Note: Intro -- Preface -- Contents -- Contributors -- Part I : Global Problems and Mountain Regions -- Chapter 1: Scientific Research Basis for Sustainable Development of the Mountain Regions: Main Concepts and Basic Theories -- 1.1 Introduction -- 1.2 Research Base for Sustainable Development of Mountain Regions -- 1.3 "Pressure, State, Response" (PSR) and DPSIR Models Require Trans-Disciplinarity -- 1.4 Conclusions -- References -- Chapter 2: Solar Activity, Climate Change, and Natural Disasters in Mountain Regions -- 2.1 Background -- 2.2 Heliocentric Hypothesis on Forest Fires -- 2.3 Conclusion -- References -- Chapter 3: Mass Movement Processes Under Changing Climatic and Socioeconomic Conditions -- 3.1 Introduction -- 3.2 The Matrix of Mass Movement Processes and Triggering Parameters -- 3.2.1 Basics -- 3.2.2 The Event of 2005 (Communities of Gasen and Haslau, Austria) -- 3.3 Climate Change: Facts and Assumptions -- 3.4 Socioeconomic Development and Rising Disadvantages -- 3.5 Working with Scenarios: An Approach -- 3.6 Conclusions -- References -- Part II : Nature Resources and Land Use in Mountain Regions -- Chapter 4: Mountains and Mountain Regions in Bulgaria -- 4.1 Introduction -- 4.2 Arguments -- 4.3 Criteria -- 4.4 Results -- 4.5 Conclusion -- References -- Chapter 5: The Nature Potential of Mountains in Bulgaria and Its Sustainable Use -- 5.1 Former Studies on the Natural Potential of the Mountains in Bulgaria -- 5.2 Assessment of Nature Potential by Components for Various Economic Purposes -- 5.2.1 Assessment of Relief -- 5.2.2 Climate Assessment -- 5.2.3 Assessment of Water -- 5.2.4 Assessment of the Soils, Vegetation, and Animal World -- 5.2.5 Complex Assessment of Mountain Landscapes -- 5.3 Assessment of the Possibilities for Sustainable Utilization of the Natural Potential of Mountains -- 5.4 Conclusion -- References. , Chapter 6: Morphometry and Land Use on High Mountains in the Republic of Macedonia -- 6.1 Introduction -- 6.2 Methodology -- 6.3 Basic Morphometric Characteristics -- 6.4 Basic Land Use Characteristics -- 6.4.1 Hypsometry and Land Use -- 6.4.2 Slopes and Land Use -- 6.4.3 Aspects and Land Use -- 6.5 Conclusion -- References -- Chapter 7: Usage of the Mountain Areas in the Republic of Macedonia -- 7.1 Introduction -- 7.2 Methodology of Work and Data Sources -- 7.3 Population as a Precondition for Area Usage -- 7.4 Size of Villages According to Population Number -- 7.5 Usage of the Areas of Mountain Villages -- 7.6 Conclusion -- References -- Chapter 8: Physical Geographic Characteristics and Sustainable Development of the Mountain Area in Montenegro -- 8.1 Introduction -- 8.2 Borders and Division of the Mountain Terrain -- 8.3 Geologic Background -- 8.4 Climate Conditions -- 8.5 Hydrologic Characteristics -- 8.6 Geomorphological Characteristics -- 8.7 Geoheritage and Environmental Protection -- 8.8 Potentials and Limitations for the Application of the Concept of Sustainable Development -- 8.9 Conclusion -- References -- Chapter 9: Climate Variability, Soil, and Forest Ecosystem Diversity of the Dinaric Mountains -- 9.1 Introduction -- 9.2 Climate Characteristics and Observed Climate Change in Dinarides -- 9.3 Main Soil-Forming Factors -- 9.4 Characteristic Soil Types -- 9.5 Forest Vegetation of Dinarides -- 9.6 Climate Modeling and Future Climate Changes in Croatia -- 9.7 Conclusions -- References -- Chapter 10: Assessment of Greek Forests Protection and Management -- 10.1 Introduction: Forest Ecosystems in Greece -- 10.1.1 The General Context -- 10.1.2 Greek Diversity -- 10.2 Forests in Mountain Regions of Greece -- 10.2.1 Morphology and Diversity -- 10.2.2 Species and Formations of Forests in Mountainous Regions of Greece. , 10.3 Direct and