Forest degradation in the Brazilian Amazon due to selective logging and forest fires may greatly increase the human footprint beyond outright deforestation. We demonstrate a method to quantify annual deforestation and degradation simultaneously across the entire region for the years 2000–2010 using high-resolution Landsat satellite imagery. Combining spectral mixture analysis, normalized difference fraction index, and knowledge-based decision tree classification, we mapped and assessed the accuracy to quantify forest (0.97), deforestation (0.85) and forest degradation (0.82) with an overall accuracy of 0.92. We show that 169,074 km 2 of Amazonian forest was converted to human-dominated land uses, such as agriculture, from 2000 to 2010. In that same time frame, an additional 50,815 km 2 of forest was directly altered by timber harvesting and/or fire, equivalent to 30% of the area converted by deforestation. While average annual outright deforestation declined by 46% between the first and second halves of the study period, annual forest degradation increased by 20%. Existing operational monitoring systems (PRODES: Monitoramento da Florestal Amaz?nica Brasileira por Satélite) report deforestation area to within 2% of our results, but do not account for the extensive forest degradation occurring throughout the region due to selective logging and forest fire. Annual monitoring of forest degradation across tropical forests is critical for developing land management policies as well as the monitoring of carbon stocks/emissions and protected areas.
References
[1]
Rosa, I.M.D.; Souza, C.; Ewers, R.M. Changes in size of deforested patches in the Brazilian Amazon. Conserv. Biol 2012, 26, 932–937.
[2]
Shimabukuro, Y.E.; dos Santos, J.R.; Formaggio, A.R.; Duarte, V.; Rudorff, B.F.T. The Brazilian Amazon Monitoring Program. In Global Forest Monitoring from Earth Observation; Achard, F., Hansen, M.C., Eds.; CRC Press: Boca Raton, FL, USA, 2012; pp. 167–184.
[3]
Souza, C., Jr. Monitoring of Forest Degradation. In Global Forest Monitoring from Earth Observation; Achard, F., Hansen, M.C., Eds.; CRC Press: Boca Raton, FL, USA, 2012; pp. 185–208.
[4]
Numata, I.; Cochrane, M.A.; Roberts, D.A.; Soares, J.V.; Souza, C.M.; Sales, M.H. Biomass collapse and carbon emissions from forest fragmentation in the Brazilian Amazon. J. Geophys. Res.: Biogeosci 2010, 115, G03027.
[5]
Nepstad, D.C.; Varissimo, A.; Alencar, A.; Nobre, C.; Lima, E.; Lefebvre, P.; Schlesinger, P.; Potter, C.; Moutinho, P.; Mendoza, E.; Cochrane, M.; Brooks, V. Large-scale impoverishment of Amazonian forests by logging and fire. Nature 1999, 398, 505–508.
[6]
Asner, G.P.; Knapp, D.E.; Broadbent, E.N.; Oliveira, P.J.C.; Keller, M.; Silva, J.N. Selective logging in the Brazilian Amazon. Science 2005, 310, 480–482.
[7]
Chen, Y.; Randerson, J T.; Morton, D.C.; DeFries, R.S.; Collatz, G.J.; Kasibhatla, P.S.; Giglio, L.; Jin, Y.; Marlier, M.E. Forecasting fire season severity in South America using sea surface temperature anomalies. Science 2011, 334, 787–791.
[8]
Skole, D.; Tucker, C. Tropical deforestation and habitat fragmentation in the Amazon—Satellite data from 1978 to 1988. Science 1993, 260, 1905–1910.
[9]
Asner, G.P.; Broadbent, E.N.; Oliveira, P.J.C.; Keller, M.; Knapp, D.E.; Silva, J.N.M. Condition and fate of logged forests in the Brazilian Amazon. Proc. Natl. Acad. Sci. USA 2006, 103, 12947–12950.
[10]
Matricardi, E.; Skole, D.; Cochrane, M.A.; Pedlowski, M.; Chomentowski, W. Multi-temporal assessment of selective logging in the Brazilian Amazon using Landsat data. Int. J. Remote Sens 2007, 28, 63–82.
[11]
Numata, I.; Mark, A.C.; Carlos, M.S., Jr.; Marcio, H.S. Carbon emissions from deforestation and forest fragmentation in the Brazilian Amazon. Environ. Res. Lett 2011, 6, 044003.
