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APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Classification Accuracy for RISAT-1 Hybrid Polarimetric Data
Varsha Turkar1, Shaunak De1, G. G. Ponnurangam1, Rinki Deo1, Y.S. Rao1 and Anup Das2
1 CSRE, Indian Institute of Technology Bombay2 Space Application Center, ISRO
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Introduction• Studies on compact and hybrid polarimetric SAR data is
currently in focus.• Primary reasons: [1]
• Wider swath than Full-Pol mode• Low PRF requirement – less demanding on hardware• Higher incidence angle range coverage
• Studies demonstrated with compact-pol: [2]
• Crop classification• Soil moisture estimation• Ship detection and sea-ice classification
[1] R.K. Raney, “Hybrid-polarity SAR architecture”, IEEE Trans. Geosci. Remote Sens., 45(11): 3397 –3404, Nov. 2007[2] F.J. Charbonneau, B. Brisco, R.K. Raney, H. McNarin, P.W.Vachon, J.Shang, R. DeAbreu, C. Champagne, A. Merzouki and Geldsetzer, “Compact polarimetry overview and application assessment”, Can. J. Remote Sens., vol. 36, 2, pp. s298-s315, 2010.
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
RISAT-1 – The first compact pol SAR
• The work carried out so far has been based on simulated hybrid-pol data
• RISAT-1 – first spaceborne hybrid PolSAR system• Indigenously developed • C-band (5.35 GHz) hybrid polarimetric
SAR• Multi-polarisation and multi-resolution • 50m – 1m spatial resolution• RH/RV, HH/HV modes supported
• Right circular transmit and coherent linear receive mode (CTLR)
Courtesy: ISRO
Backscatter ( 0 ) Calculation
• SLC data is supplied as 16 bit integers
• Converted to complex floating point
• Radiometric correction of data• The calibration constant (KdB) is
supplied
Here:
RH 0 (db) - Mumbai
Export to C2 Matrix
𝐶=[ ⟨𝐸𝑅𝐻𝐸𝑅𝐻∗ ⟩ ⟨𝐸𝑅𝐻𝐸𝑅𝑉
∗ ⟩⟨𝐸𝑅𝑉 𝐸𝑅𝐻
∗ ⟩ ⟨𝐸𝑅𝑉 𝐸𝑅𝑉∗ ⟩ ]
• Two channel data – i.e. RH and RV
• Supplied as SLC data(complex) 16 bit integer values
• After conversion to float C2 is calculated:
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Classification Methods
• Wishart supervised classifier• Compute the mean covariance matrix (C2) over the training areas
This is the mean covariance matrix for class .
• The complex Wishart distrubution is given by:
• The distance dm is computed for each pixel, for each class
• The pixel is assigned to the class with the minimum distance
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Classification Methods
• SVM (Support Vector Machine)• It is based on search of optimal hyperplane which can separate the classes.
• The SVM makes the use of non-linear function which transforms the data from input space to higher dimension feature space so that the data can be linearly separable.
• Various kernels may be used:• Linear• RBF• Polynomial
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Objectives of Study
• Backscattering coefficient ( 0σ ) for discrimination of various land features using both linear and hybrid polarimetric RISAT-1 data
• Compared classification accuracy using RADARSAT-2 simulated hybrid and RISAT-1 compact pol data
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Study Area: Mumbai, India.
Scene CenterLongitude:72.930005Latitude :19.220882
RISAT-1RH/RV – FRS
15th Nov 2012
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Study Area: Mumbai, India.
RISAT-1RH/RV – FRS
15th Nov 2012
Test site chosen is the metropolis of Mumbai, India.
The area consists of:• Built-up dense urban settlements• Moderately dense deciduous forest• Mangroves• Wetlands• Bare soil • Water• Grasslands
Urban AreasCourtesy:
indianexpress.com
Forest Mangroves
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Study Area: Mumbai, India.
RISAT-1RH/RV – FRS
15th Nov 2012
Wetland / Saltpan
Bareland Water
Grassland
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Data sets and Field data collection
RISAT-1 data has been acquired on two successive days over Mumbai.