Indirect Benefits of Forests -- 10.3.1 Direct Benefits -- 10.3.2 Indirect Benefits -- 10.4 Sustainable Forest Management -- 10.4.1 A Definition -- 10.4.2 The Global View -- 10.4.3 The European View -- 10.4.4 Greek Management -- 10.4.5 Regional Issues -- 10.4.6 The Future Approach -- 10.5 Threats and Risks of the Greek Forests -- 10.6 Restoration of Greek Forest Ecosystems -- References -- Chapter 11: Mapping Forest Fragmentation Based on Morphological Image Analysis of Mountain Regions in Bulgaria and Slovakia -- 11.1 Introduction -- 11.2 Materials and Methods -- 11.2.1 Study Areas -- 11.2.2 Data -- 11.2.3 Morphological Image Analysis -- 11.3 Results and Discussion -- 11.4 Conclusion -- References -- Chapter 12: Evaluation of the Avalanche Danger in Northwest Rila Mountain -- 12.1 Introduction -- 12.2 Avalanche and Avalanche Danger -- 12.3 Conclusions -- References -- Chapter 13: Management of Snow Avalanche Risk in the Ski Areas of the Southern Carpathians-Romanian Carpathians -- 13.1 Introduction -- 13.2 General Facts of the Studied Area -- 13.3 Terrain Factors and Climatic Variables Analysis as Favorable for Ski Activities -- 13.3.1 Terrain Factors -- 13.3.2 Climatic Variables -- 13.4 Management of Snow Avalanche Risk -- 13.5 Conclusions -- References -- Chapter 14: Landscape Structure and Ecosystem Services of Etropole Municipality -- 14.1 Introduction -- 14.2 Study Area -- 14.3 Materials and Methods -- 14.4 Results -- 14.5 Conclusion -- References -- Part III : Social, Economic and Regional Problems of Mountain Regions -- Chapter 15: Demographic Potential and Problems of the Settlements Network in the Mountains of Bulgaria -- References -- Chapter 16: Demographic Limits to Sustainable Development of Mountain Regions in Serbia -- 16.1 Introduction -- 16.2 The Analysis -- 16.3 The Future -- References. , Chapter 17: Changes in the Ethnic and Demographic Profile of the Population in Eastern Stara Planina Region -- 17.1 General Notes -- 17.2 The Turkish Ethnic Group -- 17.3 The Bulgarian and the Roma Ethnic Groups -- 17.4 Classification and Grouping -- References -- Chapter 18: Small Urban Centers in the Alps and Their Development Issues -- 18.1 Introduction -- 18.2 Basic Features of Small Urban Centers in the Alps -- 18.2.1 Population Growth -- 18.2.2 Aging of the Population -- 18.2.3 Working Population -- 18.2.4 Jobs -- 18.2.5 Tourism -- 18.2.6 Transport Accessibility and Mobility -- 18.3 Survey on Contemporary Development Issues -- 18.4 Discussion -- 18.5 Conclusion -- References -- Chapter 19: Impact of Macroeconomic Changes and Property Rights on Forest Degradation, Land Use, and Environmental Situation in Albania -- 19.1 Historical Land Tenure in Albania -- 19.1.1 Privatization of Agricultural Land -- 19.2 Main Land Tenure Issues -- 19.2.1 Land Fragmentation -- 19.3 Effects of Land Reforms on Land Use in Albania After 1991 -- 19.3.1 Land Cover -- 19.3.2 Forest Degradation -- 19.3.3 Pasture Degradation -- 19.4 Conclusions -- References -- Chapter 20: Sustainable Development in the Eastern Black Sea Mountains: Present State and Perspectives -- 20.1 Introduction -- 20.2 The Eastern Black Sea Region -- 20.2.1 Settlement System -- 20.2.2 The Economy -- 20.3 The Eastern Black Sea Regional Development Plan (DOKAP) and Sustainable Mountain Development -- 20.3.1 Legislative Basis -- 20.3.2 Design -- 20.3.3 Objectives, Rationale, and General Description -- 20.3.4 Financing -- 20.3.5 Administration of the Plan -- 20.4 The Project Achievements -- 20.4.1 Accessibility and Mountain Development -- 20.4.2 Tourism and Mountain Development -- 20.4.3 The Kaçkar Mountains National Park: A Model for Sustainable Mountain Development -- 20.5 Conclusion -- References. , Chapter 21: Regional Differences