Milan KONECNY President; International Cartographic Association (ICA) Institute of Geography, Faculty of Science, Masaryk University, Kotlarska 2, 611 37 BRNO, Czech republic konecny@geogr.muni.cz lgclogo • • •Cartography and SDI World: •the role, place and potentials. • • •20th EUC, Warsaw,Oct 26, 2005 • • • •International Cartographic Association •www.icaci.org Commissions of ICA •Commission on Cartography and Children •Commission on Education and Training •Commission on Gender and Cartography •Commission on Generalisation and Multiple Representation •Commission on the History of Cartography •Commission on Incremental Updating and Versioning •Commission on Management • and Economics of Map Production •Commission on Mapping from Satellite • Imagery •Commission on Map Projections •Commission on Maps and Graphics • for the Blind and the Partially Sighted •Commission on Maps and the Internet •Commission on Marine Cartography •Commission on Mountain Cartography • •Commission on National and Regional • Atlases •Commission on Planetary Cartography •Commission on Spatial Data Standards •Commission on Theoretical Cartography •Commission on Ubiquitous Mapping •Commission on Visualization and Virtual • Environments • • • • • •Working Group on Mapping Africa for Africa • •Working Group on Spatial Data Uncertainty • and Map Quality • •WG on Use and User issues • •WG on Geospatial analysis • •WG on historical geometrical analysis • •Publications Committee • • • •ICA and ESRI • • 1.Information/Knowledge-based Society 2.European Challenges 3. Position of Cartography (geotechnology) 4. GMES and INSPIRE •5. State of the Art of Cartography •6. SDI and Cartography •7. Geospatial Information & the Knowledge Economy •8. Early Warning, Disaster management and cartography: Nobody is Perfect? • •„Information Society” is the term that is used to capture the increasing contemporary influence of information and communication technologies (ICTs). • •Knowledge-based society enhances content of the processes based on data, information and knowledge. •Information Society •Sustainable Information Society • •The linkage between sustainability •and information society development •is still poorly understood. • • • •2. European Challenges • • •“i2010 – A European Information Society for growth and employment” • •COM(2005) 229 final •COMMUNICATION FROM THE COMMISSION TO THE COUNCIL, THE •EUROPEAN PARLIAMENT, THE EUROPEAN ECONOMIC AND SOCIAL •COMMITTEE AND THE COMMITTEE OF THE REGIONS •Brussels, 31.05.2005 •(Text with EEA relevance) • •i2010 Content: • •A single European information space • •Inclusion, better public services and quality of life • •Conclusion: i2010 within the new Lisbon governance cycle p-009412-00-2h • •Connecting the UK: the Digital Strategy • •Cabinet Office •Prime Minister’s Strategy Unit • •March 2005 • •UK Approach •Contents • •Section 1: A ‘digitally rich’ UK – progress to date •Section 2: The ‘digital divide’: problems with low take-up •Section 3: Why should the Government intervene to promote take-up? •Section 4: How can we close the digital divide and become a world leader in digital excellence? • • •• Raising our game: Making the UK a world leader in digital excellence • •Action 1: Transform learning with ICT •Action 2: Set up a “Digital Challenge” for LAs •Action 3: Make the UK the safest place to use the Internet •Action 4: Promote the creation of innovative broadband content •• Constructing a robust strategy to achieve our vision • •Action 5: Set out a strategy for transformation of delivery of public services • •Action 6: Ofcom’s strategy should consider improving competition and take-up in the broadband market • •• Tackling social exclusion & bridging the digital divide • •Action 7: Improve accessibility to technology for the digitally excluded and ease of use for the disabled • •Action 8: Review the digital divide in 2008 • • • •OS MasterMap: • •a definitive digital map of Great Britain, providing •detailed geographic information for a wide range of business and government purposes. • •OS MasterMap underpins a huge range of •commercial services used by millions of people every day. Changing models of geographic information •Paper map •Digital data file • •Spatial database topo topoaddress topoaddressitn topoaddressitnimagery •Topography •Addresses •Integrated Transport Network •Imagery Layers of OS MasterMap •Tony Blair, Patricia Hewitt: • •….. We now have a world-leading position in digital TV…. the most extensive – and one of the most competitive broadband markets in the G7. • •Virtually all households in the UK are within •easy-reach of a UK online centre where they can access the internet in a safe, secure and •supportive environment. • • •We cannot…think the job is done. We must harness the power of ICT to modernise public services so they are as personalised, efficient and responsive as the most successful companies. • •We must be in the forefront of new technologies to remain globally competitive. • •And most important of all, we must make sure the whole of society can experience the benefits of the internet. •Too many people still don’t enjoy the advantages of that ICT offers. We are committed to ending the digital divide for families with children by the end. …. • •Strategy to make the UK a world •leader in digital excellence and the first nation to close the digital divide. • • • •How is reacting and what will do cartographic and geoinformatics community? • •GI in IT? • • •3. Position of Cartography (Geotechnology) • •Mapping • opportunities •Nature, January 2004 • • •Scientists who can combine geographic information systems with satellite data •are in demand in a variety of disciplines. • •In start of 2004, the US Department of Labor identified geotechnology as one of the three most important emerging and evolving fields, along with nanotechnology and biotechnology. • •The demand for geospatial skills is growing •worldwide, but the job prospects reflect a country’s •geography, mapping history and even political agenda. • • • • • •4. COPERNICUS (GMES) and INSPIRE • •Global Monitoring for Environment and Security (GMES) • •seeks to bring together the needs of society related to the issue of environment and security with the advanced technical and operational capability offered by terrestrial and space born observation systems. GMES relevant policy areas: •Sustainable Development • •Global Climate Change • •Common Defence and Security Policy • •European Research Area • •European Strategy for Space • • • •(INSPIRE/ESDI) •Global Monitoring for Environment and Security • • INSPIRE •Infrastructure for Spatial Information in Europe • • •The INSPIRE concept: • •Availability •Accessibility •Legislation rules. • • • Current status Architecture model • • • •Clients •Middleware •Servers •Features •Coverages •Metadata update • • • •Catalogs •Geo-processing •and catalog Services • • • • • • • •Content •Repositories • •Other data • •e.g., administrative, •statistical, env. reporting • •Distributed Geographic reference data • • •Service chaining: •search, display, access, e-commerce, •…. • •User applications • •Direct •data •access • •Access to transformed •data, pictures, maps, reports, •multi-media content •Metadata search and retrieval for •data and services • • • •After the Digital Earth Reference Model INSPIRE Scope: 17 Themes-1 •1. Geographical location •2. Administrative units •3. Properties, buildings and addresses •4. Elevation •5. Geo-physical environment • •6. Land surface/land cover •7. Transport •8. Utilities and facilities •9. Society and population •10. Spatial planning/ Area regulation • INSPIRE Scope: 17 Themes-2 •11. Air and climate •12.Water/ • hydrography •13. Ocean and seas •14.Biota/biodiversity •15. Natural resources • •16. Natural and technological risks and natural disasters •17. Areas under anthropogenic stress •The term Spatial Data Infrastructure (SDI) is used to encapsulate the technologies, policies, institutional arrangements, financial and human resources that facilitate the availability, access and effective usage of geographic data. Start: Clinton 1994. •The SDI provides the means for discovery, access and application of spatial data for policy-makers, planners and managers, citizens and their organizations. •SDI technologies consist of a set of data services that provide geographic data and their attributes. •Services and data are documented with meta-data which that subsequently offer the means •to discover, visualise and evaluate the data through the Web. Additionally, methods are provided to access the data. Applications are built to solve specific needs on the data service layer. •Santiago Borrero (PAIGH SG): importance of non-technical variables in SDI building in Developing Nations. • •“Culturally speaking, particularly, there is a problem of attitude and a history of isolation, ill-defined ideas, language barriers, and financial challenges. In every country SDI will reflect local social and economic conditions, cultural aspects and elements related to national identity“. 