VIIRS LST Uncertainty Estimation And Quality Assessment of Suomi NPP VIIRS Land Surface Temperature Product 1 CICS, University of Maryland, College Park;

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VIIRS LST Uncertainty Estimation And Quality Assessment of Suomi NPP VIIRS Land Surface Temperature Product 1 CICS, University of Maryland, College Park; 2 STAR/NESDIS/NOAA Yuling Liu 12, Yunyue Yu 2, Peng Yu 12, Zhuo Wang 12 Land Surface Temperature (LST) is one of Environmental Data Records (EDRs) provided by the Visible Infrared Imaging Radiometer Suite (VIIRS) onboard the Suomi NPP (S-NPP) satellite, with a spatial resolution of 750m at nadir. It is derived from a split-window regression algorithm in which the algorithm coefficients are surface type dependent as referred to 17 International Geosphere-Biosphere Programme (IGBP) types. The VIIRS LST EDR has gone through a maturity evolving process, completed validated V1 stage maturity review in December This presentation shows some validation results of the review including comparisons of the most recent VIIRS LST product with the ground in-situ observations and with heritage LST product from Moderate Resolution Imaging Spectroradiometer (MODIS) Aqua collection 5. Comparisons against the SURFRAD station (e.g. in-situ) observations indicate an overall accuracy of -0.37K and precision of 2.35 K, with a better accuracy achieved at nighttime compared to that at daytime. The result from the field measurements in Gobabeb, Namibia suggests that both VIIRS and MODIS underestimate the LST by 1.6K and 3K, respectively. Some issues can be summarized: (1) cloud contamination, particularly the cloud detection error over snow/ice surface, shows significant impact on LST validation quality; (2) performance of the VIIRS LST is strongly dependent on a correct classification of the surface type, e.g. the given surface type commission error causes 0.7K LST error using MODTRAN simulation data and 1.2K LST error using the real data; (3) the VIIRS LST can be degraded when very high brightness temperature difference between the split windows is observed; (4) surface type dependent algorithm exhibits inappropriate in overcoming the large emissivity variations within a surface type. Introduction VIIRS LST Algorithm Establish the 2-band 10.76µm(M15) and 12.01µm(M16) split window algorithm for both day and night based on regression equation for each of the 17 IGBP surface types. Cross Satellite Comparison Where (with k=0 to 4) are coefficients depending on surface type (with i =0 to 16 for 17 IGBP surface types) and day/night condition (with j=0 to 1), and θ is satellite viewing zenith angle. Suggested for matchup Sensor Location Ground data in Gobabeb, Namibia Corresponding matchups for VIIRS and MODIS Aqua: Time span: Jan – Dec Corresponding matchups for VIIRS and MODIS Aqua: Time span: Feb – Aug (VIIRS) Jan – Jul. 2013(MODIS) SURFRAD data in US Comparisons against SURFRAD observations indicate an overall accuracy of -0.37K and precision of 2.35K with a better accuracy at nighttime. The result over one field measurement dataset in Africa suggests that both VIIRS and MODIS underestimate the LST by 1.6K and 3K, respectively. Cross comparison results at global scale and granule scale indicate an overall good agreement between VIIRS LST and MODIS LST. The discrepancy of the two satellite LSTs is much smaller when VIIRS LST is calculated using the MODIS sensor data as proxy. This suggests the algorithm difference is not the main cause for the large LST difference. However, there is a positive bias mostly less than 0.5K between VIIRS and MODIS LST. Cloud contamination, particularly the cloud detection error over snow/ice surface, show significant impacts on LST validation quality therefore additional cloud filter is strongly recommended for LST validation and applications. VIIRS LST quality is strongly dependent on a correct classification of the surface type. The given surface type commission error causes 0.7K LST error using MODTRAN simulation data and 1.2K LST error using the real data. The difference between the results from the theoretical analysis and real data analysis is likely caused by the emissivity characterization of surface types. The emissivity variability within a surface type could cause a large error over different regions. The sensor noise, surface type accuracy as well as algorithm uncertainty causes an overall LST uncertainty of 0.9K. VIIRS LST EDR is in validated V1 maturity, ready for scientific use of the data. Comparison results from Simultaneous Nadir Overpass (SNO) between VIIRS and AQUA in 2012, 2013 and early 2014 over US, polar and low latitude areas. The matchups are quality controlled using the quality flags in each product. a) all comparison results under cloud clear condition ; b) based on a, and the satellite zenith angle difference between VIIRS and MODIS is constrained within 10 degrees; c) based on a, and spatial variation tests are added ; d) based on c, and angle difference is added ; e) based on d, and VIIRS LST is calculated using MODIS data as input and then compare to MODIS LST. abcde Daily LST and BT maps are generated for cross-satellite comparison. a)VIIRS LST daytime; b)AQUA LST daytime; c)VIIRS BT11 daytime; d)MODIS BT11 e)LST is calculated with MODIS sensor data and VIIRS algorithm. a b c d e Summary Overall StatisticsImpact on LST All0.73 *Reference: Damien Sulla-Menashe, VIIRS ST V1 Quality Assessment April 02, 2014 EDR meeting is the probability of mis-classfication of surface type i (i=1,2…17) to be j (j=1,2…17) is the LST difference between LST calculated with the equation for surface type i and with the equation for surface type j for each pixel with i surface type represents the error for each IGBP type i under either day or night condition represents the error for all IGBP types and all day/night conditions represents the number of samples for surface type IGBP i represents the total number of samples for all cases Overall StatisticsImpact on LST All-Day1.5K All-Night0.8K All1.2K Impact on LST using real orbit data on Oct. 22, 2014, daytime (top) and nighttime(bottom) Overall Statistics Uncertainty by Surface Type Accuracy Uncertainty by Sensor Noise Algorithm Uncertainty Overall LST product Uncertainty ** All All-Day All-Night Sensor Noise Overall Uncertainty Surface Type Commission Error Granule Scale Impact on LST using simulation data Global Scale Temperature based Validation represents the error caused by sensor noise from both BT11 and BT12 for each IGBP type I under either day or night condition i (i=1,2…17) j(0:night,1:day) represents the error caused by sensor noise from BT11 represents the error caused by sensor noise from BT12 represents noise requirements for emissive band at 11micron and 12micron, onboard the VIIRS, respectively represents the overall error caused by sensor noise represents the number of samples for surface type IGBP i represents the total number of samples for all cases and Where represents the overall LST uncertainty represents the uncertainty caused by surface type represents the uncertainty caused by sensor noise is the algorithm uncertainty, estimated in the coefficients regression procedure bases only on the simulation data.