Progress of researches on monitoring large-area forest disturbance by Landsat satellite images

doi:10.6046/gtzyyg.2014.02.02

Abstract
References
Related Articles
Metrics

Download: PDF(719 KB) HTML
Export: BibTeX | EndNote | Reference Manager | ProCite | RefWorks

Abstract The frequent forest disturbance caused by natural factors and human activities has very important effects on forest resources management, climate change and some other fields. Under the background of global warming, researches on forest disturbance monitoring and its corresponding influence have become one of the hot topics both in China and abroad. Based on a detailed analysis of the previous studies, this paper has reviewed the progress of monitoring methods for the large-area forest disturbance by using Landsat satellite imagery, which mainly include wall-to-wall mapping, sampling mapping and data fusion with the image of low spatial resolution. The advantages and disadvantages of these methods as well as the possible research prospects in the future are also discussed.

Keywords remote sensing city heat island effect “white roof plan” energy efficiency

S771.8

Issue Date: 28 March 2014

	Service

	E-mail this article
	E-mail Alert
	RSS
	Articles by authors

	XU Fei
	ZHANG Xuehong
	LI Dong
	FENG Xiaoyu

Cite this article:

XU Fei,ZHANG Xuehong,LI Dong, et al. Progress of researches on monitoring large-area forest disturbance by Landsat satellite images[J]. REMOTE SENSING FOR LAND & RESOURCES, 2014, 26(2): 5-10.

URL:

https://www.gtzyyg.com/EN/10.6046/gtzyyg.2014.02.02 OR https://www.gtzyyg.com/EN/Y2014/V26/I2/5

