Use of Remote Sensing Data for Delineation of Wildland Fire Effects

1. Use of Remote Sensing Data for Delineation of Wildland Fire Effects Presented by: Jason Adams Spatial Database Administrator Yukon Wildland Fire Management

2. Overview • Background Information • Platforms Utilized • Methodologies Employed • Conclusions

3. Remote Sensing Platforms • MODIS (Moderate Resolution Imaging Spectroradiometer) • LandSAT TM/ETM (Thematic Mapper) • SPOT Image • QuickBird • Airborne GPS

4. Background Information • MODIS Hotspot Fire Detections

5. Background Information • False colour MODIS image Fall 2004 • LandSAT TM Bands very similar

6. Background Information Red = Band 7 (mid-IR) Green = Band 4 (near-IR) Blue = Band 3 (visual red)

7. MODIS Platform • There are two main products of the MODIS program employed by WFM. • Hotspot data (Thermal) • False colour imagery (Reflected Infrared)

8. MODIS Platform

9. Using MODIS Hotspot Data

10. Using MODIS Hotspot Data

11. Using MODIS Hotspot Data Classic Geoprocessing Hotspot points Buffer points Back-Buffer points

12. Using MODIS Hotspot Data

13. Using MODIS Hotspot Data Map Display

14. SPOT Image • 10m SPOT Imagery • Black indicates burn area, red indicates healthy vegetation (Similar to IR Photo) • Heads up digitized on tablet PC running ArcMap

15. Quickbird • In 2007 this image was acquired along the Dempster Highway and contained part of a 2007 fire. • Testing phase for uses in delineation of fire effects.

16. LandSAT TM • Overview of 2007 fire DA-11 in a 7-4-3 LandSAT TM band combination • Detail shown at level used for Heads-up digitizing. • Scene Level View, DA-11 seen in bottom left quadrant. • Even light cloud cover is still valuable.

17. Comparison of Methods • Fire BC-03-2006 • MODIS Hotspot Buffer • GPS Perimeter • LandSAT Perimeter • Comparison in detail

18. Burn Severity & LandSAT

19. TM4 – TM7 NBR = TM4 + TM7 Burn Severity & LandSAT Landsat Pre and Postfire Views of the Herron River Fire, DENA 2001

20. Burn Severity & LandSAT • WFM has run a trial with dNBR • Some challenges are faced. • Could lead to automated fire poly generation with some GIS processing. • No field verification program, see challenges above.

21. Airborne GPS • Becoming rare for use as final mapping as cost and accuracy of hyper-spectral satellite imagery is becoming lower, soon to be free (LandSAT). • Mainly used on campaign fires where data is needed right away. • Although accuracy is “better” on GPS units then a 30m pixel LandSAT image the method of collection (flying around in a helicopter) compromises this. Picture an intoxicated individual walking a line.

22. GPS Accuracy Three hour plot of stationary GPS, differentially corrected

23. Airborne GPS Real World example BC-03-06 Pre Fire LandSAT Scene Pre Fire LandSAT Scene with GPS Track Post Fire LandSAT Scene Post Fire LandSAT Scene with GPS Track Post Fire LandSAT Scene with GPS Track (blue) and RS digitized perimeter (yellow) Comparison of GPS Track (blue) and RS digitized perimeter (black)

24. Methodologies • Primary method of fire effects (perimeter) data capture is via digitizing hyperspectral imagery on tablet PC. • Secondary method is GPS capture • Future methods to use hyperspectral data and dNBR, this will give both perimeter and severity data.

25. Conclusions • Given the size of the Yukon and staffing level, Remote Sensing is the ONLY option for collection of fire data. • For present time LandSAT is perfectly adequate, SPOT shows a gain is precision but would be cost prohibitive. • Quickbird is interesting however would probably be only used for WUI or large scale mapping of culturally/ecologically significant targets

26. Thank-you Haeckel Hill Fire, Whitehorse, 1991