COMPARISON OF MODEL ACCURACY IN TREE CANOPY DENSITY ESTIMATION USING SINGLE BAND, VEGETATION INDICES AND FOREST CANOPY DENSITY (FCD) BASED ON LANDSAT-8 IMAGERY (CASE STUDY: PEAT SWAMP FOREST IN RIAU PROVINCE)
Abstract
Identification of a tree canopy density information may use remote sensing data such as Landsat-8 imagery. Remote sensing technology such as digital image processing methods could be used to estimate the tree canopy density. The purpose of this research was to compare the results of accuracy of each method for estimating the tree canopy density and determine the best method for mapping the tree canopy density at the site of research. The methods used in the estimation of the tree canopy density are Single band (green, red, and near-infrared band), vegetation indices (NDVI, SAVI, and MSARVI), and Forest Canopy Density (FCD) model. The test results showed that the accuracy of each method: green 73.66%, red 75.63%, near-infrared 75.26%, NDVI 79.42%, SAVI 82.01%, MSARVI 82.65%, and FCD model 81.27%. Comparison of the accuracy results from the seventh methods indicated that MSARVI is the best method to estimate tree canopy density based on Landsat-8 at the site of research. Estimation tree canopy density with MSARVI method showed that the canopy density at the site of research predominantly 60-70% which spread evenly.
Keywords
Full Text:
PDFReferences
APOEC.org, (2003), Forest Structure, downloaded April 14, 2016 from: http://www.apoec.org.nz/docs/
Ayat S., Tarigan J., (2010), Forest village of Lubuk Beringin: Scenario Conservation of Bungo Regency. Kiprah Agroforestri 6, 3:2, page. 3-5
Campbell JB, Wynne RH, (2011), Introduction to Remote Sensing. New York: Guilford Press.
Forest Watch Indonesia, (2014), Profile of Indonesia's Forests in 2009-2013 Period. FWI.
Jensen JR, (2007), Remote Sensing of the Environment: An Earth Resource Perspective. 2nd Edition, Pearson Prentice Hall, Upper Saddle River.
Lillesand TM, Kiefer RW, Chipman J., (2014), Remote Sensing and Image Interpretation. 7th Edition. USA: John Wiley & Sons, Inc.
Lund HG, (2002), Definitions of old growth, pristine, climax, ancient forests, and similar terms. [Online publication], Manassas, VA: Forest Information Services. Misc. Pagination, downloaded January 20, 2016 from http://home.att.net/~gklund/pristine.html
MAB Indonesia, (2016a), Cagar Biosfer Giam Siak, diunduh 14 April 2016 dari http://www.mab-indonesia.org/cagar.php?i=giam
MAB Indonesia, (2016b), Peta Area Cagar Biosfer, downloaded April 14 , 2016 from http://www.mab-indonesia.org/cagar.php
Matthews JA, (2013), Encyclopedia of Environmental Change. United Kingdom: Sage Publications.
Myeong S., Nowak DJ, Duggin MJ, (2006), A temporal analysis of urban forest carbon storage using remote sensing Remote Sens. Environ. 101 277–82
Panta M., (2003), Analysis of Forest Canopy Density and Factors Affecting It Using RS and GIS Techniques. Unpublished M.sc. Thesis, ITC, Netherland.
Republic of Indonesia, (1999), Law of the Republic of Indonesia No.41 of 1999 on Forestry.
Tempo.co, (2015a), Police Shoot Squadron Giam Siak Kecil Biosphere Reserve Bukit Batu, downloaded April 13, 2016 from: https://m.tempo.co/read/news/2015/06/14/058674941/polisi-tembak-perambah-cagar-biosfer-giam-siak-kecil
Tempo.co, (2015b), Forest Fires in Riau Threatens Biosphere Reserve of Giam Siak Kecil, downloaded April 13 , 2016 from: https://m.tempo.co/read/ news/2015/10/22/206711908/kebakaran-hutan-di-riau-ancam-cagar-biosfer-giam-siak
Tohir NR, Prasetyo LB, Kartono AP, (2014), Mapping of Canopy Density Changes in the People's Forest of Kuningan Regency of West Java. National Seminar on Remote Sensing: Detection of Geobiophysical Parameters and Remote Sensing Dissemination.
Wibowo A., Gintings A., (2010), Degradation and Forest Conservation Efforts. Reversing the Degradation Trends of Land and Water Resources. P. 67-87.
Refbacks
- There are currently no refbacks.