[1] 吴雪琼,覃先林,周汝良,等.森林覆盖变化遥感监测方法研究进展[J].林业资源管理,2010(4):82-87. Wu X Q,Qin X L,Zhou R L,et al.Progress of study on forest cover change detection by using remote sensing technique[J].Forest Resources Management,2010(4):82-87.
[2] Dale V H,Joyce L A,Mcnulty S,et al.Climate change and forest disturbances[J].Bioscience,2001,51(9):723-734.
[3] Houghton R A.The annual net flux of carbon to the atmosphere from changes in land use 1850—1990[J].Tellus Series B-Chemical and Physical Meteorology,1999,51(2):298-313.
[4] Avissar R,Werth D.Global hydroclimatological teleconnections resulting from tropical deforestation[J].Journal of Hydrometeorology,2005,6(2):134-145.
[5] Broich M,Stehman S V,Hansen M C,et al.A comparison of sampling designs for estimating deforestation from Landsat imagery:A case study of the Brazilian Legal Amazon[J].Remote Sensing of Environment,2009,113(11):2448-2454.
[6] Curran L M,Trigg S N.Sustainability science from space:Quantifying forest disturbance and land-use dynamics in the Amazon[J].Proceedings of the National Academy of Sciences of the United States of America,2006,103(34):12663-12664.
[7] FAO.State of the world's forests[R].Rome,2005.
[8] 李世明,王志慧,韩学文,等.森林资源变化遥感监测技术研究进展[J].北京林业大学学报,2011,33(3):132-138. Li S M,Wang Z H,Han X W,et al.Overview of forest resources change detection methods using remote sensing techniques[J].Journal of Beijing Forestry University,2011,33(3):132-138.
[9] 赵宪文,李崇贵,斯林.基于信息技术的森林资源调查新体系[J].北京林业大学学报,2002,24(5):147-155. Zhao X W,Li C G,Si L.Building a new system of forest resources inventory by information technology[J].Journal of Beijing Forestry University,2002,24(5):147-155.
[10] Hansen M C,DeFries R S,Townshend J R G,et al.Towards an operational MODIS continuous field of percent tree cover algorithm:Examples using AVHRR and MODIS data[J].Remote Sensing of Environment,2002,83(1/2),303-319.
[11] Hansen M C,DeFries R S,Townshend J R G,et al.Global percent tree cover at a spatial resolution of 500 meters:First results of the MODIS vegetation continuous fields algorithm[J].Earth Interactions,2003,7(10):1-15.
[12] Jin S,Sader S A.MODIS time-series imagery for forest disturbance detection and quantification of patch size effects[J].Remote Sensing of Environment,2005,99(4):462-470.
[13] Hansen M C,Stehman S V,Potapov P V,et al.Humid tropical forest clearing from 2000 to 2005 quantified by using multitemporal and multiresolution remotely sensed data[J].Proceedings of the National Academy of Sciences,2008,105(27):9439-9444.
[14] Morton D C,DeFries R S,Shimabukuro Y E,et al.Rapid assessment of annual deforestation in the Brazilian Amazon using MODIS data[J].Earth Interactions,2005,9(8):1-22.
[15] Czaplewski R L.Can a sample of Landsat sensor scenes reliably estimate the global extent of tropical deforestation?[J].International Journal of Remote Sensing,2003,24(6):1409-1412.
[16] Duveiller G,Defourny P,Desclee B,et al.Deforestation in central Africa:Estimates at regional,national and landscape levels by advanced processing of systematically-distributed Landsat extracts[J].Remote Sensing of Environment,2008,112(5):1969-1981.
[17] Huang C Q,Kim S,Song K,et al.Assessment of Paraguay's forest cover change using Landsat observations[J].Global and Planetary Change,2009,67:1-12.
[18] Skole D,Tucker C.Tropical deforestation and habitat fragmentation in the Amazon:Satellite data from 1978 to 1988[J].Science,1993,260,1905-1910.
[19] INPE.Monitoramento da Floresta Amazônica Brasileira por Satélite. Projeto PRODES[EB/OL].http://www.obt.inpe.br/prodes/,2001.
[20] Guild L,Cohen W,Kauffman J.Detection of deforestation and land conversion in Rondonia,Brazil using change detection techniques[J].International Journal of Remote Sensing,2004,25(4):731-750.
[21] Townshend J R G,Bell V,Desch A C,et al.The NASA Landsat pathnder humid tropical deforestation project,land satellite information in the next decade[C]//Tyson's Corner,Virginia:American Society Of Photogrammetry and Remote Sensing,1995,IV76-IV87.
[22] Sánchez-Azofeifa G A,Harriss R C,Skole D L.Deforestation in Costa Rica:A quantitative analysis using remote sensing imagery[J].Biotropica,2001,33(3):378-384.
[23] Forest Survey of India.State of forest report 2003[R].Dehra Dun,India:Ministry of Environment and Forest,2004.
[24] Hansen M C,Roy D,Lindquist E,et al.A method for integrating MODIS and Landsat data for systematic monitoring of forest cover and change in the Congo Basin[J].Remote Sensing of Environment,2008,112(5):2495-2513.
[25] Shimabukuro Y E,Batista G T,Mello E M K,et al.Using shade fraction image segmentation to evaluate deforestation in Landsat Thematic Mapper images of the Amazon Region[J].International Journal of Remote Sensing,1998,19(3):535-541.
[26] FAO.Tropical resources assessment 1990[R].FAO Forestry Paper 112,Food and Agricultural Organization of the United Nations,Rome,1993.