and Regional Planning of Economic Activities in Bosnia and Herzegovina -- 21.1 Introduction -- 21.2 Methodology of Research -- 21.3 Socioeconomic Transformation and Regional Development of Bosnia and Herzegovina Since the Mid-­Twentieth Century -- 21.4 Modern Regional Development of Bosnia and Herzgovina -- 21.5 Conclusion -- References -- Journal Article -- Book -- Part IV : Nature Protection, Conservation and Monitoring -- Chapter 22: Applying Integrated Nature Conservation Management: Using Visitor Management and Monitoring to Handle Conflicts Between Winter Recreation and Grouse Species in Berchtesgaden National Park -- 22.1 Introduction and Background -- 22.2 Study Area and Study Objects -- 22.2.1 Berchtesgaden National Park -- 22.2.2 Winter Recreation: Ski-Touring and Snowshoeing -- 22.2.3 Wildlife: Grouse Species -- 22.3 Temporal and Spatial Use Characteristics of Ski-­Touring and Snowshoeing -- 22.3.1 Visitor Numbers and Temporal Use Characteristics -- 22.3.2 Spatial Use -- 22.4 Conflicts and Integrated Management Measures -- 22.4.1 Winter Season -- 22.4.2 Spring Season -- 22.5 Outlook -- References -- Chapter 23: Environmental Changes in the Maramureş Mountains Natural Park -- 23.1 Introduction -- 23.2 Environmental Changes in  Maramureş Mountains Natural Park -- Settlement Expansion -- Overgrazing -- Deforestation -- Mining Activities -- Touristic Activities -- 23.3 Conclusions -- References -- Chapter 24: BEO Moussala: Complex for Environmental Studies -- 24.1 Introduction -- 24.1.1 Climate Notes -- 24.1.2 The Station Chronology -- 24.2 Environmental Measurements at BEO Moussala -- 24.2.1 Vaisala Automatic Weather Station (AWS) -- 24.2.2 POPs Passive Air Sampling -- 24.2.3 Atmospheric Gas Analysis System -- 24.2.4 BEO Moussala Aerosol Measurement and Devices -- 24.2.4.1 Scanning Mobility Particles Sizer. , 24.2.4.2 Nephelometer TSI 3563.

Note: Intro -- Contents -- Part I: Introduction -- Chapter 1: Ecological Informatics: An Introduction -- 1.1 Introduction -- 1.2 Data Management -- 1.3 Analysis and Synthesis -- 1.4 Communicating and Informing Decisions -- 1.5 Case Studies -- References -- Part II: Managing Ecological Data -- Chapter 2: Project Data Management Planning -- 2.1 Introduction -- 2.2 Components of a Data Management Plan -- 2.2.1 Context -- 2.2.2 Data Collection and Acquisition -- 2.2.3 Data Organization -- 2.2.4 Quality Assurance/Quality Control -- 2.2.5 Documentation -- 2.2.6 Storage and Preservation -- 2.2.7 Data Integration, Analysis, Modeling and Visualization -- 2.2.8 Data Policies -- Box 2.1 Recommended Data Citation Guidelines from Dryad Digital Repository (2016) -- 2.2.9 Communication and Dissemination of Research Outputs -- 2.2.10 Roles and Responsibilities -- 2.2.11 Budget -- 2.3 Developing and Using a Data Management Plan -- 2.3.1 Best Practices for Creating the Plan -- 2.3.2 Using the Plan -- 2.4 Conclusion -- References -- Chapter 3: Scientific Databases for Environmental Research -- 3.1 Introduction -- 3.2 Challenges for Scientific Databases -- 3.3 Examples of Scientific Databases -- 3.3.1 A Useful Analogy -- 3.3.2 Examples of Databases -- 3.4 Evolving a Database -- 3.4.1 A Strategy for Evolving a Database -- 3.4.2 Choosing Software -- 3.4.3 Database Management System (DBMS) Types -- 3.4.4 Data Models and Normalization -- 3.4.5 Advantages and Disadvantages of Using a DBMS -- 3.5 Interlinking Information Resources -- 3.5.1 A Database Related to the Human Genome Project -- 3.5.2 Environmental Databases for Sharing Data -- 3.5.3 Tools for Interlinking Information -- 3.6 Conclusions -- References -- Chapter 4: Quality Assurance and Quality Control (QA/QC) -- 4.1 Introduction -- 4.2 Quality Assurance -- 4.3 Quality Control -- 4.3.1 Data