1. The value of scientific data confessions of an applied environmental scientist Neil Burrows Science Division Department of Environment & Conservation Western Australia Department of Environment & Conservation Western Australia

2. Slide courtesy N. Burrows Becoming a scientist; destiny or serendipity? From fighter pilot to fire ecologist?

3. Slide courtesy N. Burrows Science & Scientists Identify the problem and define the research question(s) Identify the problem and define the research question(s) Do background research Do background research Formulate a hypothesis Formulate a hypothesis Test hypothesis by experimentation Test hypothesis by experimentation Collect data Collect data Analyze data and draw conclusions Analyze data and draw conclusions Communicate findings Communicate findings

4. Slide courtesy N. Burrows Role of science in conservation & land management  Science informs policy, planning and decision making  Science underpins conservation and land management actions  Engenders political & community confidence  Agency credibility

5. Slide courtesy N. Burrows Data acquisition Knowledge from data gathered via; Experimental research Experimental research Survey Survey Monitoring Monitoring Adaptive management Adaptive management The global science network The global science network

6. Slide courtesy N. Burrows Life as an applied scientist: experimental design and implementation Identify the variables to be measured Identify the variables to be measured Determine procedures for measuring/collecting data Determine procedures for measuring/collecting data Establish experimental sites Establish experimental sites Implement treatments, collect data Implement treatments, collect data Enter and check data Enter and check data Analyse & interpret data Analyse & interpret data Present data Present data Publish & communicate findings Publish & communicate findings Determine implications of findings and transfer knowledge (tech transfer, knowledge uptake) Determine implications of findings and transfer knowledge (tech transfer, knowledge uptake) Move on to next research program Move on to next research program

7. Slide courtesy N. Burrows Something missing? The Confession What happens to the data? What happens to the data? –A small subset are published –Most stagnate in personal filing cabinets, computers, notebooks, field sheets, etc –Sometimes thrown out! Why bother with post-research data management?

8. Slide courtesy N. Burrows Bushfire Management Fire Management Objectives Protect life, property and ecosystem services from wildfires Protect life, property and ecosystem services from wildfires Protect biodiversity & ecosystem health Protect biodiversity & ecosystem health Reduce greenhouse gas emissions Reduce greenhouse gas emissions Fire Management Strategies Planned (prescribed) burning Fire detection Fire suppression

9. Slide courtesy N. Burrows Research to underpin bushfire management Fire behaviour Fire behaviour Fire ecology and impacts Fire ecology and impacts –Forests –Hummock grasslands

10. Slide courtesy N. Burrows Fire Behaviour Research Objective: To model the behaviour of bushfires in order to: Objective: To model the behaviour of bushfires in order to: –Forecast fire danger –Predict fire behaviour

11. Slide courtesy N. Burrows Field-based (empirical) approach Identify and measure variables thought to influence fire behaviour Identify and measure variables thought to influence fire behaviour –Fuel –Weather –Topography Measure fire behaviour variables Measure fire behaviour variables –Flame rates of spread –Flame dimensions –Fire intensity (killing power) –Fire perimeter & area growth Model relationships Model relationships

12. Slide courtesy N. Burrows Data collection (field work) ~ 250 experimental and wildfires over 15 years ~ 250 experimental and wildfires over 15 years  Establish experimental plots  ~3,000 sample points  ~10 attributes at each point  Conduct exp. burns  10 person years of field work  Field work cost ~ $3M

13. Slide courtesy N. Burrows Managing the data (office work) Clean-up and entry Clean-up and entry Analysis Analysis Write-up Write-up Converting data into knowledge: Communication & tech transfer Converting data into knowledge: Communication & tech transfer –35 person years –Cost ~3.5M

14. Slide courtesy N. Burrows Science Division of the WA Department of Environment & Conservation (DEC) ~130 science projects ~130 science projects 174 staff 174 staff Annual expenditure ~$20M Annual expenditure ~$20M Generating 10 x pieces of data each year Generating 10 x pieces of data each year

15. Slide courtesy N. Burrows

29. The $ cost of collecting and working with data – DEC Science Division Annual research budget ~$20M or ~$200M per decade. Annual research budget ~$20M or ~$200M per decade. Data cost component of this is ~ $150M per decade. Data cost component of this is ~ $150M per decade. DATA ARE VERY VALUABLE!

30. Slide courtesy N. Burrows Importance of good data management Data have high $ value Data have high $ value Data = knowledge = power & influence! Data = knowledge = power & influence! Protect data from loss or misuse Protect data from loss or misuse Responsibility & accountability - usually a 3 rd party has paid for data Responsibility & accountability - usually a 3 rd party has paid for data Tradable Tradable

31. Slide courtesy N. Burrows Importance of good data management Value add, re-analyse (e.g., climate change, new techniques) Value add, re-analyse (e.g., climate change, new techniques) Shared Shared Avoids duplication Avoids duplication Some data are irreplaceable (unique) Some data are irreplaceable (unique) WE NEED A DATA MANAGEMENT PLAN

32. Slide courtesy N. Burrows Data management: some attributes Database structure Database structure –Logical directories or files –Named –Easy to access –Relationships with other databases Data warehouse Data warehouse –Secure –Accessible (input and extract) –Maintain integrity of data Data mobility Data mobility –Easy to move/transfer –Hardware/software compatibility –Data mining Database administration Database administration –Dedicated resources –Corporate systems

33. Slide courtesy N. Burrows Conclusions We live in a world dependent on knowledge and information for “sustainable development” Data are valuable at many levels Need (and legal obligation) for institutions to develop systems & infrastructure to preserve, protect and facilitate access to data Good data management = we work more efficiently and effectively as an individual and as an agency Good data management = we work more efficiently and effectively as an individual and as an agency

34. Slide courtesy N. Burrows Thank You (Blood, Sweat………. and Beers!)