[27] FAO.Forest resources assessment 1990:Survey of tropical forest cover and study of change processes[R].FAO Forestry Paper 130,Food and Agricultural Organization of the United Nations,Rome,1996.
[28] Tejaswi G.Manual on deforestation,degradation,and fragmentation using remote sensing and GIS[R].MAR-SFM working paper,Rome,2007.
[29] Tucker C J,Townshend J R G.Strategies for monitoring tropical deforestation using satellite data[J].International Journal of Remote Sensing,2000,21(6-7):1461-1471.
[30] Hansen M C,Shimabukuro Y E,Potapov P,et al.Comparing annual MODIS and PRODES forest cover change data for advancing monitoring of Brazilian forest cover[J].Remote Sensing of Environment,2008,112:3784-3793.
[31] Goward S N,Masek J G,Cohen W B,et al.Forest disturbance and North American carbon flux[J].Earth Observing System Transactions,2008,89(11):105-116.
[32] Skole D,Chomentowski W H,Salas W A,et al.Physical and human dimensions of deforestation in Amazonia[J].Bioscience,1994,44(5):314-321.
[33] Stone T A,Schlesinger P,Houghton R A,et al.A map of the vegetation of South America based upon satellite imagery[J].Photogrammetric Engineering and Remote Sensing,1994,60(5):541-551.
[34] FAO.Global forest resources assessment 2000:Main report[R].Forestry Paper No140,Food and Agriculture Organization of the United Nations,Rome,2001.
[35] Achard F,Eva H D,Stibig H J,et al.Determination of deforestation rates of the world's humid tropical forests[J].Science,2002,297(5583):999-1002.
[36] McRoberts R E,Wendt D G,Nelson M D,et al.Using a land cover classification based on satellite imagery to improve the precision of forest inventory area estimates[J].Remote Sensing of Environment,2002,81:36-44.
[37] McRoberts R E,Holden G R,Nelson M D,et al.Using satellite imagery as ancillary data for increasing the precision of estimates for the forest inventory and analysis program of the USDA forest service[J].Canadian Journal of Forest Research,2005,35(12):2968-2980.
[38] Stehman S V,Sohl T L,Loveland T R.An evaluation of sampling strategies to improve precision of estimates of gross change in land use and land cover[J].International Journal of Remote Sensing,2005,26:4941-4957.
[39] Richards T,Gallego J,Achard F.Sampling for forest cover change assessment at the pan-tropical scale[J].International Journal of Remote Sensing,2000,21(6/7):1473-1490.
[40] Baumann M,Ozdogan M,Kuemmerle T,et al.Using the Landsat record to detect forest-cover changes during and after the collapse of the Soviet Union in the temperate zone of European Russia[J].Remote Sensing of Environment,2012,124:174-184.
[41] Sanchez-Azofeifa G,Skole D L,Chomentowski W.Sampling global deforestation databases:The role of persistence[J].Mitigation and Adaptation Strategies for Global Change,1997,2(2/3):177-189.
[42] Gallego F J.Stratified sampling of satellite images with a systematic grid of points[J].ISPRS Journal of Photogrammetry and Remote Sensing,2005,59(6):369-376.
[43] Mayaux P,Holmgren P,Achard F,et al.Tropical forest cover change in the 1990s and options for future monitoring[J].Philosophical Transactions of the Royal Society B,2005,360(1454):373-384.
[44] Tomppo E,Czaplewski R L,Mkisara K.The role of remote sensing in global forest assessment [R].Forest Resources Assessment Working Paper 61 Rome:Food and Agriculture Organization of the United Nations.ftp://ftp.fao.org/docrep/fao/006/ad650e/ad650e00.pdf,2002.
[45] Dunn R,Harrison A R.Two dimensional systematic sampling of land use[J].Applied Statistics,1993,42(4):585-601.
[46] Ridder R M.Global forest resource assessment 2010[R].Options and Recommendations for a Global Remote Sensing Survey of Forests.Forest Resources Assessment Programme.Working Paper 141.Rome,2007.
[47] Gao F,Masek J,Schwaller M,Hall F,et al.On the blending of the Landsat and MODIS surface reflectance:Predicting daily Landsat surface reflectance[J].IEEE Transactions on Geoscience and Remote Sensing,2006,44(8):2207-2218.
[48] Ranson K J,Kovacs K,Sun G,et al.Disturbance recognition in the boreal forest using radar and Landsat-7[J].Canadian Journal of Remote Sensing,2003,29(2):271-285.
[49] Leckie D.Advances in remote sensing technologies for forest survey and management[J].Canadian Journal of Forest Research,1990,20(4):464-483.
[50] Arai E,Shimabukuro Y E,Pereira G,et al.A multi-resolution multi-temporal technique for detecting and mapping deforestation in the Brazilian Amazon Rainforest[J].Remote Sensing,2011,3(12):1943-1956.
[51] Zhu Z,Evans D L.US forest types and predicted percent forest cover from AVHRR data[J].Photogrammetric Engineering and Remote Sensing,1994,60(5):525-531.
[52] Fazakas Z,Nilsson M.Volume and forest cover estimation over southern Sweden using AVHRR data calibrated with TM data[J].International Journal of Remote Sensing,1996,17(9):1701-1709.
[53] Hayes D J,Cohen W B.Spatial,spectral and temporal patterns of tropical forest cover change as observed with multiple scales of optical satellite data[J].Remote Sensing of Environment,2007,106(1):1-16.