Satellite Mode Date of Acquisition Incidence angle
RISAT-1 HH/HV 14th Nov 2012 49.3
RH/RV 15th Nov 2012 35.9
RADARSAT-2 Full Pol. 16th Feb 2011 41.73
Ground-truth parameters in terms of soil moisture, vegetation height and biomass, etc. were collected synchronous with the satellite passes.
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
RISAT-1BACKSCATTER ANALYSISComparison between RH/RV and HH/HV backscatter
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
MethodologyRISAT-1 Data
• cFRS-1 [RH/RV]• FRS-1 [HH/HV]
Pre-processing• Data extraction
• Calibration
Multilook • 3:3 in Range: Azimuth
Compute statistics for 6 test areas
Plot Backscattering Coefficient
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
RISAT-1 0 B Analysisԁ
Class HV HH RV RH
Grass-land -12.48 -4.13 -7.47 -3.35
Bare-land -14.67 -5.88 -10.56 -6.47
Water -17.62 -11.53 -15.12 -11.64
Mangroves -11.30 -3.28 -6.37 -2.79
Forest -12.76 -4.20 -7.18 -4.27
Urban -13.15 -1.87 -5.87 -0.28
Wetland -16.99 -10.57 -10.69 -9.54
AVERAGE 0 ԁB VALUES FOR LINEAR AND HYBRID MODE DATA
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
RISAT-1 0 B Analysis (Cont.)ԁ
Mean and standard deviation of σ0 dB of RISAT-1 linear and hybrid mode data for various classes.
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
RISAT-1 0 B Analysis (Cont.)ԁ
• There is a clear separation of mean 0 values of various classes
• Yet, we can not classify data on backscatter alone• Standard deviation of features is high• Overlaps with mean values of other features• Example: forest and mangrove class overlap
• The standard deviation from mean is consistent in all classes• Value ranging from 2.18 in water to 2.73 in the forest class• Exception: urban class - higher standard deviation of 4.32
• There is a 13.4o difference in the incidence angle between the RH/RV and HH/HV datasets from RISAT-1 : This may be the reason for the difference in mean σ0
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
RISAT-1 & RADARSAT-2CLASSIFICATIONComparison between hybrid and simulated hybrid data
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Datasets
m-chi decomposed image for RISAT-1 - Mumbai city
RADARSAT-2 Mumbai area -Zyl decomposition
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Hybrid Polarimetric Decompositions
m-δ m-χ m-
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
MethodologyImport and Prepare Data• RISAT-1
(HybridPol)• RADARSAT-2
(Full Pol)
Multilook to reduce speckle• 3:3 Multilook
5x5 Refined Lee Filter
Co-Register Datasets
Wishart Classification• Intensity • Complex
Decomposition• m-• m-• CPR
Classification and Analysis• SVM• Wishart
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Combining CPR, SPAN and m-δ / m-
CPR SPAN
m-δ / m-
VolumeDoubleBounce
Surface
SVM
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Combining CPR, SPAN and m-δ / m-
Histogram of CPR for test areas
• The CPR, SPAN and individual components of the m-δ / m- decompositions (Vol, Dbl, Surface) are normalized and used as input bands to the SVM classifier.
• CPR helps discriminate between mangroves and forest areas (see histogram)
• SPAN helps discriminate urban areas from background.
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Classification Results – Test Area
Class
RISAT-1 Hybrid PolRISAT-1 Dual Pol
RADARSAT-2 Simulated Hybrid Pol
Wishartm-,
CPR,SPAN (SVM)
m-χ, CPR,SPAN
(SVM)Wishart Wishart
m-,CPR-SPAN (SVM)
m-χ, CPR,SPAN
(SVM)
Water % 100.00 100.00 100.00 65.15 100.00 100.00 100.00
Mangroves %
73.87 76.78 77.41 37.21 67.84 60.29 56.96
Urban % 78.64 91.56 97.85 69.95 75.25 71.03 73.43
Forest % 86.52 99.34 99.57 82.74 45.58 45.01 41.23
Wetland % 91.57 94.45 94.77 48.67 98.83 97.97 98.93
Grassland % 78.16 84.66 85.44 32.46 45.00 57.09 60.96
Overall User Acc. %
84.67 91.61 92.84 58.57 68.45 68.17 67.69
Classification accuracy for various land covers using test areas
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Results and Analysis• Wishart supervised classifier:
• RISAT-1 – (RH/RV) • 80.62% for training areas • 84.67% for test areas.