[12]
Cochrane, M.A.; Laurance, W.F. Fire as a large-scale edge effect in Amazonian forests. J. Trop. Ecol 2002, 18, 311–325.
[13]
Souza, C.M., Jr.; Roberts, D.A.; Cochrane, M.A. Combining spectral and spatial information to map canopy damage from selective logging and forest fires. Remote Sens. Environ 2005, 98, 329–343.
[14]
Alencar, A.; Asner, G.P.; Knapp, D.; Zarin, D. Temporal variability of forest fires in eastern Amazonia. Ecol. Appl 2011, 21, 2397–2412.
[15]
Morton, D.C.; DeFries, R.S.; Nagol, J.; Souza, C.M., Jr.; Kasischke, E.S.; Hurtt, G.C.; Dubayah, R. Mapping canopy damage from understory fires in Amazon forests using annual time series of Landsat and MODIS data. Remote Sens. Environ 2011, 115, 1706–1720.
[16]
Roberts, D.A.; Numata, I.; Holmes, K.; Batista, G.; Krug, T.; Monteiro, A.; Powell, B.; Chadwick, O.A. Large area mapping of land-cover change in Rondonia using multitemporal spectral mixture analysis and decision tree classifiers. J. Geophys. Res.: Atmos 2002, 107, 8073.
[17]
Cochrane, M.A.; Souza, C.M., Jr. Linear mixture model classification of burned forests in the Eastern Amazon. Int. J. Remote Sens 1998, 19, 3433–3440.
Johns, J.S.; Barreto, P.; Uhl, C. Logging damage during planned and unplanned logging operations in the eastern Amazon. Forest Ecol. Manage 1996, 89, 59–77.
[20]
Nepstad, D.C.; Verissimo, A.; Alencar, A.; Nobre, C.; Lima, E.; Lefebvre, P.; Schlesinger, P.; Potter, C.; Moutinho, P.; Mendoza, E.; Cochrane, M.; Brooks, V. Large-scale impoverishment of Amazonian forests by logging and fire. Nature 1999, 398, 505–508.
[21]
Souza, C.M.; Roberts, D.A.; Cochrane, M.A. Combining spectral and spatial information to map canopy damage from selective logging and forest fires. Remote Sens. Environ 2005, 98, 329–343.
[22]
Souza, C., Jr.; Siqueira, J.V. ImgTools: A Software for Optical Remotely Sensed Data Analysis. Proceeding of Anais XVI Simpósio Brasileiro de Sensoriamento Remoto, Foz do Igua?u, PR, Brazil, 13–18 April 2013; pp. 1571–1578.
[23]
Verbyla, D.L.; Boles, S.H. Bias in land cover change estimates due to misregistration. Int. J. Remote Sens 2000, 21, 3553–3560.
[24]
Carlotto, M.J. Reducing the effects of space-varying, wavelength-dependent scattering in multispectral imagery. Int. J. Remote Sens 1999, 20, 3333–3344.
[25]
Roberts, D.A.; Adams, J.B.; Sabol, D.E. Remote sensing of vegetation in Amazonia, ecological implications of spectral mixtures. Bull. Ecol. Soc. Amer 1993, 74, 412.
[26]
Adams, J.B.; Sabol, D.E.; Kapos, V.; Filho, R.A.; Roberts, D.A.; Smith, M.O.; Gillespie, A.R. Classification of multispectral images based on fractions of endmembers: Application to land-cover change in the Brazilian Amazon. Remote Sens. Environ 1995, 52, 137–154.
[27]
Roberts, D.A.; Numata, I.; Holmes, K.; Batista, G.; Krug, T.; Monteiro, A.; Powell, B.; Chadwick, O.A. Large area mapping of land-cover change in Rond?nia using multitemporal spectral mixture analysis and decision tree classifiers. J. Geophys. Res.: Atmos 2002, 107, 8073.
[28]
Asner, G.P.; Bustamante, M.M.C.; Townsend, A.R. Scale dependence of biophysical structure in deforested areas bordering the Tapajo’s National Forest, Central Amazon. Remote Sens. Environ 2003, 87, 507–520.
[29]
Numata, I.; Soares, J.V.; Roberts, D.A.; Leonidas, F.C.; Chadwick, O.A.; Batista, G.T. Relationships among soil fertility dynamics and remotely sensed measures across pasture chronosequences in Rondonia, Brazil. Remote Sens. Environ 2003, 87, 446–455.
