Post on 09-Jul-2020
Overview on Land Cover and Land Use
Monitoring in Russia
Russian Academy of Sciences
Space Research Institute
Sergey Bartalev
Joint NASA LCLUC Science Team Meeting and GOFC-GOLD/NERIN, NEESPI Workshop
Monitoring land cover and land use in boreal and temperate Europe
August 25-28, 2010, Tartu, Estonia
Russian Academy of Sciences’ activity related to LCLU satellite monitoring
– land cover mapping using MODIS data and LAGMA
method;
– agricultural monitoring with focus on arable land and
crops mapping;
– burnt area mapping and severity assessment using
MODIS and high-resolution optical data;
– TerraNorte Information System
Some features of R&D at IKI
Focus is on national (entire Russia) and sub-continental (Northern Eurasia) monitoring
Primary sources of EO data are moderate resolution satellite instruments (mainly MODIS and SPOT-VGT), while the role of high-res. (e.g. Landsat-TM, SPOT-HRV/HRVIR, RapidEye) data for national monitoring is rapidly increasing
Focus on long-term time-series data analysis for land cover mapping and monitoring
Development of automatic satellite data processing chains to perform monitoring in the routine and repeatable manner
OTHER VEGETATION TYPES AND COMPLEXES
TUNDRA
WETLANDSFORESTS
SHRUBLANDS
GRASSLANDS
NON-VEGETATED LAND
COVER TYPES
GLC2000 legend for Northern Eurasia
Main features of GLC2000 Northern
Eurasia land cover map1-km resolution SPOT-Vegetation data for year 2000
Mapping method involves:
i. set of advanced spectral-temporal and spectral-angular indexes to distinguish various land cover types
ii. clustering and significant human input for labelling and decomposing of ambiguous semantic clusters
Advantages:
– large number of mapped land cover types
– high level mapping accuracy
Disadvantages:
– limited repeatability
Towards better land cover mapping:
main directions of consideration
- spatial resolution of mapping according to satellite
sensors ability (1 km => 250 m)
- mapping accuracy
- mapping repeatability (annual as the target)
- possibility to modify mapping legend (e.g. to increase
number of thematic classes)
Cloud-free summer MODIS composite
Cloud-free winter MODIS composite
Classification based on LAGMA method
Satellite
data
Training
samples
Training samples
spatial regularization
(gridding)
Classes’
signatures for
cell-grid nodes
Contextual Maximum
Likelihood classification
New land
cover map
TerraNorte RLC mapping method
GLC 2000 Forest map
Auxiliary thematic products
Peatlands map
Spectral mixture
modeling
Expert
evaluation and
correction
Thematic source data
Training data preparation
Histogram
filtration
GIS
analysis
Manual
selection
GIS analysis
Burnt area Croplands Water mask Urban mask
Contextual Maximum Likelihood Classification
Local spectral-temporal signatures of classes Spectral-temporal MODIS data composites
Maximum likelihood classifier
Covariation of
metrics
Average of
metrics
Number of
samples
Metrics for the pixel
Probabilities for classes
The land cover map for Russia based on MODIS 250 m
TerraNorte RLC Map for 2005
The Legend of TerraNorte RLC Map
Boschetti et al. Analysis of the conflict between omission and commission in low spatial resolution dichotomic thematic products: The Pareto Boundary // Remote Sensing of Environment 91 (2004) 280–292
The Pareto Boundary method to estimate accuracy of the land cover map
Pareto optimum: for 250 m resolution
for 1000 m resolution
Site 2: Komi RepublicSite 1: Karelia Republic
1
2
TerraNorte RLC accuracy assessment for two test sites
PVI time-series analysis
0
0,1
0,2
0,3
0,4
2002 2003 2004 2005 2006 2007
PVI
arable lands
natural vegetation
NIR
RED
Soil line
PVI
A
PVI= - 0.83*RED+0.56*NIR-0.005
PVI=Distance (A, Soil line)
Inter-annual PVI dynamic similarity analysis and multi-annual phenological features retrieval
The features for arable lands mapping with MODIS multi-annual data time-series
Features Description Formula Feature Image Histograms
Index of shortest vegetation period
1/ 21..
