Making International Collaboration Work: A View from Brazil

1. Earth Observation Business Network Vancouver, CA, May 2002 Making International CollaborationWork: A View from Brazil Gilberto Câmara Director for Earth Observation National Institute for Space Research (INPE) Brazil

2. Introduction • International co-operation • Key issue in civilian EO programmes • Major obstacle to success • “My Fair Lady” syndrome • How to improve? • Understanding each partner’s motivation • Proposal: framework with four critical factors

3. Introduction • Brazilian Space Program • Basis for the position stated • Hope that rationale can be generalized • Relevant experience • LANDSAT data reception and use since 1974 • CBERS China-Brazil Earth Resources Satellite • RADARSAT reception and use

4. Introduction • Position paper • Perspectives from a DSP (developing country with space program) • User and producer of EO data • Government perspective • “Public good” must prevail • “Best use” of citizen’s money • We support the high-tech industry • (our own, preferably....)

5. Government and Job Creation

6. Assessing International Collaboration • Four Key Factors • Strategy • Societal Benefits • Industrial Innovation • Cost • Based on Porter’s Approach • “Competitive Advantage of Nations”

7. The Strategy Factor • Impact of the program in the nation-wide policymaking • When presidents meet, is the program in their agenda? • Is the program seen as influencing positively the commercial balance of trade? • Is the imagery provided capable of making a novel contribution to the management of country’s territory?

8. The Industrial Innovation Factor • Impact of the program in fostering innovation in its high-technology sector • Governments • expect some form of spillover effect • reluctant to spend public funds in supporting high-tech jobs abroad • Requirement • Tangible compensation for the local high-technology industry

9. The Societal Benefits Factor • “Public good” component of EO data • Assessment criteria • Proven applications that can be derived from satellite imagery • Data reliability • Data quality • Data continuity.

10. The Cost Factor • Expected cost reduction by international collaboration • EO programs in DSP • High degree of government intervention. • Seen as R&D investment • Right question • Not “how much does the program cost?” • But “what fraction of a country’s R&D budget is being committed to the program?”.

11. EO-diamond: An example • Hypothetical situation • Useful type of EO satellite • Ground segment = Us$ 50 million (public money)

12. EO-diamond: LANDSAT • Societal benefits (0.95) • Helping Brazil manage its large territory • Cost (0.75) • US$ 60 million in 18 years • Acquisition of ground stations and satellite access fees • Strategy (0.6) • Foundation for the establishment of the Brazilian Earth Observation program • Changes in program status in the US administration • Industrial Innovation (0.3) • Development of Image Processing and GIS technology

13. EO-diamond • Assessment of an EO-program • Benefits of LANDSAT Program to Brazil (1974-2002)

14. Applying the EO-diagram • How Can International Collaboration Work in EO? • when all four decision-making factors (strategy, industry, society and cost) have properly been taken into account and each partner is satisfied that his objectives are met • (in practice....)

15. Improving Societal Benefits • Perspective for increasing market returns • EO from a government-led program to a commercially-led one • Uncertainty in terms of market growth • perception about the limitations of the information content of the satellite data • “Knowledge gap” (MacDonald) • Data-to-information conversion

16. Improving Societal Benefits • Removing barriers to information use • Some high-resolution imagery companies • Restrictions on data distribution • Aerial imagery companies • less restrictive dissemination policy • provide the data integrated into a GIS • Increasing EO market share • Requires changing commercial EO practices

17. Improving Societal Benefits • “Knowledge gap” from EO data • Result of market segmentation • Satellite operators == data providers, • Image processing software companies == systems for information extraction • Market comparison • Spatial information systems = $1.08 billion (1999) • ESRI, leading GIS = US$340 million (1999) • ERDAS, leading IP = US$23.5 million (2000)

18. Improving Societal Benefits • “Deadlock” situation • Small size of commercial IP • Not enough income for R&D investment • Improvements on information extraction • Needed for the market to grow • Knowledge extraction procedures • very litlle technological innovation • limited academic research in EO-GIS integration

19. Improving Societal Benefits • Most applications of EO data • “Snapshot” paradigm • Recipe analogy • Take 1 image (“raw”) • “Cook” the image (correction + interpretation) • All “salt” (i.e., ancillary data) • Serve while hot (on a “GIS plate”) • But we have lots of images!