• RADARSAT-2 (Simulated RH/RV)• 72.83% for training areas • 68.45% for test areas
• The classification accuracy increases by 7% after combining the three components of m-χ or m-δ with the CPR and SPAN [3] for RISAT-1.
• RISAT-1 hybrid polarimetric data performs better than RADARSAT-2 simulated hybrid polarimetric data for all three combinations.
• The lowest classification accuracy of 32.46% for the grassland class is due to its confusion with forest class.
[3] V. Turkar, Shaunak De, Y. S. Rao, A. Bhattacharya and A. Das, “Comparative Analysis Of classification Accuracy For RISAT-1 Hybrid Pol. Data”, Proc. IEEE IGARSS 2013, Melbourne.
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Classified Images of RISAT-1
Classified image of RISAT-1 C-band Hybrid polarimetrc Mumbai data (a) Wishart supervised (b)SVM classified (m-χ + CPR + SPAN)
Wishart Supervised SVM (m-χ + CPR + SPAN)
Legend
Water
Mangroves
Forest
Urban
Wetland
Grassland
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
SVM Classified Images (m- + χ CPR + SPAN)
SVM (m-χ + CPR + SPAN) classified image of (a) RISAT-1 hybrid and (b) RADARSAT-2 simulated hybrid mode data.
Legend
Water
Mangroves
Forest
Urban
Wetland
Grassland
RISAT-1 RADARSAT-2
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
EFFECT OF TRAINING AREA SELECTIONComparison of classification RISAT-1 (RH/RV)
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Classification – with different training areas
Classification accuracy for various land covers using test areas
Class
RISAT-1 Hybrid PolLarge Training Area
RISAT-1 Hybrid PolSmall Training Area
Wishart Wishart
Water % 100.00 100.00
Mangroves % 73.87 84.67
Urban % 78.64 91.66
Forest % 86.52 76.47
Wetland % 91.57 93.16
Grassland % 78.16 88.79
Overall User Acc. % 84.67 89.12
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Classified Image - RISAT-1 (RH/RV)
Water Mangrove Urban Forest Wetland Grassland
Producer's
Accuracy
Water 100 0 0 0 0 0 100
Mangrove 0 79.81 7.93 12.26 0 0 79.81
Urban 0 5.32 94.19 0.3 0.07 0.12 94.19
Forest 0 9.13 0.63 84.17 0.29 5.78 84.17
Wetland 0 0 0 0 95.8 4.2 95.80
Grassland 0 0 0 13.33 6.67 80.00 80.00
User Accuracy 100 84.67 91.66 76.47 93.16 88.79 89.12
Homogeneous Training Areas
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Confusion Matrix –Small training areas
RISAT-1 RH/RV Wishart
Class Urban Forest Mangroves Water Wetland
Urban 97.95 0.34 0.73 0 0
Forest 0.28 88.33 11.2 0 1.59
Mangroves 1.78 9.9 88.06 0 0
Water 0 0 0 100 1.59
Wetland 0 1.43 0 0 96.81
Overall Accuracy: 94.23
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Confusion Matrix –Large training areas
RISAT-1 RH/RV Wishart
Class Urban Forest Mangroves Water Wetland
Urban 85.97 0 0 0.63 13.4
Forest 0 92.59 0.71 6.7 0
Mangroves 0 13.42 85.58 1 0
Water 0 8.12 0.09 91.44 0.35
Wetland 12.78 0 0 2.3 84.92
Overall Accuracy: 88.10
APSAR 2013 Tsukuba Japan - Sep. 23 - 27, 2013.
Conclusion• Mean and standard deviation values follow the same trend for both the
imaging modes: linear and hybrid
• Urban class exhibits higher standard deviation from mean
• The horizontally polarized receive components, HH and RH are higher than their respective vertically polarized receive components, HV and RV
• The performance of hybrid polarimetric (RH,RV) data in terms of classification accuracy is better than dual polarization (HH, HV) data
• The classification accuracy increases by combining three components (surface, double and volume) of m- or m- along with CPR and SPAN for χ δRISAT-1 and RADARSAT-2 hybrid polarimetric data.
• RISAT-1 hybrid polarimetric data classification accuracy is better than simulated hybrid polarimetric data from RADATSAT-2.