( )j j
L Fj N
L min t t,
( ) ( )2
maxL F
PVIPVI t PVI t ,
,L max F maxt t t t
Index of vegetation spring development 1..
ijj N
i spw
MSI min PVI
Index of seasonal biomass decrease
min
1
1
Nsw
j
j
N
i
j i sw
PVI
NSMI const
PVI
Arable lands map based on MODIS
MODIS derived arable lands map vs. HR imagery based fields’ limits
Crop types classification using MODIS
0
0,05
0,1
0,15
0,2
0,25
0,3
0,35
17-Apr 7-May 27-May 16-Jun 6-Jul 26-Jul 15-Aug 4-Sep 24-Sep
PVI
Peas
Melilot
Potato
Alfalfa
Perennials
Spring crops
Fallow
Rape
Winter rye
Barley+Peas mixture
Ground-truthOmission
(%)1 2 3 4 5 6 7 8 9 10
Classificatio
n
1 58 0 0 0 0 11 0 0 0 0 5,9
2 0 127 0 0 3 34 0 0 3 1 24,4
3 0 0 101 0 0 10 7 1 0 0 15,1
4 0 0 0 26 0 0 0 0 0 0 0,0
5 0 0 1 1 797 116 17 8 1 0 15,3
6 2 3 3 0 2 5822 9 6 4 4 0,6
7 0 1 7 0 2 49 574 4 0 0 9,9
8 0 0 0 0 0 127 0 175 1 0 42,2
9 0 0 0 0 0 14 7 0 72 0 22,6
10 0 0 0 0 0 42 0 0 0 46 47,7
Commission (%)
3,3 3,1 9,8 3,7 0,9 6,5 4,5 9,8 11,1 9,8 93
Burnt area mapping using MODIS
Detection of SWVI statistical anomalies
Thermal anomaliesBurnt area maps
Combined SWVI and thermal anomalies
SWVI time-series
Multi-annual MODIS data
-100
0
100
200
300
400
500
30 60 90 120 150 180 210 240 270 300
day
SW
VI (x
10
00
)
mean mean-2*sdev mean+2*sdev current year
fire
Contaminated pixels detection
SWVI time-series restoration
Burnt area for year 2009
Fires in Central European Russia in 2010
The considered period:
July 1 – August 21, 2010
The fires have been
mapped using MODIS data
and MOD14 thermal
anomalies detection
algorithm implemented
within the Satellite
Monitoring Information
System of Russian Forest
Service
Ground-truth collection using HR data samples Burns severity assessment using MODIS data
Forest burns severity assessment
Field measurements HR Satellite images Burns severity assessment
Land cover
Data analysis
Statistical relationships
Burn severity assessment
Burns severity by forest types
Lost forest areaassessment
Burnt area mapping
-0,5 0,0 0,5 1,0 1,5 2,0 2,5 3,0 3,5 4,0 4,5 5,00
20
40
60
80
100
120
140
160
180
Чи
сл
о н
аб
л.
Усыхающие насаждения
10 20 30 40 50 60 70 80 90 100
Степень повреждения по данным MODIS
0
2
4
6
8
10
12
Число н
абл.
Statistics on forest mortality
Landsat-TM 07.09.2009; RGB:NIR-SWIR-Red
Burns limits from MODIS
Forestry districts
< 10%
11-40%
41 - 80%
>80%
Trees mortality
Post-fire assessment of trees mortality
Response of forests to drought 2010
Vyksunskyy administrative district
Semenovskyy administrative district
25.07.2010
07.08.2010
TerraNorte: Data Products on-line
http://terranorte.iki.rssi.ru/