1. • • • • • • •GEOSS and GNSS Activities • •G-8 Conference 2003 in Evian: • the Ad hoc „Group on Earth Observation“ (GEO) were created with intention to design Global Earth Observation System of Systems (GEOSS). •Earth Observation Summit 2005 in Brussels decided about permanent GEO activities (based at WMO, Geneva, Switzerland). • The 10 Years Implementation Plan, so called - 10YIP was adopted. •Purpose of GEOSS (ref. 1st EOS in 2003) •1. to achieve comprehensive, coordinated, and sustained Earth observations for the benefit of humankind. •2. to improve • - monitoring of the state of the Earth, • - increased understanding of dynamic • Earth processes, • - enhanced prediction of the Earth • system, and • - further implementation of international • environmental treaty obligations. • • Nine Societal Benefit Areas of GEOSS have been formulated • •Disasters •Health •Energy •Climate •Water • •Weather •Ecosystems •Agriculture •Biodiversity • • •GLOBAL SPATIAL DATA PROJECTS •Global Mapping •Global Spatial Data Infrastructure (GSDI) •Digital Earth •U. N. Geographic Data Base •GI for Sustainable Development (GISD) (OGC) •GNSS (EOS, GEOS, GEOSS), FAO.. • • maparelie parqnaturales reginaturale zoniifclimatica politico Understanding Digital Earth cloud89a elnin89a Cloud El Nino sst89a Sea water temperature botto89a Earth Surface quake89a Earthquake volca89a Volcano ndvi89a Vegetation plate89a Plate Boundary (http://www.nasm.si.edu/EarthToday) • •Tools & •Technology •Tools & •Technology •Enabling Citizens •and Communities •Enabling Citizens •and Communities •Interoperability •Interoperability •Collecting Data •Collecting Data •EARTH •EARTH •Digital Resources •Digital Resources Understanding Digital Earth •(White paper by NASA Digital Earth office, 2000) •U.N. department of Outer Space in Vienna: • •GNSS (Global Spatial and Navigation Systems) – harmonization of data and information from NAVSTAR, GALILEO, GLONASS and other systems for everyday users needs. •LBS • IMG_0308 • • • •5. State of the Art of Cartography • • • •Cartography needed • •Cartography offer its help mapa_palava •Prehistoric Map, Pavlov Hills, South Moravia, 24 000 B.C. • 219 komenius DSM_DTM_image • sh1 •3-D Image of Pudong Area, Shanghai • •Height •Unit: m •Elevation Map of Buildings Produced from 3-D Imager 3 •It is not enough to build a nice technical infrastructure without teaching the population how to use the maps (analog or digital one). •We have to provide: -the concepts with which the population is able to deal with geospatial information, -to provide maps from which the population is able to derive the information they need: information that is up-to date and tailor made for solving the problems. • •Cartography is originally an instinctive science, which nowadays enters a new, revolutionary period of its development. • •In a modern approach, mapping is understood as the ability to create a knowledge frame of an environment in space. • • •The creation of maps and the use of maps, have evolved separately for centuries. • • •A new generation of electronic maps and atlases, mainly on the Internet, resulted in the definition of multimedia cartography. • •Multimedia, global communication systems, and global publishing offer possibilities for the production of dynamic and interactive visualizations, which utilize mainly virtual environments (developed originally for the computer games industry). • Cube2 • •The Map use cube showing four forms of visualization for exploration. • Analysis and Presentation A.M. MacEachren) •Intelligent access to databases and interactive user support can be used not only for the location of suitable maps on the Internet, but also for map creation and modification according to • specific and individual requirements. •Instead of just using maps created by someone else in advance, these new research technologies allow individuals •to use cartography interactively, on the basis of individual user's requirement, to study and present spatial information. •Four most dynamic streams •in cartography: • 1.Cartographic visualization (ICA Commission on Visualization and Virtual Environments). 2.Ubiquitous mapping 3.Internet maps 4. Map Use •Cyber Cartography??? 1. 