Filters. , 4.3.2 Graphical QC -- 4.3.3 Statistical QC -- 4.3.4 Treatment of Errors and Outliers -- 4.4 Implementing QA/QC -- 4.5 Conclusion -- References -- Chapter 5: Creating and Managing Metadata -- 5.1 Introduction -- 5.2 Metadata Descriptors -- 5.3 Metadata Standards -- 5.3.1 Dublin Core Metadata Initiative -- 5.3.2 Darwin Core -- 5.3.3 Ecological Metadata Language -- 5.3.4 GBIF Metadata Profile -- 5.3.5 FGDC CSDGM -- 5.3.6 ISO 19115 -- 5.4 Metadata Management -- 5.4.1 Metadata Tools -- 5.4.2 Best Practices for Creating and Managing Metadata -- 5.5 Conclusion -- References -- Chapter 6: Preserve: Protecting Data for Long-Term Use -- 6.1 Introduction -- 6.1.1 Preservation and Its Benefits -- 6.2 Practices for Preserving Ecological Data -- 6.2.1 Define the Contents of Your Data Files -- 6.2.2 Define the Parameters -- 6.2.3 Use Consistent Data Organization -- 6.2.4 Use Stable File Formats -- 6.2.5 Specify Spatial Information -- 6.2.6 Assign Descriptive File Names -- 6.2.7 Document Processing Information -- 6.2.8 Perform Quality Assurance -- 6.2.9 Provide Documentation -- 6.2.10 Protect Your Data -- 6.3 Prepare Your Data for Archival -- 6.4 What the Archive Does -- 6.4.1 Quality Assurance -- 6.4.2 Documentation and Metadata -- 6.4.3 Release of a Data Set -- 6.5 Data Users -- 6.6 Conclusions -- Appendix: Example R-Script for Processing Data -- References -- Chapter 7: Data Discovery -- 7.1 Introduction -- 7.2 Discovering Data Created by Others -- 7.2.1 Internet Search Engines -- 7.2.2 Data Repositories -- 7.2.3 Data Directories -- 7.2.4 Data Aggregators -- 7.3 Best Practices for Promoting Data Discovery and Reuse -- 7.3.1 Data Products -- Box 7.1 DataCite Recommendations for Data Citation -- Box 7.2 Dryad Digital Repository Data Citation Recommendations -- 7.3.2 Scientific Code -- References -- Chapter 8: Data Integration: Principles and Practice. , 8.1 Introduction -- 8.2 Essential Characteristics of All Data -- 8.3 Data as Records About Reality -- 8.4 Record-Keeping and Prose Documents as Data Integration Challenges -- 8.5 Formal Data Structures Facilitate Integration -- 8.5.1 Sets and Sequences -- 8.5.2 Matrices -- 8.5.3 Cross-classifications -- 8.5.4 Tables -- 8.5.5 Tables or Spreadsheets? -- 8.5.6 Tables or Cross-classifications? -- 8.5.7 Modeling True Tables -- 8.5.8 Need for Global Keys -- 8.6 Merging or JOINing Tables -- 8.6.1 APPENDING or Unioning -- 8.6.2 JOINs -- 8.7 The Datum Is the Atom -- 8.8 Conclusion -- References -- Part III: Analysis, Synthesis and Forecasting of Ecological Data -- Chapter 9: Inferential Modelling of Population Dynamics -- 9.1 Introduction -- 9.2 Inferential Modelling of Ecological Data by the Hybrid Evolutionary Algorithm -- 9.2.1 Population Dynamics of the Cyanobacterium Microcystis in Lake Müggelsee (Germany) -- 9.2.2 Meta-Analysis of Population Dynamics of the Cyanobacterium -- 9.3 Inferential Modelling of Ecological Data by Regression Trees -- 9.3.1 Induction Algorithm of Regression Trees -- 9.3.2 Pruning of Regression Trees -- 9.3.3 Diatom Populations in Lake Prespa (Mazedonia) -- 9.3.4 Vegetation Status of Selected Land Sites in Victoria (Australia) -- 9.4 Conclusions -- References -- Chapter 10: Process-Based Modeling of Nutrient Cycles and Food-Web Dynamics -- 10.1 Introduction -- 10.2 Zero- and One-Dimensional Lake Models -- 10.2.1 Zero-Dimensional Model for the Phosphorus Cycle in a Hypereutrophic Wetland -- 10.2.2 One-Dimensional Model for Nutrient Cycles and Plankton Dynamics in Lakes and Reservoirs -- 10.3 Multi-dimensional Lake Models -- 10.3.1 Horizontal and Vertical Transport of Nutrients and Organisms -- 10.3.2 Multi-segment Lake Model for Studying Dreissenids and Macrophytes -- 10.4 Concluding Remarks -- References. , Chapter 11: