Agriculture Reference
In-Depth Information
Root RR, Wagtendonk J (1999) Hyperspectral analysis of multi-temporal Landsat TM data for
mapping fuels in Yosemite National Park. In: Annual ASPRS Conference, Portland, OR., USA,
May 17-21, 1999. Society of American Photogrammeters, Bethesda, MD., USA, pp 399-408
Root RR, Stitt SCF, Nyquist MO, Waggoner GS, Agee JK (1985) Vegetation and fire fuel models
mapping of North Cascades National Park. In: The tenth William T. Pecora remote sensing
symposium, Fort Collins, CO, 1985, pp 287-294
Saatchi S, Halligan K, Despain DG, Crabtree RL (2007) Estimation of forest fuel load from
radar remote sensing. Geosci Remote Sens, IEEE Trans 45(6):1726-1740. doi:10.1109/
tgrs.2006.887002
Salas J, Chuvieco E (1994) Geographic information systems for wildland fire risk mapping.
Wildfire 3(2):7-13
Schmidt KM, Menakis JP, Hardy CC, Hann WJ, Bunnell DL (2002) Development of coarse-scale
spatial data for wildland fire and fuel management. USDA Forest Service Rocky Mountain
Research Station, General Technical Report RMRS-GTR-87 Fort Collins, CO, USA, pp 41
Scott J, Burgan RE (2005) A new set of standard fire behavior fuel models for use with Rother-
mel's surface fire spread model. USDA Forest Service Rocky Mountain Research Station,
General Technical Report RMRS-GTR-153. Fort Collins, CO USA, pp 66
Sikkink PG, Keane RE (2008) A comparison of five sampling techniques to estimate surface fuel
loading in montane forests. Int J Wildland Fire 17(3):363-379. doi:Doi 10.1071/Wf07003
Skidmore AK (1989) A comparison of techniques for calculating gradient and aspect from a grid-
ded digital elevation model. Int J Geogr Info Sys 3(4):323-334
Thornton PE, Law BE, Gholz HL, Clark KL, Falge E, Ellsworth DS, Goldstein AH, Monson RK,
Hollinger DY, Falk M, Chen J, Sparks JP (2002) Modeling and measuring the effects of distur-
bance history and climate on carbon and water budgets in evergreen needleleaf forests. Agric
For Meteorol 113:185-222
Varga TA, Asner GP (2008) Hyperspectral and LiDAR remote sensing of fire fuels in Hawaii Vol-
canoes National Park. Ecol Appl 18(3):613-623. doi:10.1890/07-1280.1
Vasconcelos JJPd, Paul JCU, Silva S, Pereira JMC, Caetono MS, Catry FX, Oliveira TM (1998)
Regional fuel mapping using a knowledge based system approach. In: Proceedings: III inter-
national conference on forest fire research and 14th conference on fire and forest meterology,
vol. II, 1998. pp 2111-2123
Verbyla DL (1995) Satellite remote sensing of natural resources. Lewis Publishers, CRC Press
Valley Stream, New York
Vogelmann JE, Kost JR, Tolk B, Howard S, Short K, Xuexia C, Chengquan H, Pabst K, Rollins
MG (2011) Monitoring landscape change for LANDFIRE using multi-temporal satellite imag-
ery and Ancillary data. Selected topics in applied earth observations and remote sensing. IEEE
J 4(2):252-264. doi:10.1109/jstars.2010.2044478
Willis JM (1985) Applications of Landsat imagery for fire fuels mapping projects covering large
geographic areas. In: Proceedings of the Pecora X symposium, 1985. American Society for
Photogrammetry and Remote Sensing, Falls Church, Virginia, USA, pp 394-395
Wilson BA, Ow CFY, Heathcott M, Milne D, McCaffrey TM, Ghitter G, Franklin SE (1994)
Landsat MSS classification of fire fuel types in Wood Buffalo National Park, Northern Canada.
Glob Ecol Biogeogr Lett 4:33-39
Xiao-rui T, McRae D, Li-fu S, Ming-yu W (2005) Fuel classification and mapping from satellite
imagines. J For Res 16(4):311-316. doi:10.1007/bf02858198
Search WWH ::
Custom Search