1. Geographical Information is going mobile Interest •Differences between GIS and Maps (Morita). •GIS means data input, database building, data analysis and data output for spatial information. •Mapping includes not only map making, but also map use and map communication, as it considers the interaction between map, spatial image and the real world. •GIS is system function oriented, whereas •Map is human-oriented, including spatial cognition, decision making and communication. • マッピング空間EC • • • • Where SDIs end, cartography begins? • • •Geographer Ptolemy first developed the idea of atlases: how to subdivide the world into 26 parts, how to portray the world in its entity and in parts. We are still using his ideas of subdividing the world, in parts from north to south and from west to east. • •Ortelius Atlas • •Mercator Atlas • OrtAtlas2 OrtAtlas1 •We are refining these ideas; • •In another geodata revolution, in the 19th century, we used nationaI atlases; • •The next geodata revolution at the end of the 20th century led us to digital atlases. • •But still we keep these cartographic ideas of making sense of the world. • Karlsruhe7 • • •Without guaranteed access (in sensu lato meaning) to the geospatial data and information also •the cartographical ambitions to be part of the game will be hard to reach. So there is much at stake for us cartographers as well. • • • • • • •7. Early Warning, Disaster mnagement and cartography: Nobody is Perfect? • • Praha – Vltava river mosty2 f04_mosty4 •PRAHA – capital of Czech Rep. • 57 districts •Area 496 km2 •Amount of Inhabitants 1,16 mil . •KOBE - Hyogo Declaration: •it was recognized that a culture of disaster prevention and resilience, •and associated pre-disaster strategies, must be fostered at all levels, ranging from the individual to the international levels. Human societies have to live with the risk of hazards posed by nature. •Examples of the atlas concept – atlases as ways of storage of geospatial information we have learned to deal with – are for instance emergency-atlases. • • •Here in the first place atlases allow us access to the area involved, the atlas opens the door to that area, and allows also people faraway to understand its problems. • •Maps are prepared and elaborated knowledge!!!! • A technology for designing of 3D maps • • • •Preparation of Sources for Map Creation • • • • • • •Converting of Sources in Digital Form • • • • • • •Including Third Coordinates • • • • • • •Reconstruction of Digital Terrain Model (DTM) • • • • • • •Designing of Main Content (buildings, streets etc.) • • • • • • •3D Symbolization of the 3D Map • • • • • • •Preparation of Photo textures • • • • • • •Photo-Realistic Visualization of 3D Map • • • • • •Flood 3D Main content - in flood mapping •large topographic or landscape objects – • relief bodies * roads * buildings Secondary content •traffic signs •facilities •transport elements • scene •3D map “a street in Vienna”, created by ICG, TUGraz and 3D symbols created by T. Bandrova * information signs * trees * geodetic points ghjhghjhg Additional content •quality and quantity information about objects – fence, roof, street, parcel •created as a textural database • • • View_OldSchool2_2 Sources for 3D map •paper topographic or cadastral maps •photogrammetric or surveying data •digital 2D map •topographic information, measurements, architecture drawings etc. •digital or paper photos •3D symbol system • • • • 6 ghjhghjhg •VIEW from OUTSIDE • •Kobe: •GSDI potential and the Global Mapping potential are not enough visible, at least in conference documents. •QUESTIONS: •Is it some kind of ignorance or simply the fact that we are insufficiently able to offer our results in a way which will be a part of the culture of disaster prevention and resilience, and associated pre-disaster strategy (using the words of Hyogo Declaration)? •Are we still too much concerned with the technological aspects and not enough with developing approaches towards people who needs all of our data for their everyday life, but also need to get them in a form they can understand? • •Unfortunately, lessons from recent disaster management show that the decision makers that needed the geospatial information did not have access to it in time, nor in a form they were taught to deal with. • • • • •5. Geospatial Information & the Knowledge Economy Contributions • •Geospatial •Information • • • •The •Knowledge •Economy • • •D.Coleman,Dubai,2005 Contributions of GI to the Knowledge Economy •Criteria Contribution •Knowledge Jobs High tech employment in remote sensing, mapping and surveying hardware; software development; IT consulting; application development; geospatial data collection; and project/program management. Globalization Companies in Europe, North America and Australia are partnering with IT and mapping firms in India, China and elsewhere to take advantage of a highly qualified workforce prepared to work at very competitive rates of pay. Contributions of GI to the Knowledge Economy •Criteria Contribution •Economic Dynamism and Competition •SDI evolution encourages creation and growth