20. Landsat Image – Rondonia (Brazil)

21. Landsat Image – Rondonia (Brazil)

22. Landsat Image – Rondonia (Brazil)

23. Improving Societal Benefits • What’s in an Image? • Is an image a field of energy received by a sensor? • Are images instruments for capturing landscape dynamics?

24. Improving Societal Benefits • In search of a “killer-app” • How many cutting-edge applications exist for extracting information in large image databases? • How much R&D is being invested in spatial data mining in large repositories of EO data? • How do we put our image databases to more effective use?

25. Improving Societal Benefits • Breaking the “deadlock” in knowledge extraction for EO data • Partnerships between data providers and IP software companies • Government-funded research programmes • Co-operative development environments (“the Linux of EO”)

26. Improving Societal Benefits • International co-operation • Co-operative research programmes • Emphasis on complete cycle of information processing • Research, applications, and technological developments • “Knowledge gap” is tough to remove • Requires a lot of talented researchers • Incompressible amount of time

27. Improving Industrial Innovation • EO industrial components • Commodity-based • Critical technologies • Commodity-based segment • Solar panels, on-board computers, ground stations, launching services • Worldwide market • Russia, India, China, Ukraine and Brazil are potential suppliers.

28. Improving Industrial Innovation • Commodity-based market • Still heavily regulated • Reduced competitiveness • Increased cost • International co-operation • Confidence building • Developing countries becoming major suppliers • “Balanced mutual dependence”

29. Improving Industrial Innovation • Critical technologies • Guidance systems, high-quality optics and electronics, fault-tolerant computing • Technology transfer is very restricted • Countries with EO programs • Cannot affort critical dependence • International co-operation • Step-by-step confidence building • Long-term agreements for reducing tensions

30. Improving Strategy • Key factor • Diplomatic and economic relations • EO development partnerships • No longer limited to G-7 countries • China-Brasil agreement • High-technology development can happen outside of the G-7 world

31. Improving Strategy • Current Situation • Many alternatives for EO collaboration • Negotiations between G-7 and DSP countries • DSP countries no longer simply a market for EO data • DSP countries • More demanding in technology transfer • Access to G-7 markets

32. Improving Cost • Least independent component of the “EO-diamond” • Theory • Co-operation can reduce cost of EO programs • Practice • Relative distortions = preferred allocation to country’s own industry

33. Improving Cost • Can we achieve productivity gains from scale effects? • Requires co-operation at a global scale • Process of industry consolidation • Each major component of a EO mission • available from a small number of industries • Unlikely situation?

34. EO-diamond: CBERS • Expected benefits of CBERS (2000-2010) • Strategy (1.0), Society (0.8), Cost (0.3), Industry (0.65)

35. Co-operation at a Global Scale • “How many EO satellites does the world need?” • Utopian, not superfluous question • Increase scale effects and cost reduction • Avoid duplication in missions • Enhance complementarity

36. Co-operation at a Global Scale • “How many EO satellites does the world need?” • Example from meteorological community • Coordination Group for Meteorological Satellites (CGMS) • Five geostationary satellites (2 US, 1 EU, 1 Russia, 1 Japan) + China + India • Could CEOS play a similar rôle?

37. Co-operation at a Global Scale • Utopia or Possible Realization? • Imperfect, Regulated Market • “Invisible hands” are tied • Need for an international consensus • Requires positive climate for international relations • May take time, but we’ll get there.... • EOBN is an important part of such positive build-up