Uncertainty Analysis by Bayesian Inference -- 11.1 Does Uncertainty Really Matter? -- 11.2 Hamilton Harbour -- 11.2.1 Introduction -- 11.2.2 Eutrophication Modeling to Elucidate the Role of Lower Food Web -- 11.2.3 Nutrient Export Modeling for the Hamilton Harbour Watershed -- 11.3 Bay of Quinte -- 11.3.1 Introduction -- 11.3.2 Modeling the Relationship Among Watershed Physiography, Land Use Patterns, and Phosphorus Loading -- 11.3.3 Eutrophication Risk Assessment with Process-Based Modeling and Determination of Water Quality Criteria -- 11.4 Concluding Remarks -- References -- Chapter 12: Multivariate Data Analysis by Means of Self-Organizing Maps -- 12.1 Introduction -- 12.2 Properties of a Self-Organizing Map -- 12.3 Data Preparation -- 12.3.1 Missing Values and Outliers -- 12.3.2 Data Transformation -- 12.3.3 Distance Measure -- 12.4 Self-Organizing Maps -- 12.4.1 Architecture -- 12.4.2 Learning Algorithm -- Box 12.1 Sequential Learning Algorithm of an SOM -- 12.4.3 Evaluation of Trained Map Quality -- 12.4.4 Optimum Map Size -- 12.4.5 Clustering SOM Units -- 12.4.6 Evaluation of Input Variables -- 12.4.7 Relations Between Biological and Environmental Variables -- 12.5 Application in Ecological Modelling -- 12.6 SOM Tools -- 12.7 Example of SOM Application -- 12.8 Advantages and Disadvantages -- 12.8.1 Utility for Training and Information Extraction -- 12.8.2 Visualization and Recognition -- 12.8.3 Architecture Flexibility -- 12.8.4 Flexibility in Combining with Other Models -- 12.8.5 Constraints on Measure Consistency and Output Variability -- 12.8.6 Necessity of Sufficient Data -- 12.9 Future Development -- 12.10 Conclusions -- References -- Chapter 13: GIS-Based Data Synthesis and Visualization -- 13.1 Introduction -- 13.2 Synthesizing Species Distributions by Virtual Species. , 13.3 Cartograms to Synthesize and Visualize Sampling Effort Bias -- 13.4 Fuzzy Methods to Synthesize Species Distribution Uncertainty -- 13.5 Synthesis of Remote Sensing Data -- 13.5.1 Exploratory Data Analysis -- 13.5.1.1 Correlation of Remotely Sensed Bands by Hexagon Binning -- 13.5.1.2 Correlation Among Several Layers by Texture Measures -- 13.5.2 Fourier Transformations -- 13.6 Synthesizing Diversity Measurements from Space: The Case of Generalized Entropy -- 13.7 Neutral Landscapes -- 13.8 Conclusions -- References -- Part IV: Communicating and Informing Decisions -- Chapter 14: Communicating and Disseminating Research Findings -- 14.1 Introduction -- 14.2 Publishing Research Findings -- 14.2.1 Scholarly Publications -- 14.2.1.1 Journal Articles -- 14.2.1.2 Abstracts -- 14.2.1.3 Technical Reports -- 14.2.1.4 Books and Book Chapters -- 14.2.2 Newspaper and Magazine Articles for General Audiences -- 14.2.3 Designing Effective Figures -- 14.3 Communicating Research Findings Outside of Publications -- 14.3.1 Simple Steps for Giving an Effective Presentation -- 14.3.2 Best Practices for Slides -- 14.3.2.1 Slide Design -- 14.3.2.2 Text Slides -- 14.3.2.3 Graphics -- 14.3.3 Handouts -- 14.3.4 Posters -- 14.4 Communication in a Virtual Environment -- 14.4.1 Websites -- 14.4.2 Types and Uses of Different Social Media -- 14.4.3 Simple Steps for Effective Use of Social Media -- 14.4.4 Understanding Your Social Media Impact -- 14.5 Metrics and Altmetrics -- 14.6 Conclusion -- References -- Chapter 15: Operational Forecasting in Ecology by Inferential Models and Remote Sensing -- 15.1 Introduction -- 15.2 Early Warning of HABs Based on Inferential Modelling -- 15.2.1 Cyanobacterium Cylindrospermopsis in Lake Wivenhoe (Australia) -- 15.2.2 Cyanotoxin Microcystins in Lake Vaal (South Africa) -- 15.3 Early Warning of HABs Based on Remotely-Sensed Data. , 15.3.1 Earth Observation of Water Quality Parameters.