of new high-technology companies: •Stage 1 and Stage 2 -- New hardware, software and data collection firms to support government mapping and data collection projects. •Stage 3 -- Focus shifts to IT consulting firms as interest increases in data maintenance, enterprise GIS; data distribution and interoperable systems. •Stage 4 -- Emphasis on applications development, specializ. data collection, LB services. Contributions of GI to the Knowledge Economy •Criteria Contribution Transformation to a Digital Economy Real property information component now driving applications in E-Government. • Data related to address-matched road networks driving applications in Location-Based Services and E-Commerce. •Technological Innovation Capacity New capital investments and returns from intellectual property tend to be focused on geospatial firms involved in hardware / software development, location-based services, and situations where the firm has a monopoly on management and distribution of key datasets. Contributions • •Geospatial •Information • • •The •Knowledge •Economy • • • •D.Coleman,Dubai,2005 • • •Optimistic, success-oriented, •conservative •Civic •1981 - 2000? •Millennials •Spiritual awakening; Beginnings of global awareness; Aiming to ‘carry things forward’ •Idealistic • •1943 - 1960 • •Baby-Boomers • •Flexible; sensitive to diversity (told by parents during WW2 ‘Stay out of the way, we’re busy’). •Adaptive • •1925 - 1942 • •Silent Generation • •Responded to social crisis (WW2); Focussed on common good, community, and “rebuilding the world”. •Civic • •1901 - 1924 • •GI Generation • •Comments •Characteristic •Born between… •Generation Title • •- from work by Neil Howe and William Strauss •Cynical, pragmatic, questioning •Reactive •1961 - 1981 •Generation X The “Millennial Students” now moving into the Workplace •Based on the research of Neil Howe and William Strauss. •Newest books –Millennials Rising – the Next Great Generation and Millennials Go to College: Strategies for a New Generation on Campus •“The Millennials say they want to use technology. They want to use the web as a means to access information and one another.They want to work on solving problems that matter and they want to do this in collaborative teams.” Implications to Future Geospatial Services? •Must be… •Quick •Anonymous •Authoritative •Delivered “Just-in-Time” (“Use it and lose it”) •Easy to share on-line with friends and colleagues. Geospatial Information & the Knowledge Economy •Are current SDI services oriented to continue affecting Knowledge Economy Indicators? •Will the “look and feel” of SDI services change as expectations of Millennial Generation begin to dominate the market? •What indicators will determine the success or failure of SDI over the next 10 years? •Roles of Government as SDI evolves? •NATURE again….: • •AN EXPANDING MARKET •All indications are that the US$5-billion worldwide •geospatial market will grow to $30 billion by 2005 •- a dramatic increase that is sure to create new jobs. • •NASA says that 26% of its most highly trained •geotech staff are due to retire in the next decade, and the National Imagery and Mapping Agency is expected to need 7,000 people trained in GIS in the next three years. 1.Big Data: buzz word or reality? 2. Information superhighway, SDI´s, System of Systems concepts (GEO, GEOSS,..) BD4 • (Bandrova, Konecny, Yotova, 2014) • • • • BD: Definitions • •Zucker, S., (2014) : • • “a popular term used to describe the exponential growth and availability of data, both structured and unstructured” . • •”There is no rigorous definition of big data. Initially the idea was that the volume of information had grown so large that the quantity being examined no longer fit into the memory that computers use for processing, so engineers needed to revamp the tools they used for analyzing it all” (Mayer-Schönberger V., Cukier K., 2013). • • • • How to manage volunteer geographic information? Chaos or help? • •Volunteer geographic information VGI: • • “The terms, “crowdsourcing” and “collective intelligence” draw attention to the notion that the collective contribution of a number of individuals may be more reliable than those of any one individual. • •The term VGI refers specifically to geographic information and to the contrast between the actions of amateurs and those of authoritative agencies.” Goodchild (2009, p. 18) •Virtual Geographic Environments • • •Kniha v češtině •Next ICC • •Moscow 2007 • •Next after Next • •Chile 2009 PRAHA BRNO1 PALAVA • •BLAGODARJA •Aligator •Xie, Xie •THANK YOU •VERY •MUCH !!!!! • •DĚKUJI ( in Czech) •