[1]	LIU Wen, WANG Meng, SONG Ban, YU Tianbin, HUANG Xichao, JIANG Yu, SUN Yujiang. Surveys and chain structure study of potential hazards of ice avalanches based on optical remote sensing technology: A case study of southeast Tibet[J]. Remote Sensing for Natural Resources, 2022, 34(1): 265-276.
[2]	WANG Qian, REN Guangli. Application of hyperspectral remote sensing data-based anomaly extraction in copper-gold prospecting in the Solake area in the Altyn metallogenic belt, Xinjiang[J]. Remote Sensing for Natural Resources, 2022, 34(1): 277-285.
[3]	LYU Pin, XIONG Liyuan, XU Zhengqiang, ZHOU Xuecheng. FME-based method for attribute consistency checking of vector data of mines obtained from remote sensing monitoring[J]. Remote Sensing for Natural Resources, 2022, 34(1): 293-298.
[4]	ZHANG Daming, ZHANG Xueyong, LI Lu, LIU Huayong. Remote sensing image segmentation based on Parzen window density estimation of super-pixels[J]. Remote Sensing for Natural Resources, 2022, 34(1): 53-60.
[5]	XUE Bai, WANG Yizhe, LIU Shuhan, YUE Mingyu, WANG Yiying, ZHAO Shihu. Change detection of high-resolution remote sensing images based on Siamese network[J]. Remote Sensing for Natural Resources, 2022, 34(1): 61-66.
[6]	SONG Renbo, ZHU Yuxin, GUO Renjie, ZHAO Pengfei, ZHAO Kexin, ZHU Jie, CHEN Ying. A method for 3D modeling of urban buildings based on multi-source data integration[J]. Remote Sensing for Natural Resources, 2022, 34(1): 93-105.
[7]	LI Weiguang, HOU Meiting. A review of reconstruction methods for remote-sensing-based time series data of vegetation and some examples[J]. Remote Sensing for Natural Resources, 2022, 34(1): 1-9.
[8]	DING Bo, LI Wei, HU Ke. Inversion of total suspended matter concentration in Maowei Sea and its estuary, Southwest China using contemporaneous optical data and GF SAR data[J]. Remote Sensing for Natural Resources, 2022, 34(1): 10-17.
[9]	GAO Qi, WANG Yuzhen, FENG Chunhui, MA Ziqiang, LIU Weiyang, PENG Jie, JI Yanzhen. Remote sensing inversion of desert soil moisture based on improved spectral indices[J]. Remote Sensing for Natural Resources, 2022, 34(1): 142-150.
[10]	ZHANG Qinrui, ZHAO Liangjun, LIN Guojun, WAN Honglin. Ecological environment assessment of three-river confluence in Yibin City using improved remote sensing ecological index[J]. Remote Sensing for Natural Resources, 2022, 34(1): 230-237.
[11]	HE Peng, TONG Liqiang, GUO Zhaocheng, TU Jienan, WANG Genhou. A study on hidden risks of glacial lake outburst floods based on relief amplitude: A case study of eastern Shishapangma[J]. Remote Sensing for Natural Resources, 2022, 34(1): 257-264.
[12]	AI Lu, SUN Shuyi, LI Shuguang, MA Hongzhang. Research progress on the cooperative inversion of soil moisture using optical and SAR remote sensing[J]. Remote Sensing for Natural Resources, 2021, 33(4): 10-18.
[13]	LI Teya, SONG Yan, YU Xinli, ZHOU Yuanxiu. Monthly production estimation model for steel companies based on inversion of satellite thermal infrared temperature[J]. Remote Sensing for Natural Resources, 2021, 33(4): 121-129.
[14]	LIU Bailu, GUAN Lei. An improved method for thermal stress detection of coral bleaching in the South China Sea[J]. Remote Sensing for Natural Resources, 2021, 33(4): 136-142.
[15]	WU Fang, JIN Dingjian, ZHANG Zonggui, JI Xinyang, LI Tianqi, GAO Yu. A preliminary study on land-sea integrated topographic surveying based on CZMIL bathymetric technique[J]. Remote Sensing for Natural Resources, 2021, 33(4): 173-180.

Viewed

Full text

Abstract

Cited

Shared

Discussed