[30]
Souza, C.M., Jr.; Firestone, L.; Silva, L.M.; Roberts, D. Mapping forest degradation in the Eastern Amazon from SPOT 4 through spectral mixture models. Remote Sens. Environ 2003, 87, 494–506.
[31]
Small, C. The Landsat ETM+ spectral mixing space. Remote Sens. Environ 2004, 93, 1–17.
[32]
Asner, G.P.; Keller, M.; Pereira, R.; Zweede, J.C. Remote sensing of selective logging in Amazonia—Assessing limitations based on detailed field observations, Landsat ETM+, and textural analysis. Remote Sens. Environ 2002, 80, 483–496.
[33]
Boardman, J.W.; Kruse, F.A.; Green, R.O. Mapping Target Signatures via Partial Unmixing of AVIRIS Data. Proceedings of Annual JPL Airborne Geoscience Workshop, Pasadena, CA, USA, 23–26 January 1995; pp. 23–26.
[34]
Powell, R.L.; Matzke, N.; de Souza, C.; Clark, M.; Numata, I.; Hess, L.L.; Roberts, D.A.; Clark, M.; Numata, I.; Hess, L.L.; Roberts, D.A. Sources of error in accuracy assessment of thematic land-cover maps in the Brazilian Amazon. Remote Sens. Environ 2004, 90, 221–234.
[35]
Souza, C.M., Jr.; Cochrane, M.A.; Sales, M.H.; Monteiro, A.L.; Millicone, D. Integrating Forest Transects and Remote Sensing Data to Quantify Carbon Loss due to Forest Degradatin in the Brazilian Amazon. Forest Resource Assessment Working Paper 161;; FAO: Rome, Italy, 2009; pp. 1–17.
[36]
Asner, G.P. Cloud cover in Landsat observations of the Brazilian Amazon. Int. J. Remote Sens 2001, 22, 3855–3862.
[37]
FAO. On Definitions of Forest and Forest Change. In Food and Agriculture Administration, Forest Resource Assessment. Working Paper 33;; FAO: Rome, Italy, 2000; p. 13.
[38]
Puyravaud, J.P. Standardizing the calculation of the annual rate of deforestation. Forest Ecol. Manage 2003, 177, 593–596.
[39]
Cochrane, M.A.; Alencar, A.; Schulze, M.D.; Souza, C.M.; Nepstad, D.C.; Lefebvre, P.; Davidson, E.A. Positive feedbacks in the fire dynamic of closed canopy tropical forests. Science 1999, 284, 1832–1835.
[40]
Davidson, E.A.; de Araujo, A.C.; Artaxo, P.; Balch, J.K.; Brown, I.F.; C. Bustamante, M.M.; Coe, M.T.; DeFries, R.S.; Keller, M.; Longo, M.; et al. The Amazon basin in transition. Nature 2012, 481, 321–328.
[41]
Soares-Filho, B.S.; Nepstad, D.C.; Curran, L.M.; Cerqueira, G.C.; Garcia, R.A.; Ramos, C.A.; Voll, E.; McDonald, A.; Lefebvre, P.; Schlesinger, P. Modelling conservation in the Amazon basin. Nature 2006, 440, 520–523.
[42]
INPE. Prodes, Monitoramento da Floresta Amaz?nica por Satélite. Available online: http://www.obt.inpe.br/prodes/index.php (accessed on 6 May 2013).
[43]
Barlow, J.; Peres, C.A.; Henriques, L.M.P.; Stouffer, P.C.; Wunderle, J.M. The responses of understorey birds to forest fragmentation, logging and wildfires: An Amazonian synthesis. Biol. Conserv 2006, 128, 182–192.
[44]
Barlow, J.; Parry, L.; Gardner, T.A.; Ferreira, J.; Aragao, L.E.O.C.; Carmenta, R.; Berenguer, E.; Vieira, I.C.G.; Souza, C.; Cochrane, M.A. The critical importance of considering fire in REDD+ programs. Biol. Conserv 2012, 154, 1–8.
[45]
Barber, C.P.; Cochrane, M.A.; Souza, C.; Verissimo, A. Dynamic performance assessment of protected areas. Biol. Conserv 2012, 149, 6–14.
