly the difficulty in accessing and standardizing the data of several sources. Therefore, it is extremely important to create agreements for sharing geospatial databases in order to integrate and share the most commonly used sources.